GTX3000-H4~H10 sofarsolar alternative lithium ion amasstore HV energy storage battery system

Product outline

Coremax has introduced its newest GTX3000-H4~H10 sofarsolar alternative battery energy storage systems (BESSs), featuring for HV energy storage solution for residential BESS and utility-scale power plants, this alternative amasstore GTX3000-H4 for global commercial and industrial (C&I) applications.

The new systems offer minimised system cost, higher dischargeable energy capacity and greater flexibility.

About HV Battery storage system

High-voltage (HV) energy storage battery systems are designed to store large amounts of energy for use in grid-scale applications, such as energy storage for utility-scale renewable energy projects. These systems typically use lithium-ion battery technology and are capable of storing energy in the range of megawatt-hours (MWh).

The primary advantage of HV energy storage battery systems is their ability to provide reliable and stable power to the grid, which is critical for maintaining grid stability and supporting the integration of renewable energy sources. These systems can provide grid operators with the flexibility to adjust energy supply and demand in real-time, allowing for better management of grid fluctuations and the integration of intermittent renewable energy sources.

In addition to their grid-scale applications, HV energy storage battery systems are also being used in commercial and industrial (C&I) applications, such as data centers, hospitals, and manufacturing facilities. These systems can help businesses reduce their energy costs and improve energy efficiency by storing excess energy during off-peak hours and releasing it when needed, thereby reducing the demand for grid power during peak periods.

One of the key challenges in the development of HV energy storage battery systems is the cost of the technology. While the cost of battery storage has decreased significantly in recent years, HV energy storage battery systems remain expensive due to the high cost of the components and the complexity of the system. However, as the technology continues to improve and demand for renewable energy and energy storage increases, the cost of HV energy storage battery systems is expected to decrease, making them more accessible to a wider range of applications.

Overall, HV energy storage battery systems are an important component of the transition to a more sustainable and reliable energy system. As renewable energy sources continue to grow in importance, the need for reliable and flexible energy storage solutions will only become more critical, and HV energy storage battery systems will play a key role in meeting this need.

Problem

With industries around the world beginning to recover from the impact of COVID, the demand for energy has increased significantly, creating imbalance between supply and demand. Renewable energy is seen as a long-term solution, and in combination with energy storage can help resolve issues of volatility in supply.

However, while energy storage is a rapidly growing market in many parts of the world, large utility-scale battery storage plants face numerous challenges including high capital cost, low energy output, low flexibility and safety issues.

To date, the vast majority of battery storage systems have used HVAC for air cooling, and direct paralleling of multiple battery racks to increase energy density. This can lead to problems such as high auxiliary power consumption and low heat dissipation efficiency, having a negative effect on project income. This HV AC ESS offered by Coremax is the best solution as GTX3000-H4. The greatest alternative sofarsolar amasstore HV storage system.

Solution

Similar like GTX3000-H4~H10, Coremax HV energy storage battery system BESS solutions use advanced air cooling technology to dissipate heat more evenly from the battery, with the enhanced thermal conductivity of the coolant reducing the auxiliary power consumption required for system cooling.

The typical solution in kWh (kilowatt-hours) for energy storage systems varies depending on the application and the energy needs of the end-user. Residential energy storage systems typically range from 5 kWh to 20 kWh, while commercial and industrial energy storage systems can range from several hundred kWh to several MWh (megawatt-hours).

For example, a small residential energy storage system designed to complement a home solar PV system might have a capacity of 5-10 kWh, while a larger system designed to provide backup power during grid outages or to reduce reliance on the grid might have a capacity of 20 kWh or more.

On the other hand, a commercial or industrial energy storage system might have a capacity of several hundred kWh to several MWh, depending on the energy needs of the facility. For example, a data center with high energy demands might require an energy storage system with a capacity of several MWh to provide backup power in the event of a grid outage or to reduce energy costs during peak demand periods.

In summary, the typical solution in kWh for energy storage systems varies depending on the application and the energy needs of the end-user. Energy storage systems can range from small residential systems with capacities of 5-20 kWh to large commercial and industrial systems with capacities of several hundred kWh to several MWh.

Application

Coremax HV battery cabinet has a maximum capacity 20 kWh, with 4 BMU battery modular unit connected in series, 32S battery modules (32pcs in a modular) and HV combiner box, with additional Master BMS communication compatible capability. According to customer requirements, the total energy capacity of each battery cabinet can be tailored to achieve the best economics for a specific project.

The Amasstore gtx3000-h4 alternative solution has a maximum capacity of 100 kWh, including a battery managment unit, switchgear.

High-voltage (HV) battery systems are used in a variety of applications, ranging from grid-scale energy storage to commercial and industrial (C&I) applications. Here are some of the most common applications for HV battery systems:

1. Grid-scale energy storage: HV battery systems can be used to store excess energy generated by renewable energy sources, such as wind turbines and solar PV systems, and release it when needed. This helps to balance energy supply and demand on the grid, improving grid stability and reducing the need for fossil fuel-based peaker plants.
2. Microgrids: HV battery systems can be used in microgrid applications to provide backup power in the event of a grid outage, and to help balance energy supply and demand within the microgrid.
3. Commercial and industrial applications: HV battery systems can be used in a variety of C&I applications, such as data centers, hospitals, and manufacturing facilities, to reduce energy costs and improve energy efficiency. These systems can store excess energy during off-peak hours and release it when needed, reducing the facility’s reliance on grid power during peak demand periods.
4. Electric vehicle (EV) charging: HV battery systems can be used to store excess energy generated by renewable energy sources and use it to charge EVs, reducing the reliance on grid power for EV charging.
5. Renewable energy integration: HV battery systems can be used to integrate renewable energy sources into the grid, providing reliable and stable power to the grid and reducing the need for fossil fuel-based power plants.

In summary, HV battery systems have a wide range of applications, from grid-scale energy storage to C&I applications and EV charging. As renewable energy sources continue to grow in importance, the demand for HV battery systems is expected to increase, making them an important component of the transition to a more sustainable and reliable energy system.

Platform

Residential BESS and C&I applications.

Residential BESS (Battery Energy Storage System) refers to battery storage systems designed for residential use, typically in single-family homes or multi-unit dwellings. These systems allow homeowners to store excess energy generated by their solar PV systems during the day and use it when needed, such as during the evening or at times of peak demand. Residential BESS can provide greater energy independence, reduced energy bills, and improved energy efficiency for homeowners.

On the other hand, C&I (Commercial and Industrial) applications refer to battery storage systems designed for larger-scale energy storage needs, typically for commercial and industrial applications. These systems can be used to store excess energy generated by solar PV systems, wind turbines, or other renewable energy sources, and release it when needed. C&I applications can help businesses reduce their reliance on grid power, improve energy efficiency, and reduce their carbon footprint.

The main difference between residential BESS and C&I applications lies in the scale of the energy storage needs. Residential BESS are typically smaller in size and capacity, designed to meet the energy needs of a single home or small community, while C&I applications are larger and designed to meet the energy needs of larger commercial or industrial facilities.

In summary, understanding the differences between residential BESS and C&I applications is important when considering the energy storage needs of different applications. Whether it’s for residential or commercial use, battery storage systems can provide a range of benefits, including greater energy independence, reduced energy bills, and improved energy efficiency.

Availability

Already available in Europe. USA.