GCL's lithium iron phosphate energy storage materials rely on an innovative process with independent intellectual property rights - the iterative effect of PHY physical dry technology, which reduces production costs, investment costs and energy consumption indicators by about 50%, and has the advantages of no wastewater, waste gas, waste residue, etc. throughout the process. Various indicators such as compaction degree, energy density and number of cycles all surpass traditional processes.

The silicon-carbon anode material developed by GCL can replace graphite and exhibits high energy density, significantly enhancing the capacity and electrochemical performance of battery anode materials. As an extension project of GCL's silicon industry chain, the raw materials for silicon-carbon anode (silicon powder, silane) are sourced from the FBR granular silicon unit.The silicon-carbon anode material produced through GCL's nanoscale silicon technology exhibits a single-cell specific capacity exceeding 1500, with a first charge-discharge efficiency reaching 91%.

Supramolecular technology enables the reengineering of materials, effectively addressing safety concerns such as thermal runaway and flammability associated with conventional electrolyte materials.

The GCL cell products possess elevated levels of safety and exceptional cycle reliability, making them suitable for applications in power storage, communication storage, new energy vehicles, and engineering machinery, among other scenarios.
GCL Energy Storage specializes in long-lasting lithium iron phosphate batteries for energy storage, offering a remarkable combination of high energy density, efficiency, rate capability, and thermal stability. With an impressive lifespan of 12,000 cycles, these batteries achieve a harmonious balance between light storage and durability.

GCL's energy storage packs are characterized by their high energy density, excellent cycling performance, and exceptional safety features. These packs find wide applications in areas such as commercial and industrial energy storage, power auxiliary services, and integrated energy systems.
The energy storage system incorporates high-efficiency liquid cooling technology, advanced thermal isolation techniques, and safeguards against thermal propagation and thermal runaway incidents. With these features, the system ensures optimal energy efficiency and utilizes CTS (Cell Temperature Stabilization) technology to effectively manage cell temperatures.

The intelligent string-type energy storage system integrates grid monitoring, smart distribution, energy storage, and inverter equipment into a standard-sized container, enhancing the system's available capacity. It features advanced battery unit expansion and bidirectional inverter units, as well as a fault-level pre-processing mechanism. Furthermore, the system enables human-machine interaction by collecting various signals from the DC and AC sides of the energy storage system for monitoring and control purposes.
GCL intelligent string-type energy storage system adheres to a design philosophy that emphasizes modularity and integration. It effectively integrates grid monitoring, smart distribution, energy storage, and inverter equipment into a standard-sized container.