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Liquid Cooling of ESS Container
완벽한 온도 제어 솔루션을 위해 지금 바로 문의하세요.
Currently, temperature control technologies in the energy storage field mainly include air cooling and liquid cooling. Air cooling technology is extended from air conditioners, while liquid cooling technology is borrowed from electric vehicles. Air-cooling heat dissipation uses a fan to bring the heat generated by the battery core to the outside, and liquid cooling heat dissipation uses coolant convection heat transfer to accurately manage the temperature of each battery core. Air-cooling technology was first commonly used in energy storage systems because the technology has a simple structure, mature technology, and low cost, and can achieve rapid delivery and deployment. However, the air-cooling system is large in size and is greatly affected by the external environment. It has problems in terms of system safety, efficiency, and economy. There are many problems in terms of performance, and the emergence of liquid-cooled energy storage just solves the above problems.
1. Principle of energy storage system (ESS) container liquid cooling system
Liquid cooling systems are currently a popular research direction in power battery thermal management. They utilize the coolant’s large heat capacity and ability to take away excess heat from the battery system through circulation to achieve optimal operating temperature conditions for the battery pack. The basic components of the liquid cooling system include: liquid cooling plate, liquid cooling unit (heater optional), liquid cooling pipeline (including temperature sensor, valve), high and low voltage wiring harness; coolant (ethylene glycol aqueous solution), etc.
The cooling circuit of battery packs generally uses a parallel circuit to reduce the temperature difference between battery packs; battery packs generally use large battery boxes (30-50KWh/Pack) to improve system integration and reduce costs; the liquid cooling unit is arranged Both distributed and centralized. The distributed type uses one cluster or two clusters to configure one liquid cooling unit, which is generally used for a single outdoor cabinet; the centralized type uses a container system to configure one or two liquid cooling units.
2. Main advantages of energy storage liquid cooling system
(1) Safer. As the scale of energy storage project construction continues to increase, the battery cell capacity and system energy density are also increasing. Even if large-capacity batteries are used, it still takes more than a dozen to build a 100-megawatt energy storage project. Thousands or even hundreds of thousands of battery cells are combined together, which will generate greater heat and place higher requirements on the temperature control management of the energy storage system. Liquid-cooled energy storage has high technical content. It directly dissipates heat to the battery core through coolant convection. The method is controllable and is not affected by external conditions. It also has high heat dissipation efficiency and more precise temperature control. Due to factors such as small air specific heat capacity and convection heat transfer coefficient, battery air-cooling technology has low heat transfer efficiency, and the battery heat generation increases, which will cause the battery temperature to be too high, and there is a risk of thermal runaway; the liquid cooling solution can rely on a large flow of cooling medium To force the battery pack to dissipate heat and realize heat redistribution between battery modules, it can quickly inhibit the continued deterioration of thermal runaway and reduce the risk of runaway.
(2) More economical. In addition to safety, the integrated design of energy storage systems also takes into account the operation and maintenance of the entire life cycle. Liquid-cooled energy storage systems are more economical. The energy storage system generates a lot of heat during operation and dissipates heat unevenly, which not only endangers the safety of the battery energy storage system, but also affects the battery life. Through cluster-level controllers and intelligent temperature control and balancing control technology, the energy storage liquid cooling system can make the temperature of the battery core more uniform through the settings of pipelines and liquid flow. To achieve the same average battery temperature, air cooling requires 2-3 times higher energy consumption than liquid cooling. The maximum temperature of the battery pack under the same power consumption is 3-5°C higher with air cooling than with liquid cooling, and liquid cooling has lower power consumption.
(3) More suitable for long-term energy storage. From 2021 to now, various policies related to energy storage ratios have been introduced across the country, which involve two indicators, one is the power ratio, and the other is the energy storage duration. The power proportion ranges from 5% to 30%, and the energy storage time ranges from 1h to 4h. If the 4h battery energy storage system continues to use air-cooled heat dissipation technology, although its structure is simple and the cost is low, the heat generated by the battery core is directly brought to the outside through the fan, but it has low heat transfer coefficient, slow cooling speed, and requires a large area. The heat dissipation channel and other disadvantages, its area will be very huge. Liquid cooling technology has the advantages of high thermal conductivity, more uniform heat dissipation, lower energy consumption, and less floor space. The liquid-cooled energy storage system container solution has high heat dissipation efficiency. Compared with traditional air-cooled containers, the power density is increased by 100%. , saving more than 40% of the floor space, and is more suitable for large-scale and long-term energy storage scenario applications.
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정밀 냉각기 / 소형 냉각기
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이 냉각기는 다양한 산업 및 실험실에서 널리 사용될 수 있으며 맞춤형 설계를 지원합니다.
| 온도 범위 | -18°C ~ +30°C | +5°C ~ +35°C 시리즈 |
| 냉각 용량 | 0.35 ~ 0.9kW | 1.8 ~ 50kW |
재순환 냉각기
(맞춤형 디자인)
당사의 재순환 냉각기는 저온 냉동 기술을 채택하고 온도가 -120℃까지 낮으며 다양한 액세서리를 사용자 정의 할 수 있습니다.
| 온도 범위 | -25°C ~ +30°C 시리즈 | -45°C ~ +30°C 시리즈 | -60°C ~ -20°C 시리즈 | -80°C ~ -20°C 시리즈 | -120°C ~ -70°C 시리즈 |
| 냉각 용량 | 0.8 ~ 30kW | 0.75 ~ 12kW | 0.4 ~ 6kW | 0.2 ~ 6kW | 0.3 ~ 5kW |
저온 냉각기
(맞춤형 디자인)
당사는 -150°C의 낮은 온도 제어 범위를 갖춘 저온 냉각기 생산을 전문으로 하며, 다양한 산업의 냉장 요구 사항을 충족할 수 있습니다.
| 온도 범위 | -25°C ~ -5°C 시리즈 | -45°C ~ -10°C 시리즈 | -60°C ~ -10°C 시리즈 | -80°C ~ -30°C 시리즈 | -110°C ~ -50°C 시리즈 | -150°C ~ -110°C 시리즈 |
| 냉각 용량 | 12 ~ 360kW | 6 ~ 180kW | 6 ~ 180kW | 4 ~ 180kW | 2 ~ 120kW | 2.5 ~ 11kW |
(맞춤형 디자인)
차량 품질 테스트를 위한 온도 시뮬레이션: 배터리 수명 테스트, 연료 인젝터/모터 테스트 벤치, 에어백 테스트, 부품 테스트 벤치 등
(맞춤형 디자인)
전자 부품의 정밀한 온도 제어에 적합합니다. 열악한 환경을 위한 반도체 전자 부품 제조에서 IC 패키징 조립 및 엔지니어링 및 생산 테스트 단계에는 전자 열 테스트 및 기타 환경 테스트 시뮬레이션이 포함됩니다.
배터리 에너지 저장 시스템용 액체 냉각
(맞춤형 디자인)
| 유형 | 변환 스테이션의 경우 | 에너지 저장 배터리용 | 충전소용 |
| 냉각 용량 | 45kW | 5~8.5kW | 4kW |
ZLFQ 시리즈
(맞춤형 디자인)
냉각수 분배 장치
액체 냉각 장비는 반도체 테스트, 전자 장비 항온 테스트, 서버 지원 인프라 냉각 및 기타 유체 온도 제어 장소에 적합합니다.
| 온도 범위 | +5°C ~ +35°C | +5°C ~ +35°C |
| 냉각 용량 | 15 ~ 150kW | 200 ~ 500kW |
MD 써멀 척 시리즈
(맞춤형 디자인)
RF 디바이스 및 고밀도 전력 디바이스(IGBT 및 MOSFET) 테스트에 사용되며 실험실 평판(플라즈마, 생물학적 제품, 배터리) 등의 급속 냉각에도 사용할 수 있습니다.
| 온도 범위 | -75°C ~ +225°C |
| 온도 정확도 | ±0.1℃ |
스크류 칠러 (맞춤형 디자인)
저온 스크류 냉각기 및 실온 스크류 냉각기
| 온도 범위 | +5°C ~ +30°C | +5°C ~ +30°C | +5°C ~ +30°C | +5°C ~ +30°C | -25°C ~ +5°C | -25°C ~ +5°C |
| 냉각 용량 | 107 ~ 1027kW(단일 컴프레서) | 299 ~ 2134kW(듀얼 컴프레서) | 98~934kW(단일 컴프레서) | 272 ~ 1940kW(듀얼 컴프레서) | 48 ~ 467kW(단일 컴프레서) | 51 ~ 497kW(단일 컴프레서) |
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