Net zero and the energy system transition

Existing defect assessments and repair methodologies are aligned with the T/PM/P/11 and T/PM/P/20 management procedures and are adopted to inspect assess and repair the pipelines for defects and take suitable measures to reduce them. However the scope and applicability of the repair techniques in the presence of high-pressure hydrogen remain uncertain. The key questions which form an outline of the project are:

1. What are the different types of defects we may encounter or consider injurious in the presence of hydrogen?
2. What is the impact of hydrogen on each defect type? Have the mechanisms of failure changed for each defect type after hydrogen-natural gas blending?
3. Will the existing repair techniques be applicable under transmission of high-pressure hydrogen and hydrogen-natural gas blends?
4. Can we implement the defect assessment inspection and repair methodologies safely? Are the techniques safe and suitable for the pipeline operations and maintenance teams?

The project seeks to answer the above in addition to understanding the types and extent of repairs across the NTS and assess the impact of hydrogen on the effectiveness of these inspection assessment and mitigation technologies.

This project seeks to improve the accuracy of CV measurement in gas networks which distribute blended gas streams. Element Digital Engineering will address this by first studying the physics of gas blending in the gas network using Computational Fluid Dynamics (CFD). A wide range of simulations will enable the effects of different designs and mixing technologies to be understood in relation to the various gases under consideration. The predictions of these CFD studies will be validated through the design and development of a rig to simulate blending in the network. The overall results of these studies will be used to develop a tool that can be deployed within the gas networks to facilitate the accurate prediction of co-mingling and subsequent CV measurement points supporting the design of blending systems.

The statistical ‘value’ (i.e. risk reduction and cost) of remote hydrogen detectors has been determined through statistical based projects as part of the hydrogen heating programme (HHP). The cost has been shown to outweigh the risk however given hydrogen is not a mature heating solution the cost can be justified in response to risk appetite from key stakeholders such as consumers. This risk appetite is assumed. There is currently no analysis (qualitative or quantitative) into consumers attitudes towards the ‘value’ of remote detectors. This project will begin to explore the perception of risk reduction from remote detectors to be used to compliment the statistical based analysis to paint a fuller picture towards the utilisation and crucially the value of remote detectors.

National Gas has seen a significant increase in the number of enquiries from biomethane developers for connections to the NTS.

There are currently circa 66 projects the connections team have identified as having NTS connection potential with an associated volume of 5.9TWh per annum.

Developers are attracted to the NTS for numerous reasons but the following are the main drivers:

• No injection of propane or odorant
• Capacity and capability

To speed up time to connect to a biomethane facility this project was developed to produce an innovative standardised design for a Minimum Offtake Connection (MOC) in a pit.

Repurposing of natural gas pipelines made of carbon steel for use with hydrogen blends requires a fitness-for-service analysis as part of the hydrogen use safety case. Girth welds of an unknown quality exist in the Local Transmission System (LTS). In hydrogen service these welds would have a greater susceptibility to fracture failure due to material embrittlement caused by interaction of steel material with hydrogen.

Current inspection methods do not routinely inspect girth welds for defects. Deterministic defect assessment models require the use of conservative assumptions for defect sizes material properties and loading. This can lead to overly pessimistic conclusions about the suitability of pipelines with girth welds for use with hydrogen.

More detailed probability-based assessments are required to reduce the inherent pessimism in deterministic calculation methods. This would provide confidence of the safety and allow for greater use of the LTS with hydrogen and contribute to a quicker and cheaper energy transition for the UK gas network.

This project will help WWU to understand considerations for 100% Hydrogen Rollout at a town scale to inform future activity on preparation for repurposing. Areas will be chosen which are representative of different networks housing stock and demographics which will require different approaches and engagement.

National Gas are investigating the use of the National Transmission System to transport hydrogen and hydrogen blends. To support this research and testing is required to understand the risks of high pressure hydrogen transmission including ignition. This project will identify for 100% hydrogen and blends of hydrogen up to 20% the sources of ignition including how the distance of ignition sources affects the likelihood of ignition. It will also investigate the frequency and the different types of ignition events e.g. jet fires. Lastly it will look at the probability of ignition on sites and in pipework.

This project assembles a multi-laboratory team to address high-priority research topics identified by industry related to the blending of hydrogen into the U.S. natural gas pipeline network. PRCI has been contracted by DOE to provide contract and invoicing support which allows additional members to join after project start.

There were four main activities being performed in Phase 1 of the CRADA project that fell under two categories: materials research and analysis. Sandia National Laboratories (SNL) led the materials research on metals which is primarily used for natural gas transmission while Pacific Northwest National Laboratory (PNNL) headed the research on polymeric materials which comprise the natural gas distribution network. Argonne National Laboratory (ANL) was responsible for life-cycle analysis while the National Renewable Energy Laboratory (NREL) performed techno-economic analysis on hydrogen blending scenarios the work on these subjects will be extended in Phase 2.

The project will develop an integrated hierarchical network modelling framework for simulating the operation of future GB energy system scenarios with highly interconnected gas and power networks. The realistic modelling of power-to-gas and storage operators’ behaviour will be emphasised. The integrated models will be demonstrated on a simulation platform as real-time digital twins for future system scenarios.

Considerable novelty will lie in the combination of modelling scale and granularity; representation of many autonomous decentralised agents making sub-optimal decisions; and the optimal resolution of dilemmas arising from the finite energy budgets constraining primarily weather-driven low to zero carbon scenarios.

As the UK attempts to decarbonise residential heat to meet net zero by 2050 electric heat pumps along with heat networks are expected to play a key role. However it is generally accepted that no one technology will be able to meet the needs of all households. If we are to deliver affordable low- carbon heating in the residential sector we shall need as wide a range of technology options as possible to overcome the economic and technical challenges facing every customer.

Project GaIN (Gathering Insights) will explore alternatives to heat pumps and heat networks which can utilise the robust gas network and benefit from its current upgrade programme supporting the aims of DESNZ’s decarbonisation of heat roadmap. The project will discover and assess additional technology options where alternative solutions might be more costly or difficult to deliver; this will include LAEP system benefits as well as localised CAPEX and OPEX costs.