Jul 29, 2024

Solution for integrated heat utilization exploring new possibilities for using heat to achieve a carbon-free society

Panasonic Begins Demonstration Using Heat from Pure Hydrogen Fuel Cell Generators as a Heat Source for an Absorption Chiller (Air Conditioning Equipment)

Resolving the challenge of the temperature gap between the maximum hot water output by fuel cell generators and the minimum temperature of heat sources required to operate absorption chillers

Osaka, Japan – Panasonic Corporation (https://www.panasonic.com/global/home.html) (hereinafter referred to as Panasonic) today announced that it has started a demonstration experiment to utilize heat produced during power generation using pure hydrogen fuel cell generators as a heat source for an absorption chiller (air conditioning equipment). The experiment will be performed in the H2 KIBOU FIELD facility (Kusatsu City, Shiga Prefecture), which uses renewable energy to supply the electric power required for production in the fuel cell factory.

Up to this point, there has been a gap of 20°C between the heat that can be recovered from pure hydrogen fuel cell generators (maximum of 60°C) and the heat source temperature required for the operation of absorption chillers (minimum of 80°C). This made it difficult to utilize heat produced by pure hydrogen fuel cell generators during power generation as a heat source for absorption chillers. This time, improvements have been made to both of the previous pure hydrogen fuel cell generator and absorption chiller. The new fuel cell generator produces heat at a temperature of 70°C, which can be used as a heat source for the new absorption chiller for operation, improving the temperature gap by 10°C each. This has enabled a new solution for the linked use of heat at 70°C by connecting the new fuel cell generator and air conditioning equipment. In the H2 KIBOU FIELD facility, ten pure hydrogen fuel cell generators with improved hot water output temperature will be installed, along with one newly developed absorption chiller that can utilize low-temperature waste heat. Such equipment will be used for cooling and heating the facility's administration building as the demonstration experiment of a new scheme to utilize heat. Throughout the demonstration experiment, Panasonic aims to improve energy efficiency through fuel cell cogeneration (combined heat and electric power supply) and reduce power consumption in cooling and heating equipment, thereby verifying the marketability and effectiveness of this integrated heat utilization solution.

The H2 KIBOU FIELD facility at Panasonic's Kusatsu Site uses 99 units of 5 kW-type pure hydrogen fuel cell generators, photovoltaic generators with an output of approximately 570 kW, and storage batteries with a storage capacity of approximately 1.1 MWh. These three types of systems are highly integrated and controlled to generate electric power for the fuel cell factory through in-house power generation using renewable energy. Since the Fiscal Year ending in March 2023, the Company has been conducting another type of demonstration experiment to efficiently and stably supply renewable energy to the factory by reducing surplus power generation and wasteful power use, through energy management that tracks and addresses demand changes in the fuel cell production process and sudden fluctuations in photovoltaic generator output due to weather. In this new demonstration experiment for verifying heat utilization, a new catalyst currently under development has been incorporated into the power generation section of the new pure hydrogen fuel cell generator. Further, improvements have been made to increase the durability of the main body, thereby raising the temperature of the recoverable heat by 10°C, from 60°C to 70°C. Through this demonstration experiment, Panasonic will achieve an energy efficiency of 95% by simultaneously utilizing heat in addition to electric power. In addition, while heat utilization has previously focused on hot water supply and heating, it will now be possible to use heat for air cooling through absorption chillers. This will enhance the practicality of cogeneration systems in industrial applications and explore new possibilities for heat utilization.

Meanwhile, Panasonic's absorption chillers, which boast a top market share*¹ in Japan, are highly efficient air conditioning systems. By using water, a natural refrigerant, the chillers do not use any specified CFCs or alternative CFCs, making them environmentally friendly systems that reduce the impact on the depletion of the ozone layer and global warming. Their lineup also includes a waste heat recovery type that utilizes heat emitted from factories and other facilities to operate equipment. This experiment is equipped with a new absorption chiller in which the process of absorbing water vapor and concentrating the absorbing solution has been improved. While the chiller is the same size as existing products, it has lowered the minimum heat source temperature requirement by 10°C, from 80°C to 70°C, making it possible to utilize the heat produced by pure hydrogen fuel cell generators during power generation. Further, chilled water generated by the absorption chiller will be used for the commercial air conditioners that cool and heat the administration building in the demonstration facility. This experiment is the industry's first*² attempt to use chilled water from the absorption chiller to achieve the energy saving of commercial air conditioners, aiming to reduce the air conditioning power consumption by 50%. In addition, lowering the minimum heat source temperature required by absorption chillers has the potential to address the current issue where heat below 80°C, which accounts for approximately 70% of all industrial waste heat emitted from factories and other facilities, cannot be effectively utilized*³.

In this demonstration experiment, by combining the advantages of Panasonic's industry-leading products across business and organizational boundaries, Panasonic aims to create unique customer value that cannot be achieved by a single business or product. Panasonic will contribute to the realization of a carbon-free society through the development of optimal solutions that leverage its strengths in the future.

Notes:

*1: Panasonic's estimate based on the Japan Refrigeration and Air Conditioning Industry Association's Fiscal Year ending in March 2023, domestic shipments of absorption chillers (refrigeration tons)

*2: This is the first system demonstration in the industry to achieve energy saving by using chilled water generated by the absorption chiller to dissipate all heat dissipated from the condenser of a water-cooled commercial air conditioner (as of July 2024, according to Panasonic).

*3: Source: Panasonic's estimate based on the Survey Report on the Actual Situation of Waste Heat in the Industrial Sector (Thermal Management Materials and Technology Research Association, March 2019)

[Outline of the demonstration experiment]

General overview	Chilled water is produced by the absorption chiller using heat at 70°C output during power generation by the pure hydrogen fuel cell generators. The demonstration experiment aims to reduce the power consumption of single-room air conditioning equipment by using chilled water to assist with the heat dissipation of the condensers in the commercial air conditioner's outdoor unit, thereby lowering the condensation temperature.
Equipment used	Pure hydrogen fuel cell generator (5 kW type, hot water output temperature at 70°C): 10 units Absorption chiller that can utilize low-temperature waste heat (8 refrigeration tons): 1 unit Commercial air conditioner (Assisted by chilled water) (6 HP): 1 outdoor unit and 2 indoor units
Start date	July 2024

[Features]

1. Lowered the minimum heat source temperature required by previous absorption chillers by 10°C

Absorption chillers are air conditioning units that use water, a natural refrigerant, to generate chilled water by utilizing the heat of vaporization as water evaporates. The absorbing solution captures the water vapor generated during the evaporation of water. The diluted absorbing solution is then concentrated by heating with waste heat to regenerate the solution, and the water vapor generated during regeneration is condensed and recovered as water. This refrigeration cycle utilizes the properties of water, repeating the four stages of evaporation, absorption, regeneration, and condensation. Until now, with waste heat below 80C, it was difficult to concentrate and regenerate the absorbing solution to a high concentration, leading to reduced water vapor absorption and lower refrigeration capacity. This time, Panasonic has developed technology that enables the high concentration of the absorbing solution even with waste heat as low as 70°C by incorporating a drip-type regenerator that gradually concentrates the solution. Furthermore, to address the decrease in the amount of water vapor absorbed by the absorbing solution, the Company has now adopted new two-stage evaporation/absorption technology with enhanced pressurizing capability, allowing for increased water vapor absorption.

2. A 10°C increase in the temperature of hot water output by the pure hydrogen fuel cell generators can be used by the absorption chiller, achieving an energy efficiency of 95%

Pure hydrogen fuel cell generators induce chemical reactions between high-purity hydrogen and oxygen in the air to generate electrical energy. Multiple equipment units with 5 kW output can be connected, enabling support tailored to customers' power needs and installation location requirements. Cogeneration (combined heat and electric power supply) is also supported, which converts heat generated during power generation into hot water. The temperature of hot water output by the 10 demonstration generators for this experiment has been increased by 10°C to 70°C. To address the deterioration of catalyst materials due to high temperatures, the generators are equipped with a new mesoporous carbon (MPC) catalyst, which is under development and twice as active as conventional catalysts, to enhance the power generation performance. In addition, the performance of the humidifier has been improved to prevent deterioration due to dryness, and the high-temperature performance of the fuel cell stacks has been enhanced. Moreover, a heat exchanger has been added to increase heat recovery efficiency, achieving an output hot water temperature as high as 70°C. This achieves an energy efficiency of 95% by utilizing the electric power and heat generated by the fuel cell generator. In addition, when 10 generator units are connected together, each pure hydrogen fuel cell generator sends a signal indicating whether it is generating electric power or stopped, allowing for control in conjunction with external solenoid valves. This prevents the inflow of low-temperature water from pure hydrogen fuel cell generators when they are stopped, making it possible to consistently supply hot water at 70°C to the absorption chiller.

3. Industry's first*² demonstration aimed at utilizing chilled water from the absorption chiller to operate single-room air conditioning equipment and reduce power consumption by 50%

In this demonstration experiment, chilled water from the absorption chiller is not used directly for air cooling but is employed to assist in reducing the power consumption of existing single-room air conditioning equipment (commercial air conditioner). The chilled water generated by the absorption chiller cannot be transported to the refrigerant piping of single-room air conditioning equipment. Therefore, the previous air-cooled condenser, which uses outside air in the outdoor unit as a cooling medium to remove heat, has been replaced with a water-cooled condenser, enabling the use of chilled water to cool the refrigerant of the existing single-room air conditioning equipment. This outdoor unit assisted by chilled water is used for the demonstration to utilize the chilled water generated by the absorption chiller, thereby achieving a refrigeration cycle of air conditioning that significantly lowers the condensation temperature of the refrigerant. Based on this achievement, Panasonic aims to reduce the power consumption of the entire single-room air conditioning equipment, including the commercial air conditioner indoor and outdoor units, by 50% through the reduction of the input electricity required for the compressor of the outdoor unit.

＜Panasonic Group's Environmental Initiatives＞

The Panasonic Group has established a long-term environmental vision, Panasonic GREEN IMPACT, to achieve both a better life and a sustainable global environment. The Group is working on business activities with the aim of achieving net-zero CO₂ emissions from all its operating companies by 2030, creating a CONTRIBUTION IMPACT to reduce more than 300 million tons*⁴ of CO₂ emissions, equivalent to approximately 1% of the current global total of approximately 31.7 billion tons*⁵, by 2050, and realizing a circular economy.

*4: CO₂ emission factor is based on the year 2020

*5: 2020 energy-derived CO₂ emissions: 31.7 billion tons (Source: IEA)
https://holdings.panasonic/global/corporate/panasonic-green-impact.html

About Panasonic Corporation

Panasonic Corporation offers products and services for a variety of living environments, ranging from homes to stores to offices and cities. There are five businesses at the core of Panasonic Corporation: Living Appliances and Solutions Company, Heating & Ventilation A/C Company, Cold Chain Solutions Company, Electric Works Company and China and Northeast Asia Company. The operating company reported consolidated net sales of 3,494.4 billion yen for the year ended March 31, 2024. Panasonic Corporation is committed to fulfilling the mission of Life Tech & Ideas: For the wellbeing of people, society and the planet, and embraces the vision of becoming the best partner of your life with human-centric technology and innovation. Learn more about Panasonic: https://www.panasonic.com/global/about/

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