Post on 30-Nov-2021
First in Africa liquid organic hydrogen carrier (LOHC) system - a pilot plant for renewable energy storage
by Philllimon Modisha , Gerhard Human & Dmitri Bessarabov, HySA Infrastructure
Table of Contents
• Background & Motivation
• Energy storage technologies
• Chemical storage
• Liquid organic hydrogen carriers
• 1st in Africa LOHC pilot plant
• Conclusions
Background & MotivationHySA Infrastructure CoC
Director: Dr Dmitri Bessarabov
Focus areas: Hydrogen Production
and Storage
Projects:
• Solar to Hydrogen (generation,
compression/ storage)
• Hydrogen storage on/in porous
materials (MOF, CNS)
• Chemical Carriers (Ammonia,
Formic Acid, LOHC)
• Composite Overwrapped
Pressure Vessels
Background & Motivation
LOHC
• New energy storage technologies for efficient and reliable Renewable Energy need to be developed.
• Conventional energy storage system have limitations such as: high costs, long lead time, self discharge, low energy density, safety, etc.
LOHC (liquid organic hydrogen carrier): Hydrocarbon molecule that store/ release hydrogen through catalytic hydrogenation/ dehydrogenation.
A SASOL produced Marlotherm SH® (mixture of dibenzyltoluene isomers) is classified as an excellent liquid organic hydrogen carrier (LOHC).
The high boiling point, low melting point and high H2 storage capacity (1m3 MSH= 624 m3 (57 kg) of H2 ) express Marlotherm SH ® as an excellent hydrogen carrier.
Aslam et al, Separation and Purification Technology 163 (2016) 140-144
Marlotherm SH: mixture of dibenzyltolueneisomers
Liquid Organic Hydrogen Carriers
Comparison of Chemical H2 storage systems
of Chemical H2 storage systems
Okada et al, Technical paper, Technology Development Unit, Chiyoda Corporation, Japan
Liquid Organic Hydrogen Carriers
Examples of LOHC Systems & Selection Criteria
Markiewicz et al, Energy Environ. Sci., 2015, 8, 1035
Selection of a suitable LOHC System
Hydrogen capacity (mass H2 / kg (liter) LOHC system)
Rate of charging/decharging (kinetics)
Selectivity and stability
Melting point and boiling point of carrier fluid
Compatibility to today‘s infrastructure for fuels
Safety aspects
Toxicology and ecotoxicology
Advantages of using LOHC using
LOHCs
© Air Products and Chemicals, Inc., 2010 Pub. No. 352-10-001-GLB
Not consumable like diesel or petrol, only H2 is released.Diesel like properties-easy to transportEfficient : 1kg LOHC= 2.2 kWhLong term storage without self dischargeSafe: Less toxic than diesel, No CO2 / CO emissions, non-flammableEasy to store at ambient conditions
Pumped hydro=100mCAES=2MPaH2 storage underground, 200 barH2 tube storage: 120 bar H2 Storage aboveground 18 bar
Comparison of long term energy storage technologieshnolog
Copyright 2015 Siemens AG
Compressed H2 gas vs LOHC
57 kg H2
1800 kg H2
1,9 MWh
60 MWh
Reversible hydrogen storage
Renewable energy storage
30 bar, 65.4 kJ/molPGM/Al2O3, 150 oC
1 bar, 65.4 kJ/molPGM/Al2O3, 300 oC
Hydrogenation pilot plant
Specifications• H2 consumption: 1000 NL/hr• Max operating pressure :40 bar• Max operating temperature: 300 °C
• Reactor volume: 50 litres• LOHC production: 1,3L/hr (3 kW/hr)• Hydrogenation grade:>99 %
Parametric effects on DBT conversion: Hydrogenation reaction
Liquid Carrier Stability Tests
Lab Scale Hydrogenation system Lab scale dehydrogenation system
Rapid hydrogenation and dehydrogenation for cycling stability
Specifications
• H2 consumption: 4000 NL/hr• LOHC production: 5,5 L/hr
Pre-Commercial System for Hydrogen Storage
Conclusions
• The LOHC hydrogenation plant was successfully commissioned and operational
• Pre-commercial quantities delivered to various customers
• High liquid feed flow decrease DBT conversion
• High DBT conversion can be achieved at 35 bar 180 oC and low flow rate.
• Or 30 bar 150 oC and recirculation to achieve even high degree of hydrogenation >99 %
Thank you!