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Transcript of Design and Development of Medical Device to Improve Assembly of Head/Neck Taper Junctions in Modular...
UNIVERSITY OF BATH
DEPARTMENT OF MECHANICAL ENGINEERING
DESIGN AND DEVELOPMENT OF A MEDICAL
DEVICE TO IMPROVE THE ASSEMBLY OF
HEAD/NECK TAPER JUNCTIONS IN MODULAR
TOTAL HIP REPLACEMENTS
Submitted by Robin Maguire
For the Degree of MSc Engineering Design
September 2013
COPYRIGHT
Attention is drawn to the fact that copyright of this dissertation rests with the
author. This copy of the dissertation has been supplied on condition that
anyone who consults it is understood to recognise that its copyright rests with
its author and that no quotation from this dissertation and no information
derived from it may be published without the prior written consent of the
author.
This dissertation may be available for consultation within the University
Library and may be photocopied or loaned to other libraries for the purpose of
consultation.
CHEATING AND PLAGIARISM
“I certify that I have read and understood the entry in the Student Handbook
on Cheating and Plagiarism and that all material in this assignment is my own
work, except where I have indicated with appropriate references.
Name: Robin Maguire
Student Number: 129399661
Signed: ___________________ Date:_______
ABSTRACT
There has been a significant failure rate in modular total hip replacements
(MTHR) over the past few years, particularly with the use of large diameter
Metal on Metal (MoM) bearings. Various studies have shown that sub-optimal
strength of the head-neck taper junction plays an important role in these high
failure rates.
The purpose of this project is to design and develop a medical device to
improve the assembly of this taper junction with an overall aim to reduce the
occurrence of early revision surgeries on MTHRs. The device aims to ensure
axial alignment of the head and neck tapers before providing an adjustable
impact force between 4KN and 6KN to achieve the strongest possible junction
assembly, with the target of reducing the incidence of fretting and corrosion at
this junction and its associated problems.
User-Needs and Design requirements for this device were established
thought an in depth investigation of relevant literature. From this investigation
a Product Design Specification (PDS) was produced and a final concept
generated, based on these requirements. A Testing Rig was then developed
and manufactured as a proof-of-concept for the impact delivery system
proposed in the final design. Testing and evaluation using this Rig provided
useful data emphasising the effect of tip material selection on the impulse
force produced by the Testing Rig. This project has resulted in the
development of a device design capable of improving the strength of
head/neck taper junctions in MTHRs. It has also resulted in the manufacture
of a lab testing rig which can be used again in the future to further aid the
development of this design.
2
CONTENTS
1. INTRODUCTION 1
1.1 What is a Total Hip Replacement? 1
1.2 What are THRs used to treat? 2
1.3 What is a Modular Total Hip Replacement? 3
1.4 Why are they Modular? 4
1.5 How are MTHRs implanted? 4
1.6 How are MTHR assembled? 5
1.8 What is the problem effecting MTHR? 6
2. AIMS AND OBJECTIVES 8
3. LITERATURE REVIEW 9
3.1 Understanding the problem and why it is occurring 9
3.2 How to reduce or eliminate the problem 12 3.2.1 What influence do Manufacturers have on the assembly? 12 3.2.2 What influence do Surgeons have on the assembly? 15
4. USER NEEDS & DESIGN REQUIREMENTS 24
4.1 Fundamental Design Requirements 26
4.2 Establishing and Defining User Needs 27
4.3 Product Design Specification 33 4.3.2 Commercially available designs and patent research 35 4.3.1 Medical device standards review 38
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4.3.2 Generation of PDS 39
5. DEVELOPMENT & EVALUATION 40
5.1 Concept Generation and Evaluation 40 5.1.1 Initial Product Design Specification (PDS) 41 5.1.2 Discretisation of Design Challenge 42 5.1.3 Radial Thinking 43 5.1.4 Visual Concept Analysis 44 5.1.5 Critical Assessment and Selection 52 5.1.6 Further Investigation of Powering Concept 55 5.1.7 Development of Final Powering Concept 60 5.1.8 Mechanical Feasibility of Chosen Concept 67 5.1.9 Development of Proof-Of-Concept Testing Rig 73
5.2 Detailed Design 79 5.2.1 Solid Modelling 79 5.2.3 Draft Drawings 80 5.2.4 Manufacturing 80
6. TESTING 81
6.1 Calibration of the Load Cell 81
6.2 Rig Testing 83 6.2.1 Procedure 84 6.2.2 Data recorded 87
7. RESULTS AND DISCUSSION 92
7.1 Evaluation of Instron Data 92
7.2 Evaluation of Load Cell Data 93
7.3 Evaluation of Testing Rig 95
4
7.4 Discussion 95
8. CONCLUSIONS 96
10. REFERENCES 98
11. APPENDICES 101
5
NOMENCLATURE
N = Newtons
KN = Kilo Newtons
F = Force
m = Mass
g = acceleration due to gravity (9.81m/s)
m/s = meters per second
Kg = Kilograms
t = Time (in seconds)
Δt = Impact duration
v = Velocity
Δv = change in velocity
k = Spring Stiffness (in N/m)
ABBREVIATIONS
THR = Total Hip Replacement
MTHR = Modular Total Hip Replacement
MoM = Metal on Metal
CoC = Ceramic on Ceramic
CoM = Ceramic on Metal
UHMWPE = Ultra High Molecular Weight Polyethylene
PDS = Product design specification
LIST OF FIGURES AND TABLES
FIGURES
Figure 1: Illustrated Hip Replacement; Before and After [2] ....................................... 1
Figure 2: Charnley’s Low Friction Arthroplasty [4] ..................................................... 2
Figure 3: Illustration of Normal Vs. Arthritic Hip [5] .................................................... 3
Figure 4: Exploded View of MTHR Assembly [7] ....................................................... 3
Figure 5: Illustration of MTHR Surgical Procedure [11] .............................................. 4
Figure 6: Orthopaedic Mallet and Impactor [12] ......................................................... 6
Figure 7: Example of matched and mismatched taper angles [20] .......................... 13
Figure 8: Stuart Pugh’s Design Process Model [33] ................................................. 25
Figure 9: Orthopaedic Surgeon Survey Introduction ................................................ 28
Figure 10: Surgeon Survey, Q1 ............................................................................... 28
Figure 11: Surgeon Survey, Q2 ............................................................................... 29
Figure 12: Surgeon Survey, Q3 ............................................................................... 30
Figure 13: Surgeon Survey, Q4 ............................................................................... 30
Figure 14: Surgeon Survey, Q5 ............................................................................... 31
Figure 15: Surgeon Survey, Q6 ............................................................................... 31
Figure 16: Surgeon Survey, Q7 ............................................................................... 32
Figure 17: Surgeon Survey, Q8 ............................................................................... 32
Figure 18: Stuart Pugh’s Design Core [33] .............................................................. 34
Figure 19: Controlled Force Hammer [35] Figure 20: Controlled Force
impacting device [36] ....................................................................................... 35
Figure 21: Handling Device for Hip Implant [37] Figure 22: Hip Joint Prosthesis
and Fitting Tool [38] ......................................................................................... 35
2
Figure 23: Device for Handling Hip joint Heads [39] Figure 24: Head
holder and impactor [40] .................................................................................. 36
Figure 25: Method of applying Femoral head Resurfacing [41] Figure 26: Nail
gun Patent 1 [42] ............................................................................................. 36
Figure 27: Nail gun Patent 2 [43] Figure 28: Wire Shelf
Driver [44] ........................................................................................................ 36
Figure 29: Automatic Centre Punch [44] .................................................................. 37
Figure 30: Inserter jaw for knee prosthesis impaction and extraction [45] ................ 37
Figure 31: Comparison in grading between EU and USA Device Classification [48] 38
Figure 32: Initial sketch to capture ideas ................................................................. 42
Figure 33: Development of Objective B ................................................................... 43
Figure 34: Development of Objective C ................................................................... 44
Figure 35: Three Prong Flexible Support and Centring Cone Sketch ...................... 45
Figure 36: Semi-Cup + Centring Cone Sketch ......................................................... 45
Figure 37: Bent Hex-Rod Sketch ............................................................................. 46
Figure 38: Bent Rod Circular Profile Sketch ............................................................ 46
Figure 39: Split Cup/Split Mould Sketch .................................................................. 47
Figure 40: Slide Hammer - Direct Impact Sketch ..................................................... 47
Figure 41: Slide Hammer - To Charge Spring Sketch .............................................. 48
Figure 42: Magnets Sketch ...................................................................................... 48
Figure 43: Electro-Magnets Sketch ......................................................................... 49
Figure 44: Screw Mechanism - No Impact Sketch ................................................... 49
Figure 45: Screw Mechanism - To Charge Spring Sketch ....................................... 50
Figure 46: Lever - To Charge Spring Sketch ........................................................... 50
Figure 47: Pneumatic Piston Sketch ........................................................................ 51
Figure 48: Rod Inserted In Stem Hole Sketch .......................................................... 51
Figure 49: Mechanism to Hook around the Lips at Base Sketch .............................. 52
Figure 50: Pneumatic Nail Gun Illustration [49] ........................................................ 56
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Figure 51: The Solenoid Powered Nail Gun [49] ...................................................... 57
Figure 52: Electric Powered Nail Gun [49] ............................................................... 58
Figure 53: Can-Crushing Device [50] ...................................................................... 59
Figure 54: Adapted Juicer Sketch ............................................................................ 60
Figure 55: Adapted Can Crusher Sketch ................................................................. 61
Figure 56: Corkscrew Lever System Sketch ............................................................ 62
Figure 57: Twisting Adjustment and Release Concept Sketch ................................. 63
Figure 58: Gearbox Style Spring Compression Adjustment Concept Sketch ........... 63
Figure 59: Spring Compression adjustment System Sketch .................................... 64
Figure 60: Slotted Trigger Release Mechanism Sketch ........................................... 65
Figure 61: Firearm Trigger Concept Sketch ............................................................. 65
Figure 62: Handle Trigger System Sketch ............................................................... 65
Figure 63: Final Developed Concept Sketch ........................................................... 66
Figure 64: Tubular Casing Surrounding Spring Sketch ............................................ 67
Figure 65: 3 step sketch illustration of corkscrew charging method ......................... 67
Figure 66: Force Balancing Free Body Diagram ...................................................... 68
Figure 67: Instron Loading Machine [51] ................................................................. 74
Figure 68: Initial Testing Rig .................................................................................... 75
Figure 69: Simplified Concept for Testing Rig .......................................................... 76
Figure 70: Initial Lever Design ................................................................................. 77
Figure 71: Lever Design Development .................................................................... 78
Figure 72: Final Lever Design ................................................................................. 78
Figure 73: Final Assembled SolidEdge 3D Model .................................................... 79
Figure 74: First Calibration Test plot of Voltage Vs. Time ........................................ 82
Figure 75: Load Cell Calibration Test Data Plotted on Graph .................................. 83
Figure 76: Custom Mounting points, close up view of top, close up view of bottom . 84
Figure 77: Spring Section in mounting points, close up view of top, close up view of
bottom ............................................................................................................. 85
4
Figure 78: Base plate fixed to table with and without Rubber Base ......................... 86
Figure 79: Table of Data recorded from Instron ....................................................... 88
Figure 80: Test 2, Steel, 2KN (with rubber base) ..................................................... 89
Figure 81: Extrapolated Load Cell Data, >2KN ........................................................ 90
Figure 82: Extrapolated Load Cell Data, 4KN and 6KN ........................................... 91
Figure 83: Images of Failed PVC and Rubber Tips at 4KN Load ............................. 92
TABLES
Table 1: Data from Pennock et al. (2002) study [29], [10] ........................................ 17
Table 2: Data from Lavernia et al. (2009) Study [30], [10]........................................ 18
Table 3: Data from Heiney et al. (2009) Study [31], [10] .......................................... 19
Table 4: Data from Rehmer et al. (2012) Study [32], [10]......................................... 21
Table 5: Initial PDS.................................................................................................. 41
Table 6: Scoring Table for Sub-System Concepts ................................................... 54
Table 7: Data recorded during Load Cell Calibration ............................................... 82
1
1. INTRODUCTION
1.1 What is a Total Hip Replacement?
There are two types of Hip Replacement surgery, Hip Resurfacing and Total Hip
Replacement (THR). This project focusses on the THR procedure, which is also
known as Total Hip Arthroplasty. THRs are among the most common orthopaedic
procedures performed today [1]. The THR procedure involves removing the femoral
head (top of the thigh bone) and a layer of bone from in and around the acetabulum
(hip socket) and replacing them with artificial materials, thus resulting in an artificial
hip joint. The before and after pictures of a hip joint that has undergone a THR is
shown in Figure 1 [2] below, with the original diseased hip joint shown on the left
and the new replacement joint shown on the right.
Figure 1: Illustrated Hip Replacement; Before and After [2]
2
The first modern THRs were designed by John Charnley in the 1960s, which
stemmed from his paper “Surgery of the Hip Joint - present and future
developments” [3] published in 1960. Charnley’s THR consisted of a high density
polyethylene cup that was fixed inside the hip joint socket and a stainless steel
component that made up the artificial femoral head and stem which slotted into the
patient’s femur. This “low friction arthroplasty” [4] hip design was first implanted in
November 1962 and can be seen in Figure 2 [4] below.
Figure 2: Charnley’s Low Friction Arthroplasty [4]
1.2 What are THRs used to treat?
THRs can be used to treat degenerative arthritis in the hip joint and can also be
used to treat femoral neck fractures [1]. The original hip joint shown previously in
Figure 1 [2] is arthritic, as you can see the deterioration of the bone at the
ball/socket contact point. This is shown in more detail in Figure 3 below [5] where
illustrations show the difference between and healthy and arthritic hip joint.
3
Figure 3: Illustration of Normal Vs. Arthritic Hip [5]
1.3 What is a Modular Total Hip Replacement?
Modular THRs (MTHR) were introduced in the 1970s [6]. The previous leg (femoral)
component used in Charnley’s original design was separated into head and stem
components and the previous plastic cup was separated into shell and liner
components. An example of such a modern modularised THR design is shown in
Figure 4 [7], as follows, using an exploded view of an assembly.
Figure 4: Exploded View of MTHR Assembly [7]
4
1.4 Why are they Modular?
Modularisation was introduced into the design of THRs in the 1970s [8] to allow
more flexibility in material selection/combination and component sizing to ensure a
more individually suited THR for each patient. It also allows surgeons to reduce
inventory [9] and simplifies revision surgeries [8]. Several different material choices
and combinations are available to surgeons. For the stem and head; Cobalt Chrome
or Ceramic Heads can be used on Titanium stems. For the bearing combinations;
Metal on Metal (MoM), Ceramic on Ceramic (CoC) and Ceramic on Metal (CoM),
and finally Ceramic or Metal heads can also be used on Ultra High Molecular
Weight Polyethylene (UHMWPE). [10]
1.5 How are MTHRs implanted?
The MTHR procedure is illustrated in four steps in Figure 5 as follows.
Figure 5: Illustration of MTHR Surgical Procedure [11]
5
Step A involves making an incision to gain access to the joint area and dislocating
or “disarticulating” [11] the femoral head from the acetabulum (or hip socket).
Step B involves cutting off the femoral head with a surgical saw.
Step C involves reaming out the acetabulum and the femur to prepare them to
receive the shell and stem respectively.
Step D involves the introduction of the prosthetic components and the final image in
the bottom right hand side of the figure shows the fully installed THR.
1.6 How are MTHR assembled?
The order in which the components are introduced in this procedure is important to
note. The acetabulum shell is first introduced and fixed in place before the stem is
inserted into the femur. There are two types of stem designs; cemented, where
special cement is inserted into the reamed femur before the insertion of the stem
which is then used to permanently fix the stem in the femur; and cement-less, where
the surface finish on the stem is designed to encourage bone growth and adhesion
to the stem. Once the shell and stem have been introduced, the surgeon can then
trial their proposed head and liner size using special trial head and liner
components. Once these trial components have been fitted and the head (already
fitted to the stem) has been located in the hip socket (liner), the surgeon can then
check the fit of the joint in the patient by checking leg length and the range of motion
available. Once the surgeon is happy with the proposed size of their head and
associated liner the trial versions are removed and the exposed shell cup and stem
taper surfaces are cleaned to prepare them for the introduction of the final head and
liner components. The liner is inserted and fixed in place before the head is placed
on what is called the neck taper of the stem and the head is then impacted onto the
6
stem taper using a mallet and impactor (usually tipped with a softer material than
the head so as not to damage the surface of the head). An example of the sort of
mallet and impactor commonly used is shown in Figure 6 [12] below.
Figure 6: Orthopaedic Mallet and Impactor [12]
The male neck taper on the stem is cone shaped. This taper is designed to match a
female taper on the inside of the femoral head component. When the head is
impacted onto the neck the taper, the head taper must expand as it is forced down
the neck taper by the impact delivered by the surgeon. This increases surface
friction and creates hoop stresses that fix the two components firmly in place.
1.8 What is the problem effecting MTHR?
However, it is this particular junction which has been the focus of much research
and analysis over the past few years and is gaining more and more attention. MTHR
have long been associated with earlier than expected revision surgeries and many
7
product recalls. Large diameter (>36mm) MoM bearings are by far the worst
offenders when it comes to early revisions and product recalls. The use of large
diameter MoM bearings amplifies an existing issue regarding the strength of the
head/neck taper junction more so than other joint material and geometry selections.
Large diameter bearings produce an increase in the torque in the joint, as a larger
frictional torque is generated since there is a longer lever arm acting between the
fulcrum or centre of the joint’s rotation and the surface where the head makes
contact with the liner, especially MoM. This increase in force about the junction,
leads to increased levels of fretting wear and corrosion, which causes the liberation
of prosthesis material and hence early revision surgeries (as the human body has
an adverse reaction to the presence of these foreign particles).
Fretting corrosion and wear can still occur in all material and geometry combinations
but the accelerated and extreme instances found in some of the large diameter
MoM bearings, have really highlighted this problem and raised its importance in all
MTHR designs.
Various studies, which will be discussed in the next section, have shown that the
main factor affecting the longevity of MTHRs is the strength of the head/neck taper
junction. The main influence on the assembly of this junction is the magnitude of the
impact force applied during assembly.
The next section of this report lays out the aims and objectives of this project in a
clear and concise manner.
8
2. AIMS AND OBJECTIVES
Aim: To design and develop a medical device to improve the assembly of
head/neck taper junctions in MTHRs with an overall aim to contribute to the
reduction of early revision surgeries for MTHRs
Objectives:
1. Review relevant literature to gain greater understanding/scope of problem
2. Establish User Needs and Design Requirements
3. Produce Product Design Specification (PDS)
4. Generate and evaluate design concepts
5. Design and develop a prototype for proof-of-concept
6. Manufacture and Test prototype
7. Evaluate test results and review overall concept
9
3. LITERATURE REVIEW
This section of the report contains the findings from the literature review carried out
on the failure of MTHRs due to head/neck taper junctions. The review spread out
beyond the borders of this specific issue to ensure an understanding of the bigger
picture could be taken into account before focussing on the specific problem itself
towards the end of the review. The findings are now presented under two headings,
“Understanding the Problem and why it is occurring”, followed by “How to reducing
or eliminate the problem”.
3.1 Understanding the problem and why it is occurring
Before trying to solve the problem it is essential to take the time to fully understand
the background and history of the problem and the reason behind its occurrence.
One of the most renowned examples in the failure of large diameter MoM MTHR
was the Depuy ASR. Five hundred and five Depuy ASR MTHRs were implanted in
total [13]. They were found to have an extremely high failure rate of 48.8% after six
years [13]. The design was found to have failed for two reasons, and Heneghan et
al. (2012) [14] made an important connection between the ASRs design failings and
other existing designs that are still being used today. The first reason for the failure
of the ASR was due to the acetablular cup being too shallow. This led to wear at the
bearing edges and hence starvation of lubrication in the bearing area which led to
increased wear around the edges of the cup, thus creating a self-destructive cycle.
The wear causes the liberation of metal particles from the bearing surfaces which
cause “extensive soft tissue necrosis and disruption of bone” [14]. The second
failure reason, which is the most relevant to this project, was due to the increased
torque experienced at the head/neck taper junction which was caused by the larger
10
diameter of the bearing. This increase in torque caused wear and fretting corrosion
which again led to the liberation of metal particles and thus patient complications, as
with the first failure method. The reason why the second failure method is the most
important to this project is because the use of large diameters in MoM bearings is
not unique to the ASR design and so plays a role in the failure rates of various other
MTHR designs. Both Henghan et al. (2012) [14] and Langton et al. (2011) [13]
agree on this point and Langton et al. go on to suggest that bearing diameters of
36mm or greater are most at risk to this failure method.
Smith et al. (2102) [15] concluded, following an in depth analysis of National Joint
Registry Data covering England and Wales, that MoM bearings are more likely than
other bearing material combinations to fail, and also found that their failure rates
were increasing proportional to increasing bearing diameter size. Langton et al.
(2011) [13] also came to the same conclusion in their study into the failure of the
Depuy AST MTHR thus adding further backing to this theory.
The UK government, by way of the Medicines and Healthcare Products Regulatory
Agency (MHRA), took action on the issue by releasing a Medical Device Alert
(MDA/2012/036) [16]. This MDA provided instructions on monitoring patients with
MoM Hip Replacements (or Hip Resurfacings), and highlighted the dangers
associated with the use of the Depuy ASR models which had been recalled.
Smith et al. (2012) suggested in his study on the Joint Registry data that the
increased failure rates for Large Diameter MoM bearings could be due to the
loosening of the head/neck taper junction caused by the increased torque acting
about that junction, which was also suggested by Heneghan et al. (2012) [14], as
mentioned earlier. Bishop et al. (2008) [17] carried out a study into the frictional
moments in MTHRs and found that MoM bearing combinations produced the
11
greatest frictional moments followed by Metal on UHMWPE and then CoC with the
lowest frictional moments, thus adding to the growing evidence pointing at the
failings of MoM bearings. Langton et al. (2011) [13] found that as the trend in
increasing bearing diameter grew, there was no increase in the diameter of the neck
taper to counter the associated increase in torque. In a different study by Langton et
al. (2012) [18] they noted that neck diameters actually decreased as larger and
larger bearings sizes became available, thus exacerbating the problem. The
reasoning behind reducing the diameter of the neck taper was to increase the range
of motion of the prosthesis.
One of the biggest studies of MTHR neck/taper junctions was carried out by
Goldberg et al. (2002) [19] and looked into various different aspects and failure
methods in this junction. One of the recommendations that they put forward
following their research was to increase the neck taper diameter with an aim to
increasing the stiffness of the neck so as to reduce the fretting and corrosion that
they found to be occurring at this junction.
To summarise, the importance of the strength of the head/neck taper junction has
been highlighted by the recent failing of some designs of MTHRs (example Depuy
ASR). These designs have increased the head diameter to reduce the occurrence of
dislocations of the head in the hip socket, and reduced the neck taper diameter to
increase the range of motion in the joint, but have actually increased the torque
about the bearing, which has a loosening effect on the head/neck taper junction.
This loosening allows micro-motions in the junction, which then leads to fretting
wear and corrosion. The fretting wear and corrosion causes the liberation of taper
material particles which are toxic to the human body and produce patient
complications that are treated with revision surgeries.
12
Now that the severity and reasoning behind the failure MTHRs has been established
the next step is to look at who has influence or control over the reduction or
elimination of the problem.
3.2 How to reduce or eliminate the problem
This part of the chapter looks at who has control over or influence on the key factors
that contribute towards the strength of the head/neck taper junction. This part
finishes with an in depth analysis of four particularly relevant studies with an aim to
establishing the optimum conditions and provisions for assembling a head/neck
taper junction.
3.2.1 What influence do Manufacturers have on the assembly?
Studies by Langton et al. (2011) [13], Langton et al. (2012) [18] and Goldberg et al.
(2002) [19] have all stressed the importance of the neck taper diameter in ensuring
a strong head/neck taper junction. It must be large enough to provide the neck
stiffness required to support the joint and prevent loosening under high torques.
Manufacturers have control over this dimension, since they are the ones designing
the products. Now that they have been made aware of this factor by the
aforementioned studies they can develop their future designs with this in mind.
Others factors that can influence the strength of this junction are the tolerances
applied during manufacture. For example, it is very important that the head and
neck taper angles are as closely matched as possible for an optimal fit. This is
illustrated in Figure 7 [20] as follows.
13
Figure 7: Example of matched and mismatched taper angles [20]
Figure 7 Part A shows the correct fit with the maximum contact area between the
head and neck tapers. Figure 7 Part B on the right shows a poor fit where there is a
significant taper angle mismatch leaving low contact area creating stress
concentrations and room for micro-motion (also described as toggling) which leads
to fretting corrosion and wear. Goldberg et al. (2002) [19] stressed the importance of
angular mismatch and conicity of the tapers when trying to reduce fretting wear and
corrosion at the head/neck taper junction. They also mention the importance of a
good quality surface finish or “roughness” and its effects on the strength of the taper
junction. Fessler and Fricker (1989) [21] established a connection between the
presence of high hoop stresses in alumina heads and only small levels of taper
angle mismatch. Aside from hoop stress concentrations angular mismatch also
facilitates micro-motion since the taper is not rigidly supporting itself along its length,
as it is only held over a small collar of area (where the stress is concentrated).
Shareef and Levine (1995) [22] confirmed a link between taper angle mismatch
(including general manufacturing tolerances) and micro-motion found in taper
junctions, in their study into this phenomenon. Scharmm et al. (2000) [9] also made
the valid point that the accuracy of machining and the development of better wear-
14
resistant materials plays an important part in the improvement of these designs,
along with the recognition that only a very small mismatch is required to begin a
cycle of fretting corrosion and wear.
In a study which involved measuring the forces required to disassemble three
different model of MTHRs, which had been retrieved from patients undergoing
revision surgeries, Lieberman et al. (1994) [23] made an interesting discovery. One
of the models required a much greater force than the other two to be disassembled
and was the only model type of the three examined not to show any signs of
corrosion after a 78 month period. These particular MTHRs had a different assembly
history from the other two model types in that they had been assembled by the
manufacturer and were supplied to the surgeon in a preassembled condition. These
MTHRs had been shrink fitted with a sealant, applied during this assembly.
Lieberman et al. (1994) [23] believe the greater junction strength and resistance to
corrosion was due to improved manufacturers tolerances and the use of the sealant
during assembly. However, based on the studies in the next part (3.2.2) of this
report, it is suggested that another influence had made the difference in the
assembly. The depth to which the neck would have reached inside the head taper
would have been increased due to the shrink fitting process and no doubt would
have made the junction stronger and hence more difficult to disassemble. In normal
assembly conditions with a surgeon assembling the head and neck tapers at room
temperature, the previous fit could only be replicated with an axially aligned impact
force of optimum magnitude. As mentioned previously the assembly of MTHRs is
carried out in-vivo by a surgeon using a mallet and impactor. The next section
addresses the influence that the surgeons can have on the strength of the
head/neck taper junction.
15
3.2.2 What influence do Surgeons have on the assembly?
The “fit of the spigot head” is noted as the “most important source of error” in
Fessler and Fricker’s (1989) [21] study into the “Stresses in Alumina Universal
Heads of Femoral Prosthesis”. Bobyn et al. (1994) [24] would agree with their
statement since they found a reduction in taper surface contact area and an
increase in wear and fretting corrosion in two Modular Femoral Prosthesis, after
assembling them both using one fifth of the manufacturers recommended assembly
force and exposing them to the sort of cyclic loading that they would experience in-
vivo. Thus the impact load applied has a significant influence on the fit or the
assembly of the head on the neck. A study carried out by Goldberg and Gilbert
(2003) [25] entitled “In vitro corrosion testing of hip tapers” concluded that the
“proper seating of the head onto the neck” increases the forces required to cause
micro-motion, and hence wear and fretting corrosion. A study by Mroczkowski et al.
(2006) [26] mimicked much of the Goldberg and Gilbert’s (2003) study but added a
sub-study looking at varying the impact applied during assembly and found that, out
of head/neck tapers assembled in air and water and using either hand press
assembly or a 6.7KN impact, the tapers assembled in air using 6.7KN showed the
best resistance to fretting corrosion and wear under cyclic loading. This study again
adds to the proof of the importance of the impact magnitude when trying to prolong
the life of MTHRs in-vivo. However, as much of the previous studies would lead to
the assumption that the greater the impact the better the assembly strength, this is
not the case because if too great a force is used during assembly it can actually
damage the taper interface and cause potentially catastrophic damage to the
femoral head as well as other issues with the interface between the stem and the
femur.
16
The impact force is not the only important factor that the surgeon has influence over
during assembly. The axial alignment when placing the head on the neck taper prior
to impact and the axial alignment of the impact delivered is also extremely
important. Both Callaway et al. (1995) [27] and Pansard et al. (2012) [28] traced
back the failure of a number of MTHRs to incorrect fitting of the head on the neck
taper by examining retrieved MTHRs removed during revision surgeries. They both
found that their retrieved Hip Replacements had failed due to extreme corrosion
caused by incorrect fitting of the head during original assembly. Due to varying
manufacturing tolerances between different brands, it is also strongly recommended
not to mix different manufacturers components as this can result in poorly fitted
parts that can reduce the life of the prosthesis.
Four key papers are now discussed with a focus on the effects of the impact/s
applied during the assembly of the head/neck taper junction with an aim to
establishing the optimum impact magnitude and number of impacts so that this
information can then be used to guide the design of the device that this is being
developed for this project.
The relevant information has been extracted from each of the four studies in an
effort to simplify them for ease of comparison and add clarity to the investigation.
The implant quantities, head diameter, assembly tools, impact forces, number of
impacts and the pull-off forces (forces to pull the assemblies apart) have been used
as the categories by which to analyse these studies. The studies will appear in
chronological order, starting with Pennock et al. (2002) [29] study entitled “Morse-
type tapers: factors that may influence taper strength during total hip arthroplasty”.
The relevant data from this study has been populated in the standard table for this
investigation and is shown in Table 1 [10] as follows.
17
Table 1: Data from Pennock et al. (2002) study [29], [10]
This study looks at the effects of varying the magnitude of the impact force, the
order in which the different impact forces are applied and the total number of
impacts delivered during assembly and their effect on the resulting junction strength
(determined by pull-off tests). This study also looked at the effects of wet and dry
taper surfaces on junction strength, but the wetted samples were not included in this
table as Pennock et al. (2002) established that wet taper surfaces reduced the
strength of the junction. However, since the wet tapers were not used, this halved
the size of the data that could be used in Table 1 [10] and hence limited the amount
of data available for use and thus limited the credibility of the data used in the study.
It is also worth noting that the impact forces used were based around an average
force that was found by measuring the impact force applied by a single surgeon
over 11 impacts and came to an average of “2075N” (N for newtons). It can be
assumed then that the “Medium” force magnitude listed in this study is 2075N or
very close to it, though it is impossible to say what magnitude the “Light” and
“Heavy” impacts are.
From the pull-off values shown in Table 1 [10] it can be assumed that the highest
impact provides approximately 95% of the strength to the junction with further lighter
impacts still adding a small contribution (approximately 5%) to the overall strength
18
[29]. Pennock et al. (2002) [29] also states the importance of axial alignment when
delivering the impacts, to ensure that all of the force is transmitted during the
impaction. One of the findings taken from their study (especially when the wet
tapers were taken into consideration) was that they noted an increase in junction
strength with increasing impact magnitude [29].
The next study was carried out by Lavernia et al. (2009) [30] and looked mainly at
the effects of blood and fat contamination on the taper surfaces and the effect they
had on the junction’s strength. However, as they used “control” or dry tapers for
comparison the data recorded for these was of benefit to this investigation and has
been recorded in Table 2 [10] below.
Table 2: Data from Lavernia et al. (2009) Study [30], [10]
Since this data only covers the control for the main experiment, much like the
previous study, it does not have the largest sample size and this is recognised as a
limitation for the purpose of this investigation. It is also worth mentioning that the
four specimens used were assembled and disassembled 5 times each to establish
an average disassembly, and it is apparent that the repeated assembly and
disassembly of these specimens lowers the strength of the junction and can askew
the average disassembly forces to some degree. The impaction magnitude used in
19
this study can be considered to be a more realistic representation of the average
magnitude of a surgeons impact as they recorded the impact forces applied by 8
different surgeons as opposed to the previous study by Pennock et al. (2002) [29]
that only used 11 impacts by a single surgeon. The result is a 27% (approx.)
decrease of the force used by Pennock et al (2002). It is worth noting that this study
does not vary the impact magnitude or the number of impacts applied, but does give
a good representation of the average pull-off force for the prescribed magnitude with
a single impaction and provides another average value for surgeon impaction
magnitude, which will both be of use later when comparing this study to those that
follow on in this part of the chapter. The overall study showed that a clean and dry
taper provides the optimum assembly condition to facilitate maximum junction
strength.
The next study was carried out by Heiney et al (2009) [31] and had a much larger
sample size of useable data for the population of Table 3 [10] as seen below.
Table 3: Data from Heiney et al. (2009) Study [31], [10]
The average impact force applied by surgeon’s was also measured for this study
and improved upon the two previous study mentioned, as this time they took values
from 10 surgeons to create the average value to base their range of varied impact
20
assembly forces. The average surgeon’s impact force applied during assembly in
this study is roughly twice that of either of the two previous studies showing a large
range of magnitudes arising across the different surgeons used to create the
averages in each study.
Heiney et al. (2009) [31] found there to be a difference in junction strength between
using one impaction and two impactions but found no difference when applying
more than two impactions. This finding compliments one of the findings from the
study by Pennock et al. (2002) [29], in that the first impaction provides the majority
of the junction strength with subsequent impacts providing a small but additional
increase. Heiney et al. (2009) [31] also found that the junction strength increased
along with the impact magnitude thus adding weight to this original finding by
Pennock et al (2002) [29]. It is unfortunate that neither Pennock et al (2002) [29]
nor Heiney et al. (2009) [31] provided the impact forces in newton values instead of
written descriptions such as light, medium and heavy, so that the studies could be
compared in more detail.
Following the completion of their study Heiney et al. (2009) [31] recommended “at
least two firm, axially aligned blows” to achieve optimum junction strength, but they
also warned that impacts of an “excessively high magnitude” can lead to “femoral
fractures around cement-less stems”, as the impact force may travel down into the
patient during assembly and could damage the bone stem interface.
The next study was carried out by Rehmer et al. (2012) [32] and was the largest and
most relevant to this project. They looked at the effect that different material
combinations, impact magnitudes and the number of impactions can have on the
taper junction strength. One immediate benefit is that they provided the assembly
impact forces in newtons and not in written descriptive terms as in the previous
21
studies. The relevant data acquired from this study is shown in Table 4 [10] as
follows.
Table 4: Data from Rehmer et al. (2012) Study [32], [10]
Using pull-off and twist-off disassembly tests, Rehmer et al. (2012) [32] found that a
single impact of a minimum of 4KN (kilo-newtons) was required to ensure optimum
taper junction strength. They also discovered, just like Heiney et al. (2009) and
Pennock et al. (2002), that there was little or no benefit from more than one
impaction and even went as far as suggesting that more than one impact could
actually loosen the taper junction or reduce the strength provided by a previous
impact.
Rehmer et al. (2012) go on to state that if one single impact of a minimum of 4KN
was set as a recommendation by manufacturers for the assembly of the femoral
prosthesis, then this would place the responsibility on the surgeon to ensure
“suitable taper fixation, by firm and careful impaction”. They state that this would
greatly improve the strength of the taper junction in modular femoral prosthesis, but
unfortunately it is clear that this is currently not possible. This is proven in a similar
study by Loch et al. (1994) [8] entitled “Axial Pull-Off Strength of Dry and Wet Taper
22
head connections on a modular shoulder prosthesis”. In this study, they use a
surgeon to try to acquire an average assembly impact force for which they can
design a drop rig. The drop rig is then used to assemble their specimens with a
constant impact force but under different conditions (i.e. dry or wet) prior to
disassembly testing. The surgeon assembled 6 shoulder taper junctions using a
mallet and impactor (the same as is used in a modular femoral hip assembly), and
Loch et al. (1994) [8] then measured the force required to pull the joints apart. They
repeated this process with the surgeon and the same six specimens 16 times to
acquire their average pull-off value, which they then used to set a drop rig to
assemble the test specimens to replicate this average pull-off value (under control
conditions). It is acknowledged the average pull-off values may have been affected
by the reduction in strength that can be experienced when repeatedly assembling
and disassembling the same specimens. The pull-off forces, from the surgeon’s
assemblies, ranged from 958N all the way to 4893N which is a very wide range.
This data on its own would not be enough evidence given the reduced taper junction
strength associated with repeated assembly. However, looking back on each of the
four key studies featured previously it is clear to see that surgeons are not providing
the same magnitudes of impact, and even if they were, the axial alignment of the
impact cannot be guaranteed. So, even if the surgeons could apply an impact force
of no less than 4KN, this could still be diminished if the impact was not axially
aligned with the head and neck tapers, or if the head taper was not seated correctly
on the neck taper prior to impaction. Even though it has not been recorded in the
studies featured here, it seems there is nothing stopping an impaction exceeding
12KN and creating the potential for internal damage to the patient. This prompts the
suggestion that there is need for a device that can help surgeons ensure that the
23
head is correctly seated on the neck taper before providing a single impact of no
less than 4KN, which is axially aligned with the taper axis. The impact should also
not exceed 6KN to ensure that it does not stray into the region where it could cause
internal damage to the patient or damage to the tapers, as mentioned previously.
The findings from this review will be used to guide the design of the device
proposed in this project, and to aid the assembly of MTHRs. The next step in the
process is to establish the user needs and hence design requirements for such a
device.
24
4. USER NEEDS & DESIGN REQUIREMENTS
It is now clear from the Literature Review that there is room for improvement in the
assembly of head/neck taper junctions in MTHRs. This “room for improvement”
grows and becomes a serious problem when considered in the use of large
diameter bearings, particularly MoM bearings. Even if manufacturers applied perfect
tolerances, surfaces finishes and optimum neck taper diameters it is still essential to
correctly assemble this taper junction to benefit from these improvements. It is clear
from the wide ranging impact forces applied by different surgeons that it is unfair to
expect them to be able to repeatedly provide the very specific forces and alignments
required for the optimum assembly of MTHRs using the current tools at their
disposal (mallet and impactor). Therefore the development of a new device is
completely justified.
It is also worth mentioning at this point in the report that the Design Process
Structure being followed in this project is based loosely around Stuart Pugh’s Total
Design Approach (1991) [33]. This section of the report is mimicking the “Market”
stage in Pugh’s model, as shown in Figure 8 [33] as follows.
25
Figure 8: Stuart Pugh’s Design Process Model [33]
The stage following this will be the development of a Product Design Specification
(PDS) which is referred to in Figure 8 as “Specification”. The “Concept design” and
“Detail design” stages feature in the next chapter of this report.
This section of the project involves extracting and clearly defining the design
requirements from the Literature Review. It also includes researching and
investigating other design requirements for the proposed device, with an aim to
26
producing a Product Design Specification (PDS), which can then be used to guide
the next stage of the project.
4.1 Fundamental Design Requirements
These design requirements have been extracted directly from the findings in the
literature review and form the foundation and basis for the entire design, i.e. the
design must achieve all of these requirements to be successful. The fundamental
design requirements are listed as follows.
1. Ensure axially aligned seating of head on neck taper axis prior to impaction
2. Impact must be delivered in axial alignment with neck taper axis
3. Deliver impact force of between 4KN and 6KN, adjustable to 0.5KN
4. Must try to isolate majority of impact to head/neck taper junction
The first requirement is very much self-explanatory and is to try to prevent the
failures recorded by Callaway et al. (1995) [27] and Pansard et al. (2012) [28] as
mentioned previously in the Literature Review.
The second requirement is essential to ensure the efficient transfer of the impact
force into the junction assembly.
The third requirement has also been added from the Literature Review as the device
must now be adjustable to 0.5KN (or 500N). This is to account for the different
manufacturing tolerances and the effect that they will have on the efficient
transmission of the impact force into the taper junction. The adjustability will also be
useful when using different materials, such as ceramic heads, that may require the
27
minimum force, compared to larger metal taper junctions that may require slightly
more force for optimum assembly.
The fourth requirement involves trying to concentrate the impact to the taper
junction and not down the stem where it could cause damage to the stem/femur
interface. It is also intended to ensure the efficient transfer of impact energy into the
junction and not to have it wasted through dissipation into the surrounding region.
4.2 Establishing and Defining User Needs
Since the fundamental design requirements had now been established, the next
step was to look beyond these fundamentals to establish other design requirements.
It is extremely important to involve the end user in the design of anything to ensure
that it meets their specific needs, so a survey was used to try to gather design
information that would help to ensure that the device would not miss out on any
important design features. After looking through several different methods of
gathering these requirements through a user-centred-approach [34], such as
ethnography or contextual inquiry, and consideration of the time and finance
available for this project, a survey directed at orthopaedic surgeons (the end users)
became the most suitable option.
The survey consisted of 8 questions, with a combination of both text response and
multiple-choice answers. The questions posed in this survey are now presented as
follows.
The beginning of the survey contained a very brief introduction into the background
of the survey and its aim. This is shown in Figure 9 as follows.
28
Figure 9: Orthopaedic Surgeon Survey Introduction
After the introduction to the survey, the first question posed attempted to gain an
understanding of the size of the range of different hip implants that were being used
and whether or not they were cemented or cement-less. This would influence
whether or not the device would be designed solely for use with a very popular
model. If a wide variance was uncovered, it would lead to designing a more flexible
device that could work with all different types of implants, or at least a large range of
them. The specific wording chosen for this question can be seen in Figure 10 as
follows.
Figure 10: Surgeon Survey, Q1
29
The next task was to establish the range of femoral head sizes. This was important
to establish so that the device could be designed to facilitate the most common
head sizes. This also fulfils the purpose of establishing a general impression of the
current use of large diameter (>36mm) MoM bearings, given their associated
problems previously mentioned in the literature review. The wording and layout of
this question is shown in Figure 11 below.
Figure 11: Surgeon Survey, Q2
Since it is important to understand the environment and orientation that the device
would be used in, the next question attempts to establish which surgical approaches
are used and which are the most common. The different approaches can determine
the patient’s position, i.e. lying face up, face down or on their side. This can have an
effect on the angle that the device may have to be used at, and impacts the
ergonomics of the design. This question is shown in figure 12 below.
30
Figure 12: Surgeon Survey, Q3
The next question aims to establish the size of the access area or incision in the
patient that the device must fit and function inside. The average size is 10cm, so this
question looks to see if many surgeons work under or above this incision size. This
question is shown in Figure 13 below.
Figure 13: Surgeon Survey, Q4
No instrumentation for the assembly has been discovered in previous investigations,
apart from the mallet and impactor. However, it is still worth raising the subject with
the surgeons, in case any custom-made or other such instrumentation is already
being used. This question is shown in Figure 14 as follows.
31
Figure 14: Surgeon Survey, Q5
The next question was not so much based on the establishment of design
requirements for the device, but more so at gathering data to compare with the four
studies listed at the end of the literature review. It was acknowledged that the
responses could not be looked upon too strongly, as the information provided by the
surgeons is opinion-based and thus is quite subjective. This question is shown in
Figure 15 below.
Figure 15: Surgeon Survey, Q6
An important opinion to gauge is the perceived importance of the isolation of the
impact to the taper junction so as not to damage the stem/femur interface. This
32
question was provided in a format where the participant rates the level of
importance out of 10. This question is shown in Figure 16 below.
Figure 16: Surgeon Survey, Q7
The final question allowed the surgeon’s to propose any features that they felt
should be included in the design of the device. The intention of this question was to
give the user an opportunity to directly propose things that were of importance to
them so that the design would have some sort of user-centred-design approach.
This question is shown in Figure 17 below.
Figure 17: Surgeon Survey, Q8
The survey was created and distributed among the members of the Royal British
Orthopaedics Association, following the completion of the Literature Review. The
survey received a very good response, as 109 surgeons participated. However,
survey participation only started towards the end of the project. Therefore the survey
responses could not be considered in the design of the device during this project.
33
However, a brief analysis of the survey has shown that there is a significant amount
of very relevant data available which would be of great value to the future
development of the device. A summary of the survey response is contained in
Appendix 1.
The original plan had been to gather the findings from the literature review and the
feedback from the survey and allow this to contribute to the PDS, but as mentioned
above this was not possible so for this reason none of the feedback from the survey
influenced the PDS. The PDS will now be discussed in more detail in the next
section.
4.3 Product Design Specification
The purpose of a PDS is to provide the designer with a list of design requirements
which can be regularly referred back to, so as to ensure that the design
requirements are being satisfied at each stage in the design process. Stuart Pugh’s
“Total Design Approach” had a significant influence of the way in which the PDS
was generated for this project. Pugh’s Product Design Elements that made up the
Design core of his PDS document are shown in Figure 18 below. This provides a
good example of what sort of information goes into a full PDS.
34
Figure 18: Stuart Pugh’s Design Core [33]
Each and every Element’s constituent parts must have a measureable value so that
it can be clearly seen as to whether or not the design has satisfied the PDS.
However, given the time and detail involved in an industrial level PDS where such
detail is a requirement, this project used a slightly more simplified version. This
version which contains a listing of the different design attributes and considerations
that must be taken into account for the design to be successful in a clinical
environment. One of the first steps in generating requirements, and also in aiding
with concept generation in the later stages of the project, is to look into existing
designs and patent research. This allows the examination of features from
competitors or similar designs, and ensures that such a feature is not missed in the
design of this device.
35
4.3.2 Commercially available designs and patent research
As mentioned previously, the only commercially-available designs for the assembly
of the head/neck taper junctions are the orthopaedic hammer and impactor
methods. An in-depth patent search was carried out to establish what other like-
minded or similar and applicable designs already existed. Samples of some of the
more interesting designs are shown as follows. Some of these have made an
influence on the design of the device rig as can be seen later on in the Design and
Development stage.
Figure 19: Controlled Force Hammer [35] Figure 20: Controlled Force impacting device [36]
Figure 21: Handling Device for Hip Implant [37] Figure 22: Hip Joint Prosthesis and Fitting Tool [38]
36
Figure 23: Device for Handling Hip joint Heads [39] Figure 24: Head holder and impactor [40]
Figure 25: Method of applying Femoral head Resurfacing [41] Figure 26: Nail gun Patent 1 [42]
Figure 27: Nail gun Patent 2 [43] Figure 28: Wire Shelf Driver [44]
As can be seen from Figure 25 (resurfacing), and from Figure 26 to 27 (nail guns),
the patent search extended out to different devices with a similar purpose, which in
37
this case involved delivering an impact or maintaining an alignment. Rough notes
were taken during the patent search to keep track of any good ideas, which could
then be applied directly or manipulated to fit into the device proposed in this project.
Figure 29 and Figure 30, shown below; display two more applicable technologies
that could be of use for the concept generation stage later in the project.
Figure 29: Automatic Centre Punch [44]
Figure 30: Inserter jaw for knee prosthesis impaction and extraction [45]
38
4.3.1 Medical device standards review
Medical Device Classifications exist to grade the level of risk that a medical device
poses to a patient or user; the higher the grading, the more stringent the regulations
imposed on the development and manufacture of the device. There are different
classification systems for both the EU (EU/ISO [46]) and USA (FAA/ISO [47]), and
as the risk or grading increases, so too do the design regulations imposed by the
standardisation bodies to meet their audit requirements. The two grading streams
are illustrated side by side in an extract from medical Device Design by P.J.
Ogrodnik [48], as shown in Figure 31 below.
Figure 31: Comparison in grading between EU and USA Device Classification [48]
The device proposed in this project received the lowest grading in both systems
(grade I), meaning it has the lowest risk, as it does not remain inside the patient and
is in the same class as other common surgical tools, such as bone drill bits. This
means, as is indicated in Figure 31, that the device design is mainly self-regulated.
Several specific EU and US standards have been established that relate to the
device and are featured and referenced in the PDS, which is found in Appendix 1,
and is discussed in the next step. The purpose of the standard review was to
establish any significant design constraints that would affect the device. However,
as the device is only in an early prototyping stage in this project, it will not be ready
39
for clinical trials, so the standards review is of greater value further down the line in
future clinical design and development of this device.
4.3.2 Generation of PDS
The PDS pooled all of the design requirements acquired through the project so far,
and so took information from the Literature Review, the Surgeons’ Survey (although
left open, pending response from participants), the Standards Review, and the
patent and existing design research. The PDS is a working document, and can be
added to and edited as future work progresses on the development of the device
proposed in this project. The most up-to-date version of the PDS is included in
Appendix 2 [10].
40
5. DEVELOPMENT & EVALUATION
This chapter of the report looks at the generation, evaluation and development of a
concept for the device proposed in this project. It then examines the concept
generation, development, detailed design and manufacture of a proof-of-concept
Testing Rig, to verify the functionality of the overall device concept established in
the first phase.
5.1 Concept Generation and Evaluation
Since the PDS created in the previous chapter was quite detailed and in-depth, not
all of the points covered will be relevant at this stage in the design. It is for this
reason that the PDS was condensed down into its more critical attributes. This
created a less constrained environment to work in when generating creative
concepts. The new condensed PDS will be referred to as the “Initial PDS” from this
point on. Shown below is a summary of the steps taken in this concept generation
and evaluation phase.
Step 1: Creation of Initial Product Design Specification (PDS)
Step 2: Discretisation of design challenge
Step 3: Radial Thinking
Step 4: Visual Concept Analysis
Step 5: Critical Assessment and Selection
Step 6: Further Investigation of Powering Method
Step 7: Development of Final Powering Concept
Step 8: Mechanical Feasibility of Chosen Design
Step 9: Development of proof-of-concept Testing Rig
41
5.1.1 Initial Product Design Specification (PDS)
A full PDS was developed for a prototype device aimed at use in clinical trials but for
the purpose of this project, which will only be tested in laboratory conditions, the
original PDS was condensed down. This was carried out in order to focus on the
fundamental design requirements and to allow more creative freedom for concept
development. The PDS used for the project at this stage is shown below.
1. Performance 1.1 Must hold head taper axially aligned with neck taper axis
1.2 Must deliver impact axially aligned with neck taper axis
1.3 Must deliver adjustable impact from 4KN - 6KN to +/- 0.5KN
1.4 Must isolate impact to head-neck taper junction
2. Customer 2.1 Must be able to use with varying head size
2.2 Must be able to use with varying stem size
2.3 Must be able to position itself inside cavity created by incision
2.4 Easy to disassemble for cleaning and sterilization
3. User Friendly 3.1 Weight, preference to be lightweight
3.2 Easy to use, quick, low task complexity
4. Manufacture 4.1 Easy to Manufacture
5. Cost and Materials 5.1 Meet requirements above at minimum cost
5.2 Meet requirements above at minimum material use
Table 5: Initial PDS
42
An initial sketch was made at this point to record any design ideas that had come to
mind so far. This initial sketch is shown in Figure 32 as follows.
Figure 32: Initial sketch to capture ideas
5.1.2 Discretisation of Design Challenge
Even though the PDS was condensed down, the design challenge was still quite
complex. For simplification, this design challenge was split into four sub-systems so
that the concept generation could focus on the four key performance requirements
listed in the Initial PDS. These four key objectives are labelled with letters for clarity
during concept generation. The assignment of these letters is shown below.
(A). Hold head taper axially aligned with neck taper axis
(B). Hold impactor axially aligned with neck taper axis
(C). Deliver adjustable impact between 4KN and 6KN to +/- 0.5KN
(D). Isolate impact to head-neck taper junction
43
5.1.3 Radial Thinking
Radial thinking was used to expand on different concepts and help to develop and
record different concept ideas. Each of the four key objectives, A to D, were listed in
a bubble in the middle of a blank page and ideas stemmed outwards from this
starting point. Two examples of this exercise are shown as follows. Figures 33
shows the development of Objective B, and Figure 34 shows the development of
Objective C.
Figure 33: Development of Objective B
44
Figure 34: Development of Objective C
5.1.4 Visual Concept Analysis
After writing down all the different methods of achieving the objectives, the next step
was to roughly sketch them out so that they could be reasoned out visually and
analysed (keeping the Initial PDS in mind). For comparison to the method currently
used by the surgeons, a datum has been included at the beginning of each section
(where one exists). The rough sketches of the concepts are grouped within the four
key objective headings as follows.
(A). Holding head taper axially aligned with neck taper axis
*DATUM* Surgeon press fitting the head on the neck prior to impact
45
(A1). Three Prong Flexible Support and Centring Cone
Figure 35: Three Prong Flexible Support and Centring Cone Sketch
(A2). Semi-Cup + Centring Cone
Figure 36: Semi-Cup + Centring Cone Sketch
46
(B). Holding impactor axially aligned with neck taper axis
*DATUM* Surgeon holding impactor aligned by hand
(B1). Bent Hex-Rod
Figure 37: Bent Hex-Rod Sketch
(B2). Bent Rod Circular Profile
Figure 38: Bent Rod Circular Profile Sketch
47
(B3). Split Cup/Split Mould
Figure 39: Split Cup/Split Mould Sketch
(C). Deliver adjustable impact between 4.5KN and 11.5KN within +/- 0.5KN
*DATUM* Surgeon providing a hammer blow from a standard hammer
(C1). Slide Hammer - Direct Impact
Figure 40: Slide Hammer - Direct Impact Sketch
48
(C2). Slide Hammer - To Charge Spring
Figure 41: Slide Hammer - To Charge Spring Sketch
(C3). Magnets (forced together when opposing poles)
Figure 42: Magnets Sketch
49
(C4). Electro-Magnets (Solenoid Actuator)
Figure 43: Electro-Magnets Sketch
(C5). Screw Mechanism - No Impact
Figure 44: Screw Mechanism - No Impact Sketch
50
(C6). Screw Mechanism - To Charge Spring
Figure 45: Screw Mechanism - To Charge Spring Sketch
(C7). Lever - To Charge Spring
Figure 46: Lever - To Charge Spring Sketch
51
(C8). Pneumatic Piston
Figure 47: Pneumatic Piston Sketch
(D). Isolating impact to head-neck taper junction
*DATUM* Surgeons hand can grip the stem during impaction to prevent the impact
from being transferred to the patient
(D1). Rod Inserted In Stem Hole
Figure 48: Rod Inserted In Stem Hole Sketch
52
(D2). Mechanism to Hook around the Lips at Base
Figure 49: Mechanism to Hook around the Lips at Base Sketch
5.1.5 Critical Assessment and Selection
Each of the subsystems has been scored against their key design requirements and
the relevant Initial PDS requirements from 0 to 10, ascending in increments of two.
They are scored by how well they satisfy each of the requirements, as explained
below.
0 = “not at all”,
2 = “a little”,
4 = “below average”,
6 = “above average”,
8 = “very good”
10 is “perfect”
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The result of this exercise is the selection of concepts to address each of the four
key performance requirements. This exercise was carried out using an excel spread
sheet and is shown on the following page in Table 6. The highest scoring concept
from each of the four sections was highlighted in yellow.
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Table 6: Scoring Table for Sub-System Concepts
55
As the outcome from Table 6 has shown, the following sub-system concepts have
been chosen and are listed as follows.
(A1) 3 Prong Flexible Support + Centring Cone
(B1) Bent Hex-Rod
(C8) Pneumatic Piston
(D1) Rod Inserted In Stem Hole
Since the main function of the device is key requirement C (“Must deliver adjustable
impact from 4KN to 6KN, to +/- 0.5KN”) and the second and third ranked ideas in
this category, which were “Electro-Magnets” (C4) and “Lever to charge spring” (C7),
also scored relatively high, all of the top three designs in this category will be looked
into in more detail before finally settling on a single concept. It is also worth
mentioning that all combinations of selected successful concepts listed in the
paragraph above function collectively, and do not work against each other’s
individual aims in the overall device design.
5.1.6 Further Investigation of Powering Concept
As mentioned previously, the top three design concepts to achieve Objective C are
as follows:
1. Pneumatic Piston
2. Electro Magnets
3. Lever to Charge Spring
Due to the importance and influence of correctly achieving objective C, each of the
top three designs were explored in more detail to ensure their engineering feasibly
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in the design. This investigation was performed by looking into existing products that
were applying these three powering methods, and checking the suitability of each
method for the device in this project. These are examined as follows, starting with
the Pneumatic approach.
Pneumatic Piston
One of the best products to look at to examine the functionality of the different
methods of powering a device that provides an impact is the Nail Gun. A pneumatic
Nail Gun is shown in Figure 50 [49], below.
Figure 50: Pneumatic Nail Gun Illustration [49]
Figure 50 illustrates the basic process by which a pneumatic system works and it is
clear that it could be used in the device for this project. Pressurised air is provided in
the operating theatre up to 6 bar and pneumatic nail guns can run from 4 bar up to
22 bar for very heavy duty work. It is a clean and sterile method of operation.
However, it would reduce the simplicity of the design as the use of pressurised air
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can become quite complex and expensive when designing and manufacturing. This
project is trying to provide the simplest possible powering method, so for this reason
the pneumatic approach does not seem to be the best fit.
Electro magnets
Electro magnets, or specifically in this case electro solenoids, can be used to
electrically initiate magnetic fields, which can propel objects to create an impact.
This type of system is explained once again using a nail gun example in Figure 51
[49] below.
Figure 51: The Solenoid Powered Nail Gun [49]
Again, it is clear that this sort of technology could be used to power the device for
this project. Electricity is available in the operating room to power other electric
medical devices, and battery packs can also be used to power such a system.
However, the use of electro solenoids means that there will be electromagnetic
fields generated which can interfere with other medical devices and patient implants
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that may be close to the device when in use. This also, much like the pneumatic
option, this greatly increases the complexity in the design and means that the device
will have to abide by more constraining standards during the design process. This
will add difficulty and complexity to the future work on a clinical device, and thus
rules out this technology as a possible option.
Lever to Charge Spring
The final option for powering the device is a charged spring, which is compressed
using mechanical advantage, such as a lever system. An electrically powered
mechanical spring system is shown in Figure 52 below, again using an example of
an electric powered nail gun.
Figure 52: Electric Powered Nail Gun [49]
This sort of powering method would be the simplest to design, and could be
adjusted to remove the need for an electric power system. By using a pure
mechanical system, it would simplify the design even more and make the device
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more sustainable and reliable with no dependency on other inputs such as electricity
and compressed air. The surgeon could use their energy to provide the work
required to compress/charge the spring could be made easier with a leverage
system. An example of the employment of this sort of powering mechanism is
demonstrated in a simple can-crushing device as shown in Figure 53 below.
Figure 53: Can-Crushing Device [50]
Final Selection of Powering Method
After reviewing the different strengths and weaknesses of employing each of the
three different powering methods, as discussed previously, the option that seemed
the most appropriate to this design was the spring compressed/charged by a
mechanical advantage or levering system. This concept was then developed further
in the next step of this process.
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5.1.7 Development of Final Powering Concept
Now that the method which would power the device had been chosen, the next step
was to develop the design in more detail to prove that it could actually work.
There were three main design objectives that had to be met for the device to be able
to function. The first was to confirm the final leverage method to compress the
spring. The second was to come up with a way in which the device could deliver an
adjustable impact (which had not been focussed on previously). Finally, the third
objective was to design a trigger/release mechanism to actuate or initiate the
impact.
Mechanical Leverage System
This stage involved more sketching and research, but this time just focussed on
leveraging systems. Items such as hand-operated juicers, in which they compress
the fruit to extract juice, were seen as applicable to the design of the device. A
rough sketch showing the integration of such a system into the spring compression
system is shown in Figure 54 below.
Figure 54: Adapted Juicer Sketch
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More can-crusher products were also investigated, and an example of one of the
sketches trying to use this approach is shown in Figure 55 below.
Figure 55: Adapted Can Crusher Sketch
These designs all seemed as though they would need quite a long handle to
produce an adequate amount of enough force to compress a spring stiff enough to
provide the impact energy needed for the device. One way of shortening the
handles was to use two handles simultaneously. This is the sort of leverage system
that is used on a typical wine bottle corkscrew. A sketch utilising the application of
this design in the concept for this device is shown in Figure 56 as follows.
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Figure 56: Corkscrew Lever System Sketch
This sort of mechanism could be attached onto the end of the device, and the
surgeon could use both hands to push the levers down to the sides of the device.
This would compress a spring that can be held in place by a locking mechanism and
released by a trigger when ready for use.
Adjustability
The spring would need to be adjustable to between 4KN and 6KN as mentioned
previously, and so a mechanism would need to be designed to allow such flexibility
over the device’s output. Several spring adjustment designs are shown in the
Figures 57, 58 and 59 as follows.
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Figure 57: Twisting Adjustment and Release Concept Sketch
Figure 58: Gearbox Style Spring Compression Adjustment Concept Sketch
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Figure 59: Spring Compression adjustment System Sketch
Trigger/Release Mechanism
A trigger/release mechanism would also be required so that the spring could be
compressed away from the patient, locked in the compressed position, and then
brought to the patient for use so that it could be discharged when the surgeon had
the device in place. Several trigger mechanism concepts are presented in Figure 60,
61 and 62 as follows.
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Figure 60: Slotted Trigger Release Mechanism Sketch
Figure 61: Firearm Trigger Concept Sketch
Figure 62: Handle Trigger System Sketch
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Selection of the Concept for Objective C
The final selection of the concept for the device is shown in Figure 63 below. This
incorporates the corkscrew method of leverage seen in Figure 56 previously,
positioned out of sight to the left of the lower sketch within Figure 63 below. It also
incorporates an adjustable force mechanism behind the spring and a trigger
mechanism as shown.
Figure 63: Final Developed Concept Sketch
To give an indication of the three dimensional shape of the device, Figure 64 as
follows, illustrates a conceptual representation of the tubular casing which surrounds
the spring.
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Figure 64: Tubular Casing Surrounding Spring Sketch
5.1.8 Mechanical Feasibility of Chosen Concept
Before progressing further, the leverage mechanism must be validated theoretically
to ensure that it could realistically function and be used by a surgeon. A rough
sketch of the device moving through the charging motion is shown in Figure 65
below from left to right.
Figure 65: 3 step sketch illustration of corkscrew charging method
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The leverage force has been simplified and marked out on the Figure 56 which is
shown again below and renamed Figure 66 for clarity.
Figure 66: Force Balancing Free Body Diagram
Analysing the diagram in its static state, it can be assumed that all forces acting on
the spring and lever are balanced, as it is not in motion and the spring is loaded in
compression. L1 is the distance from the centre of the gear wheel to the point at
which the gear teeth mesh on the ridged shaft. L2 is the distance from the centre of
the cog wheel to the end of the handle. F1 (take as 6KN) is the spring force acting at
this point in the direction of impact. F2 is the resultant force of the spring acting on
the handle.
Taking L2 as 0.3m (300mm) and L1 as 0.01m (10mm) for a trial basis, F2 can be
found and it can be established whether or not it is humanly possible to compress
and hence charge the device.
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Using static force balancing analysis, Equation 1 can be derived and is as shown
below.
𝑭𝟐 = 𝑭𝟏×𝑳𝟏𝑳𝟐 (1)
Substituting in the values;
𝐹2 = (6 × 10 ) × 0.010.3
Solving for F2;
𝐹2 = 200𝑁
Since there are two levers used on the device this force can be divided by 2, so;
𝐹2 = 100𝑁
To put this in terms that are easy to comprehend, the answer is put in terms of a
weight hanging in the opposing direction to F2 (as seen in Figure 66). The weight
can be found using Equation 2 shown as follows;
𝑭 = 𝒎𝒈 (2)
Where;
g = acceleration due to gravity (constant = 9.81m/s2)
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Substitute in known values;
100 = 𝑚(9.81)
Rearrange and solve for m;
𝑚 = 10.2𝐾𝑔
Where;
Kg = Kilogram
This means that a 10.2Kg weight could be hung on one side, and it can be
visualised that the same force could be mirrored onto the other handle to statically
hold the whole device in place. Since this is has been sized for 6KN, it is the
toughest possible scenario. This is thus deemed an acceptable method as the
handles can be made longer and other design attributes can be manipulated to
reduce this value. So far, the mechanism has proven itself enough at this stage of
the design to continue in the process.
The next step was to size a spring capable of providing an impact magnitude of up
to 6KN. Using the impact impulse equation (Equation 3) below;
𝑰𝒎𝒑𝒖𝒍𝒔𝒆 = 𝑭. ∆𝒕 = 𝒎. ∆𝒗 (3)
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Where;
F = Impact Force
Δt = Impact duration (time over which impact occurs)
m = Mass
Δv = change in velocity
The force used in this equation is 6KN, since it is the highest end of the scale.
The mass used for this calculation was based on the average mass of an
orthopaedic mallet, which was found to be approx. 0.4Kg (kilograms).
Since the impact duration is unknown, a previously-recorded impulse value was
taken from a PhD student at the University of Bath who had carried out a study on
impacts and had acquired this data for 2KN, 4KN and 6KN impact forces. It should
be noted that the tip material used during these tests is unknown, and this may have
a large effect on the testing results. The impulse recorded for 6KN was 11.1Ns
(newtons per second).
The change in velocity (Δv) is equal to the initial velocity (u) minus the final velocity
(v), i.e. Δv = u – v. The final velocity is zero since the mass comes to a complete
stop. These new values can be subbed into Equation 3 as follows.
11.1 = 0.4(𝑈 − 0)
Rearranging and solving for U;
𝑈 = 27.75 𝑚/𝑠 Where
m/s = metres per second
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Now that the initial velocity has been found, this can then be used to find the kinetic
energy (KE) at the point of impact. This can be found using Equation 4.
𝑲𝑬 = 𝟏𝟐𝒎𝒗𝟐 (4)
Substituting in the known values;
𝐾𝐸 = 12 (0.4)(27.75)
Solving for KE;
𝐾𝐸 = 154.0125 𝐽𝑜𝑢𝑙𝑒𝑠
If it is assumed that there are no losses, and the KE at the point of impact is equal to
the Potential Energy (PE) stored in the spring after it has been compressed but
before it has been released, then the KE found in the previous step can be used as
the PE in Equation 5 as follows.
𝑷𝑬 = 𝟏𝟐𝒌𝒙
𝟐 (5)
Where
k = spring stiffness
x = spring displacement
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Since both k and x are both unknown at this point, it is decided to use a spring
displacement (x) of 60mm (millimetres) or 0.06m (meters). This has been chosen as
this displacement should leave enough room for sensitive adjustments to be made
to the spring later in the design process.
Substituting these values into Equation 5;
154.0125 = 12𝑘(0.06)
Rearranging and solving for k;
𝑘 = 85562.5𝑁/𝑚
Where
N/m = Newton per metre
Using this k value as a guide, a spring could then be sized from a components
catalogue. The spring had to have a minimum k value of 85562.5 N/m but also had
to have a compression displacement range of roughly 60mm to ensure the
adjustability of the spring for different impact force magnitudes.
5.1.9 Development of Proof-Of-Concept Testing Rig
Before any further development could continue on the concept developed at this
point in the project, the basic idea of using a spring to deliver the assembly impacts
74
had to be proven experimentally first. This was to be proven using a testing rig
designed purely for this purpose.
The first step in this process was to size a spring. The k value found in the last
section and the displacement of approx. 60mm was used to source a spring from
Lee Springs. The specifications for this spring are shown in Appendix 3.
It was also decided to use three magnitudes of impact force during testing. This was
done so that a line could be graphed through the three averaged points on an
impact impulse vs. spring compression displacement chart to show the predictability
and repeatability of the spring method. It could also be used as an opportunity to
explore the effects of different tip material on the impactor, and what effect they
have on the process.
To simplify the design, an Instron Impact Loading machine (30KN max load), as
shown in Figure 67 below, would be used to compress the spring to the required
compression displacements. This would make the design stage simpler and faster
to design and manufacture.
Figure 67: Instron Loading Machine [51]
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The key functions of the testing rig were to allow the Instron to compress the spring,
to hold the spring in its compressed state and then to allow the spring to be
released over a load cell in order to measure the impact force administered.
One of the early sketches in the concept development stage for this rig is shown in
Figure 68 below.
Figure 68: Initial Testing Rig
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Figure 68 includes a lever release mechanism, which is actuated by twisting a collar
fixed on the outside of the top cylinder (illustrated in the top left of the Figure). It also
features a threaded shaft with a threaded stopper disc that can be adjusted to allow
varied spring compression displacements. The design was refined further to try to
reduce its complexity, so as to save time during the detailed design phase and
manufacture. Figure 69, below, shows the refined version of the concept for the
testing rig.
Figure 69: Simplified Concept for Testing Rig
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The device could be removed from a solid plate base on which a load cell would be
secured, and then mounted using a special jig. This would be done so as to allow
the Instron to push down the body of the device with the impactor tip placed on a
fixed spigot so that the spring could be compressed inside.
Various trigger mechanisms were generated, with the final idea being a side-acting
lever. This lever would then fit into one of three specifically laid out slots that were
designed to allow the spring to be held in a compressed state under 6KN, 4KN and
just over 2KN of load in the Instron. Figure 70 below, shows the first concept,
followed by Figure 71, which shows the next development, and then finally Figure
72 showing the simplified lever release mechanism.
Figure 70: Initial Lever Design
78
Figure 71: Lever Design Development
Figure 72: Final Lever Design
79
5.2 Detailed Design
The Test Rig concept could now be developed further on SolidEdge. Stress
calculations and considerations could also be made for the manufacture of the
device, and could be followed by, the provision of draft drawings to the Machine
Shop and the manufacture of the testing rig.
5.2.1 Solid Modelling
The design had three specific compression displacement slots, slotted into an
internal impactor rod (visible in Figure 73 below protruding from the top of the
device), which was propelled by the release of the compressed spring. An isometric
view of the finished model is shown in Figure 73 below, with fasteners removed for
clarity. The assembled model is shown at the 6KN load setting.
Figure 73: Final Assembled SolidEdge 3D Model
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5.2.3 Draft Drawings
Once the final solid models had been completed a full set of draft drawings were
produced for the design. These drawing are listed in Appendix 4 and can also be
found towards the end of the report.
5.2.4 Manufacturing
The SolidEdge solid modelling program allowed the interaction between the parts to
become visible, and the manufacturing methods could be taken into consideration.
The Testing Rig was manufactured in a machine shop based in the University of
Bath and so the development of the design on SolidEdge was reviewed in stages
with the Machine Shop Technician that would be manufacturing the Rig. This helped
to simplify the manufacturing stage, as the design was customised to make use of
the most easily-available materials that were currently in stock. The device was
manufactured from steel, with exception of the bushings, which were made from
PVC, and the interchangeable material tips which were made of PVC, Mild Steel,
Nylon and Rubber.
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6. TESTING
This section of the report covers the calibration of the load cell and the testing
carried out on the Rig. The Results from this testing will be discussed in the next
Chapter.
6.1 Calibration of the Load Cell
The first step was to calibrate the Load Cell, which would be used to measure the
impact loading during the Rig testing. This was performed to ensure that the load
cell was fully functional, and also to establish a scale factor so that the output, when
Rig testing, could be provided in newton instead of in volts, which is what the load
cell measures.
An Instron loading machine (max loading of 30KN) was programmed to descend
onto the Load-Cell in steps of 2KN up to 8KN. The Load-Cell was attached to
computer through an Analogue to Digital Card which was linked to a load
measurement program designed for use on LabView. This allowed the load cell
voltage recordings, which were being recorded at a sample rate of 10,000 samples
per second, to be written and stored in a text-file on the hard drive of this computer.
The loading test was performed three times to gain an average value across the
tests for each load, which would allow for any errors or outliers. After the testing was
completed text-files were then imported into Matlab and the voltage was plotted
against time. Figure 74 as follows, shows the graph for the first test.
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Figure 74: First Calibration Test plot of Voltage Vs. Time
It is clear from Figure 74 that the line sloping downward from right to left has four
small steps, which represent 2KN, 4KN, 6KN and 8KN Loads. These loads are
represented on the graph in volts. The voltage at each of these steps was recorded
and inserted into a spread sheet on excel. Table 7 below shows the data recorded
from the three tests and shows the average voltage achieved at each load.
Table 7: Data recorded during Load Cell Calibration
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This Data was then plotted and a trend line added across the average points so that
the slope, and hence the scale factor, could be established. This chart is shown in
Figure 75 below.
Figure 75: Load Cell Calibration Test Data Plotted on Graph
The close proximity of the trend line to the points on Figure 75 showed that the load
cell was fully functional and the change in voltage for each load was proportional. It
is clear to see from Figure 75 above that the scale factor is -2678.5. This scale
factor was then programmed into LabView prior to testing so that the text-file
readings were produced in newtons as opposed to volts.
6.2 Rig Testing
After the Load Cell was calibrated, verified as fully functional and the scale factor
was established, the Rig Testing could begin.
y = -2678.5x + 13.413
0100020003000400050006000700080009000
-4.0000 -3.0000 -2.0000 -1.0000 0.0000
Load Vs. Voltage
Load Vs. VoltageLinear (Load Vs. Voltage)
84
6.2.1 Procedure
The testing involved measuring and recording several variables. These variables
are listed as follows.
1. Final displacement of spring during spring compression on Instron
2. Final load recorded during spring compression on Instron
3. Impact data recorded via LabView
Variable 1 and 2 were read directly from the computer monitor hooked up to the
Instron. The LabView data was analysed later using Matlab.
The Testing procedure involved several steps. The first step involved slotting the
required material tip into the hole at the tip of the impactor rod and then holding it in
place with the grub screw. The next step was to mount the Spring Section of the
Testing Rig onto the test fixtures, which had been designed and manufactured as a
part of this project. They held the rig in a safe and secure position during the
compression of the spring on the Instron. Figure 76 below shows the two fixtures
mounted on the top and bottom of the Instron attachment points.
Figure 76: Custom Mounting points, close up view of top, close up view of bottom
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Figure 77, as follows, shows the Spring Section of the Device fixed securely in the
mounting points.
Figure 77: Spring Section in mounting points, close up view of top, close up view of bottom ger
The top fixture was then lowered to the point where the device was securely in
position. The spring section was then compressed in very small increments until
spring compression was recognised visually by watching the top of the impactor rod
rising up out of the casing. Once this point was reached the Instron displacement
and load measurements were set to zero and the spring was slowly compressed
until the release lever could fit all the way into the assigned slot in the impactor rod
(for that particular test). Once the lever had been moved into place in the slot, the
displacement and load were then recorded on an excel spread sheet.
The next step was to raise the top fixture to its original position, insert the safety pin
which held the release lever in place, remove the spring section which was then
mounted onto the base plate which has the load cell fixed to it with two bolts. The
first round of material testing at just over 2KN was carried out without a rubber base
between the base plate and the table, to which the base plate was held in place with
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g-clamps. Figure 78, as follows, shows the base plate mounted to the table with and
without the rubber base and finally with the spring section sitting top of the base
structure prior to the assembly nuts being screwed attached.
Figure 78: Base plate fixed to table with and without Rubber Base
The Spring Section of the Device was then fixed in place with nuts above and below
its lower flange (eight nuts below, and four above the flange, in total). The LabView
program was then initialised, the offset reset (for each test) and the sampling
started. The safety pin was then removed from the lever and a copper faced mallet
was used to aid the quick release of the lever by impacting the end of the release
lever to ensure a swift removal of the lever from the impactor rod’s path.
This procedure was repeated for each individual impact test. To provide a
walkthrough of one such test a 3 minute video of one impact test was recorded with
a walkthrough narrative and posted to a DropBox online account. This video can be
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accessed by copying the following file link into the address bar on an internet
browser.
https://www.dropbox.com/s/6o668aoik0xtirz/video-2013-08-21-12-46-46.mp4
6.2.2 Data recorded
The materials were changed over after each test. The material testing order was
steel, nylon, PVC rubber and then back to steel again, which started off the next
round of testing. This allowed the rubber time to return to its original shape and
elasticity, as it temporarily deformed following impaction.
Figure 79, as follows, displays the displacement and load data which was recorded
during the Rig testing on an excel spread sheet. This figure also contains notes that
were taken to record changes in material tip samples following the failure of a
material tip during a test.
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Figure 79: Table of Data recorded from Instron
89
The impact data recorded using LabView was extracted from the text file output
using Matlab and then inserted into an excel spread sheet for analysis. The
parameters analysed for each impact test were as follows.
1. Peak Force recorded during impact in Newtons
2. Duration of Max Peak in Seconds
3. Duration of impact
These were extracted from graphs generated on Matlab and then fed into the excel
spread sheet. Figure 80, below illustrates the 3 parameters recorded from these
graphs.
Figure 80: Test 2, Steel, 2KN (with rubber base)
The extrapolated load cell data for the 2KN loads are shown in Figure 81 as follows.
Only one round of data was taken without the rubber base present, to see effects of
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vibration damping. The rubber can be considered as a representation of the soft
tissue in a patient as it absorbs some of the impact force from the Testing Rig.
However, it must be noted that an error occurred and the steel test wrote over the
Nylon test, hence why they both have the same data in the single round of testing
without the rubber base. The analysis of this data is covered in the next section of
the report.
Figure 81: Extrapolated Load Cell Data, >2KN
The impulse data was calculated by multiplying the “Peak Force” by the “Duration of
Impact”, using Equation 3 as stated previously in the report.
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Figure 82: Extrapolated Load Cell Data, 4KN and 6KN
The extrapolated load cell data for the 4KN and 6KN loads are shown in Figure 82
as follows.
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7. RESULTS AND DISCUSSION
This section of the report covers the analysis and discussion of the Instron and Test
Rig Data acquired in the previous chapter and also an evaluation of the Testing Rig.
7.1 Evaluation of Instron Data
During the testing phase, some notes were made on the spread sheet where the
Instron data was being recorded. For example, as can be noted from the comments
on Figure 79 shown previously, both PVC and Rubber failed on the first round of
testing at 4KN of loading on the Instron. New replacement tips for both materials
failed after Round 2 (their first impacts) at 4KN loading. Figure 83 below shows
images of the PVC and Rubber Tip materials which were destroyed on Round 1 of
the 4KN Testing.
Figure 83: Images of Failed PVC and Rubber Tips at 4KN Load
93
It was also clear from the “average max displacement” figures shown previously in
Figure 79 that the Rubber Tip Sample compressed during loading on the Instron to
approx. two thirds of its original thickness. This pre-deformation may have reduced
the ability of the material to lower the impulse force (as it would normally prolong the
impact duration of the peak force as seen from the load cell data).
There was some error present in the inconsistency at the point at which the load
and the displacement were reset to zero on the Instron before the spring was
compressed. There was a learning curve during the experimentation and it was
discovered towards the end of the testing that the best time to reset the load and
displacement readings to zero, before compressing the spring, was to watch to see
the top of the Impactor rod move in relation to the devices outer structure. This way
it was sure to be the point at which the spring was about to experience actual
compression, as opposed to the rig just settling out. However, even taking this error
into account the average max displacements during loading for the four materials
agree with the resistance of the materials to compression during loading. Steel
resisted compression the best, followed by Nylon and PVC in joint second and then
followed by rubber last (as confirmed by the load cell data).
7.2 Evaluation of Load Cell Data
The loads experienced during the test were of a far greater magnitude than
expected. This error can be traced back to the use of the Impulse value taken from
the PhD student’s previous study. It is now clear from the values provided in Figures
81 and 82 that the impulse force reduces significantly on the 2KN loading tests (with
rubber base) from 5142.5 Ns for steel, to 4556.18 Ns for Nylon, to 3479.28 Ns for
PVC, down as low as 692.14 Ns for Rubber. This shows that the tip material had an
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extremely large effect on the duration of the max peak which in turn affects the
resulting calculation of the impulse force. It is important to note that when using
these original impulse values the tip material used in the study in which the impulses
were recorded, was not provided to this project. This would explain to some degree
the significantly high impact forces recorded, especially with steel, which in many
cases exceeded the measurement band of the Load Cell. As per the specifications
on the Load Cell it has a max measurement capacity of 5,000 lbs (or 2267.69 Kg, or
22,246 N). The Load Cell can only measure up to 10 Volts which works out as
approximately 26,785 N, when referring back to the scale factor. It is clear that the
bandwidth of the Load Cell could not cope with the large magnitudes of force being
delivered. This brings into question the remaining results as the forces being
recorded were far greater than what was to be expected. When the Steel testing
was performed for the 6KN loading it was deemed that the load cell had been
damaged as the load reading following the impact was set permanently on approx.
25KN. Further analysis of the cables attaching the load cell to the computer was
carried out using a dummy transducer and no problems were found. However, when
testing the resistance across a wheat-stone bridge linked into the load cell an
imbalance was recorded. This indicated that at least one of the strain gauges has
been damaged and so the testing could not be continued.
Another important factor related to the experimental impulse values sourced for this
report was that that value was achieved through monitoring the assembly of a head
on a neck taper and so this would have a displacement as the head moved down
the neck taper, as it was driven by an impact. The load cell would have a much
smaller increment by which it would deflect and hence would increase the impulse
force as the peak force would spike extremely high (as can been seen from the load
95
cell data) due to the extremely sudden momentum change, as it bounces off the
load cell.
7.3 Evaluation of Testing Rig
Despite the greater peak forces than expected, the Testing Rig performed extremely
well given that the load cell failed before the Testing Rig. It functioned safely under
the loads and was quick and simple to use. The only improvements for future use
would be shortening the four threaded studs holding the spring section to the base
plate as this could be a little time consuming screwing the nuts on and off the long
sections when assembling and disassembling the rig during tests. The edge of the
release lever that fitted into the slots came under great deal of stress and future
designs may benefit from heat treating to harden the edge to reduce wear when
removing the lever under load.
7.4 Discussion
To improve the testing in the future, a hip model where the head/neck displacement
and impulse force during impaction is known, and tip material and size used should
be known prior to spring sizing calculation. A single tip of nylon should suffice for the
testing as the Nylon survived much higher impulses in the experiment in this project.
Instead of a bolt screwed into the load cell, the same hip model as mentioned above
should have its stem cut down to size so the base of the neck taper can be attached
directly to the load cell. The head/neck assembly can them be pulled apart using
pull-off and twist-off tests and compared against control specimens that have been
assembled using a mallet and impactor.
96
8. CONCLUSIONS
This section looks at the overall outcome from the different sections of this project
and their contribution to the overall aim of designing and developing a medical
device to improve the assembly of head/neck taper junctions in MTHRs.
To start with, a significant literature review was carried out for this project which
resulted in the definition of fundamental design requirements for the proposed
device. These requirements were based on an analysis of the most relevant and
credible sources available.
The user needs and design requirements developed in the next stage of the project
were of significant value, particularly the Surgeons Survey and the PDS. The
Surgeons Survey, although the feedback came late in the projects life it is still of
great value to this project and other studies in the region of MTHR taper junction
analysis. The Surgeons Survey gathered relevant information from over one
hundred specialists in the field of Orthopaedics. There is considerable future work in
analysing the data provided in this feedback, but it may hold significant findings to
help further understand the problem at hand and aid in the development of the
device developed in this project. The PDS contains a wealth of design attributes,
considerations and standards for which future generations of the device design will
come to find more relevant as the design develops. It has also helped add clarity to
the feasibility of producing such a device, in so much as medical device
classification and the applicability of certain standards.
The generation and selection of a concept for the final working device not only aids
the future development of the device but again also proves the feasibility of the
device. The final concept shows that a collection of simple mechanisms can easily
satisfy the design requirements established earlier in the project.
97
The development and manufacture of the Testing Rig has produced a finished
device which can be reused for future testing or can be manufactured again on a
smaller scale to suit a smaller spring size. All of the manufacturing draft drawings
are contained in the Appendix and only need to have the dimensions scaled down
and another smaller version could easily be produced.
The data acquired from the testing phase has shown the dramatic influence that the
tip material has on the impulse force. It has also uncovered improvements for future
testing, such as impacting a head/neck assembly fixed to a load cell and using a
smaller spring size, followed by comparing the assembly and disassembly data with
specimens assembled using a mallet and impactor.
Overall, this project has produced a detailed final design concept which can meet
the design requirements established in this project. It has also produced a testing rig
capable of aiding the laboratory development of this design concept. The feasibility
and benefit of developing the design concept has been proven in every stage of the
project
A significant amount of future work is still required to bring the proposed device to
market. It is clear from every stage of this project, that by continuing the
development of this device, it can contribute to the reduction in early revision
surgeries on MTHRs.
98
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101
11. APPENDICES
APPENDIX: 1
SURGEONS SURVEY RESPONCE
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115
APPENDIX: 2
PDS [10]
116
1. Performance
1.1 Must axially aligned seating of head on neck taper axis prior to impaction
1.2 Impact must be delivered in axial alignment with neck taper axis
1.3 Deliver impact force of between 4KN and 6KN, adjustable to 0.5KN
1.4 Must try to isolate majority of impact to head/neck taper junction
2. Customer
2.1 Must be able to facilitate a range of different head sizes (Determine using Surgeons Survey)
2.2 Must be able to fit into the exposed cavity in the patient created by the incision (Surgeons
Survey will determine the exact figures)
3. Medical Standards
3.1 Must comply with ISO13485:2003/AC:2007, has been classified as Class 1 Medical Device
4. Environment
4.1 Withstand regular exposure to temperatures up to 131 Degree C, during autoclave
sterilization as per EN ISO 17665-1:2006 [52]
4.2 Resist corrosion from saline, blood and cleaning detergents
4.3 Handle being thrown onto tray or dropped from approx. chest height and resist indentation
from other metal objects during cleaning and use
4.4 During Manufacture: Cannot be contaminated by any animal by-products, take note for
cutting fluids, solvents, lubricants, acids (plating and cleaning) to prevent transmission of
Creutzfeldt–Jakob disease [33]
4.5 During Storage: kept in trays conforming to ISO 11607-1, CE Mark or FDA clearance [52]
5. Maintenance
5.1 Must be low Maintenance
5.2 Must be easy to disassemble, reassemble and be convenient to sterilize and store
5.3 Minimise number of parts
5.4 Indicate disassembly on the device for ease of use or make it intuitive enough to use so that
it does not require instructions
117
5.5 Make assembly and disassembly “fail safe”, i.e. design for error
5.6 Preferably disassembly and reassembly does not require tooling
5.7 Must be able to be cleaned via autoclave [52]
5.8 Must be able to use medical grade lubricating oil suitable for steam sterilization, if lubrication
is required
5.9 Product should include “smart” design features that indicate clearly to the maintenance
provider when any parts need to be replaced (such as a line mark on the impactor surface if it is
prone to wear)
6. Materials
1.1 Stainless Steel, for cost and ease of manufacturing and sterilisation
7. Safety
7.1 Carry out a Risk Analysis as per the methods recommended in BS ISO 14971:2012
“Medical Devices. Application of Risk Management to Medical Devices”
7.2 Address the usability of the device by following BS EN 62366-2008 “Application of Usability
Engineering to Medical Devices”
7.3 Minimise any crevices or rough surfaces where it may be difficult to clean or dry after
cleaning to ensure effectiveness of cleaning
8. Testing
8.1 Use Head Pull-Off test ISO 7206-10 and Head Twist-Off test ISO 7206-9 to judge success of
device
9. Ergonomics
9.1 Must be able to be operated with two sets of gloves on
9.2 Consider required lighting, force required to grip and operate
9.3 Consider if the device can be operated with one hand as opposed to both hands
10. Weight
10.1 Estimated target weight or limits, source from ergonomic data
118
11. Aesthetics
11.1 Consider colour, shape, form and texture of finish. (could be influenced if an external
company wants the device designed for a particular hip model)
12. Customer
12.1 Gather surgeon’s opinions or expectations face to face, question and answer surveys etc.
Make a questionnaire for surgeons
13. Manufacturing & Manufacturing Facility
13.1 Device cannot be manufactured using any source of animals; this includes animal based
lubrications used for machining
13.2 Device can be manufactured internally in the University of Bath
14. Disposal
14.1 Consider the disassembly and disposal of the device/materials after it has reached the end
of its life cycle
14.2 Recyclability of the materials used in the final device
14.3 Carbon footprint generated by the manufacturing processes etc.
15. Product life Span
15.1 Approx. 5 years
16. Life in Service (performance)
16.1 Used 6 times per day, 5 times per week, for 5 years (approximation)
17. Installation
17.1 Consider the installation of the head into the device to deliver the impact and the spatial
constraints with which the device will have to work (i.e. within minimal invasive or standard
surgery)
17.2 The device must be able to get itself into position within the access space allowed (i.e.
within the confines of the incision)
119
18. Quantity
18.1 Low volume, when compared with mass produced goods which sell millions
19. Documentation
19.1 Keep everything documented in a logical electronic filing system that coincides with the
progressive Steps of the project
20. Legal
20.1 Consider product liability legislation and the potential for “product defect” [33], in terms of
not constraining the operation of the device to prevent possible error or misuse of the device.
20.2 Check legislation for product liability
21. Reliability
21.1 Design for low friction in parts
21.2 Design for low number of parts
21.3 Design for high quality tolerances and precision manufacturing
22. Patents, literature and Product Data
22.1 Check for the possibility of patent clashing
23. Competition
23.1 Investigate into existing or similar product to do the same or similar tasks to this proposed
device and see how this current PDS may vary with that for the other products and make sure
that this PDS has not overlooked anything [33]
120
APPENDIX: 3
SPRING SPECIFICATIONS
!
!
Quantity!1!required!
Price!quoted!over!the!phone!=!£14.11!each!(plus!post!and!packaging!of!£5.99)!
Total!=!£20.01!
(To!be!charged!to!Account!KBHMEIXLE,!as!per!Tony!Miles!request)!
122
APPENDIX: 4
SOLID MODELLING FOR TEST RIG
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
150
20
M10
M10
M10
M10
A
A SECTION A-A
O120
STEEL
NONE
Robin Maguire 08/08/2013
MODULAR HIP IMPACTOR DEVICE
BASE PLATE (Scale 1:1)
08/08/2013 R.M.0
1 0
2
M8 M8
O17
O89,4
16
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
SIDE VIEWPLAN VIEW
STEEL
NONE
Robin Maguire 08/08/2013
MODULAR HIP IMPACTOR DEVICE
PILLAR (Scale 1:1)
08/08/2013 R.M.0
2 0
170M10 (full length of bar)
*** QUANTITY 4 PILLARS ARE REQUIRED ***
16
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
STEEL
NONE
Robin Maguire 08/08/2013
MODULAR HIP IMPACTOR DEVICE
Bottom Cap (Scale 1:1)
08/08/2013 R.M.0
3 0
PLAN VIEW
FRONT VIEW
1010
A
ASECTION A-A
O10
O10
O10
O10
O10
O10
O10
O10
M3
M3 M312
0°
41
150
Hole depth 9mm, thread depth 7mm
5
O21
O25
O34,5
O41
120
68
16
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
NYLON
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
BOTTOM BUSHING(Scale 2.5:1)
09/08/2013 R.M.0
4 016
A
ASECTION A-A
O15
O 21O 25
155
5
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
BOTTOM BUSHING PLATE(Scale 2.5:1)
09/08/2013 R.M.0
5 0
A
A
SECTION A-A
5
O 21O 34,5
40
120°
120°
5,5
O 3
O 3 O 3
R2,7
5
R2,75 R
2,75
3
16
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
BOTTOM DISC(Scale 1.5:1)
09/08/2013 R.M.0
6 0
A
A
SECTION A-A
8
O89
O68
O50
O 10
O 10
O 10
O 10
16
2
27
2
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
IMPACTOR ROD TIP(Scale 1:1)
09/08/2013 R.M.0
7 1
A
A
SECTION A-A10
563
6
O 35O 22
15
6
M10
M4
1215 3
13/08/2013 R.M.1 Lengthened tip & added bores to hold contact materials
16
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
IMPACTOR ROD BODY(Scale 1:2)
09/08/2013 R.M.0
8 1
A
A
SECTION A-A15
515
556
O 18
18
M10
12
6
4,5
13/08/2013 R.M.1 Reduced diameter 12.5mm to 12mm, to reduce weight
16
165180
195
16
3146
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
SIDE VIEWPLAN VIEW
STEEL
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
SPRING TUBE(Scale 1:1)
09/08/2013 R.M.0
9 0
O 41
O50
16
248
22
O 46
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
TOP DISC(Scale 1:1)
09/08/2013 R.M.0
10 0
A
A
SECTION A-A
8
O68
O 50
23
30
O 10
O 10O 10
O 10
O6
16
89
2
54
2
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
TOP BUSHING PLATE(Scale 2.5:1)
09/08/2013 R.M.0
11 016
A
A
SECTION A-A
O 24O 34,5
R 2,75
R2,75 R
2,75O 3 O 3
O 3
5,5
120°
120°
5
40
3
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
NYLON
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
TOP BUSHING(Scale 2.5:1)
09/08/2013 R.M.0
12 0
O 18
O 24
O 28
155
5
16
A
A
SECTION A-A
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
TOP CAP(Scale 1:1)
09/08/2013 R.M.0
13 1
A
A
SECTION A-A
515
30
23
O6 O
10
O10
O10
O10
O24
O28
O41
O 34,5
5 15
M3, Hole depth 9, Thread depth 7
120°
M3
M3
M3
89
12/08/2013 R.M.1 Updated to add large diameter dimension
34
16
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
RELEASE LEVER(Scale 1:1.25)
09/08/2013 R.M.0
14 016
ISOMETRIC VIEW (Scale 1:1)
AA
SECTION A-A
R2
R2
O 6
133
2728
16
8
8
6
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
3X NYLON,3X POLYETHYLENE
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
MATERIAL TIP(Scale 5:1)
13/08/2013 R.M.0
15 0
O 6O 12
512
16
A
A
SECTION A-A
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
REF. Parts List
NONE
Robin Maguire 09/08/2013
MODULAR HIP IMPACTOR DEVICE
ASSEMBLY + PARTS LIST(Scale 1:2.5)
09/08/2013 R.M.0
16 1
A
A
SECTION A-AFRONT VIEW13/08/2013 R.M.1 Updated to include Material Tip
16
ItemNumber
Title Material Quantity
1 Base Plate Steel 1
2 Pillar Steel 4
3 Bottom Cap Steel 1
4 Bottom Bushing Nylon 1
5 Bottom Bushing Plate Steel 1
6 Bottom Disc Steel 1
7 Impactor Tip Steel 1
8 Impactor Body Nylon 1
9 Spring Tube Steel 1
10 Top Disc Steel 1
11 Top Bushing Plate Steel 1
12 Top Bushing Nylon 1
13 Top Cap Steel 1
14 Release Lever Steel 1
15 Material Tip Nylon,Rubber &PE
3x N, 3xR, 3x PE
24
113
1
41
51
61
71
81
91
101
111
121
131
141
151
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 17/08/2013
MODULAR HIP IMPACTOR DEVICE
TEST FIXTURE 1(Scale 1:1)
17/08/2013 R.M.0
X 0X
A
ASECTION A-A
O 31,7O 88
1020
25,5
22,5 O 12,88
83,8
22
ISOMETRIC VIEW (Scale 1:2)
R 6
7 3
41
30
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 17/08/2013
MODULAR HIP IMPACTOR DEVICE
TEST FIXTURE 2A(Scale 1:1)
17/08/2013 R.M.0
X 0X
A
A
SECTION A-A
7015
13
O45
O 50 O 14,5
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 17/08/2013
MODULAR HIP IMPACTOR DEVICE
TEST FIXTURE 2B(Scale 2:1)
17/08/2013 R.M.0
X 0X
O 14,5 O 45
15
A
A
SECTION A-A
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
FRONT VIEW
PLAN VIEW
STEEL
NONE
Robin Maguire 17/08/2013
MODULAR HIP IMPACTOR DEVICE
TEST FIXTURE 2C(Scale 2:1)
17/08/2013 R.M.0
X 0X
11
A
A
SECTION A-A
O 14,5 O 45
A
B
C
D
2345
A
B
C
D
5 4 3 2 1
MATERIAL
PROTECTIVE FINISH
ACTIVITY DATE
CHECKED
APPROVED
TITLE
DRAWING NUMBER SHEET No. ISSUE
UNIVERSITY OF BATH DEPARTMENT OF MECHANICAL ENGINEERING
THIS DOCUMENT IS COPYRIGHT AND THE PROPERTY OFTHE UNIVERSITY OF BATH. IT MUST NOT BE COPIED IN
WHOLE OR IN PART NOR DISCLOSED TO ANY THIRD PARTYWITHOUT PRIOR PERMISSION FROM THE UNIVERSITY.
UNIVERSITY OF BATH 2012©THIRD ANGLEPROJECTION
A3420mm x 297mm
DIMENSIONS IN MM SCALE AT A3 SIZE:DRAWN IN ACCORDANCE WITH BS8888
TOLERANCES UNLESS OTHERWISE STATEDLINEAR ±
ANGULAR ±SURFACE TEXTURE
REMOVE ALL BURRS AND SHARP EDGES0.5 MAX. RADIUS OR 45° CHAMFER
REVISION HISTORY
ISSUE DATE DRAWN APPROVED DETAILS OF CHANGES
DRAWN
NAME
SIZE
1
DO NOT TAKE MEASUREMENTS FROM DRAWING PRINTS. IF IN DOUBT: ASK.
OF
PROJECT
STEEL
NONE
Robin Maguire 17/08/2013
MODULAR HIP IMPACTOR DEVICE
TEST FIXTURE ASSEMBLY(Scale 1:2)
17/08/2013 R.M.0
X 0
FRONT VIEW
X
Distance req. for 6KN
Distance req. for 2KNDistance req. for 4KN
*** DISTANCE THROUGH WHICH THE SPRING CAN BE COMPRESSED IS CHANGED BY USING PART 2A ALONE (FOR 6KN), OR 2A+2B (FOR 4KN), OR 2A+2C+2B (FOR 2KN) ***
A
A
SECTION A-A
1313
22A
2B
2C