Compared with the traditional solar on-grid system, there is one more battery system connected to a hybrid solar system. The system consists of PV panels, hybrid inverter, lithium batteries, and metering systems. The logic of the system is that when solar power starts to generate electricity in the morning, solar generation is given priority to the residential consumption load. When the solar-generated power is greater than the home consumption power, the hybrid inverter starts charging the battery until the battery is full. Meanwhile, when the solar-generated power is less than the residential load power, the battery starts to discharge and working with solar to fulfill the consumption load. When there is no solar in the evening, the battery discharges to follow home demand until the battery is fully discharged.
The advantage of the hybrid solar system is that the battery can store surplus solar generation for self-consumption. Moreover, we can achieve peak shifting through a hybrid solar system. For example, in the red zone when the electricity price is expensive from 6 PM to 8 PM, we can set the battery is charged to SOC 100% from solar or at the moment when the electricity price is cheap. And to discharge battery only in the red zone from 6 PM to 8 PM. This is how we save electricity bills from a hybrid solar system.
There is always one CT or meter is installed on-grid side and communicated with the hybrid inverter. This is how we measure the real-time load consumption. And by this method, we can set zero export to grid availability to achieve the maximization of self-consumption. Furthermore, we have generation, grid import and export, and battery information. And all this information can be sent to the cloud server by a 4G or WIFI dongle. So that we can display and analyze the daily, monthly, or yearly data from the web.
2. Hybrid Inverters Brands and Series Numbers
Fronius symo hybrid 3.0-3-S, 4.0-3-S, 5.0-3-S.
SolarEdge StorEdge series
Solax X1 Hybrid G4, X1 Hybrid HV
Q Cells Q.Home ESS HYB-G2
Goodwe ET series, BT series, EH series, BH series, ESA series, ES series
The safety design for large scale or containerized BESS
Under the global strategic policy of reduction of “carbon emission”, to solve the energy situation for the renewable power grid, with the increase of capacity of solar and wind generation, the requirements of grid frequency regulation, peak shifting, and the “power increase” driven by resource demand. Therefore, the lithium-ion BESS (battery energy storage system) is not only to improve the energy utilization rate of the power system, but also play an important role in the use of the power from grid. With the increasing install scale, the security of safety design of lithium-ion battery storage system also adds to the ongoing focus.
For large-scale on-grid, off-grid and micro-grid energy storage stations are often to use containerized battery storage system. Tens of thousands of cells are installed in containers through series/parallel connections. There is only a thin layer of diaphragm insulation inside of cells between the negative and anode electrodes. Electrical isolation mainly depends on insulating materials and electrical switches. The insulating materials may be carbonized at high temperatures and become conductive materials. The isolating switch may also break down under high voltage. Under the reverse high voltage and surge impact, the tube electronics may also conduct abnormally. In the long-term and thousands of charge-discharge cycles, especially in the state of overcharge, over-discharge and over-temperature, it may cause disastrous short-circuit failure in the cells, partial loss of control, and safety problems in any of the cells. If there is no strict safety protection measures in advance responding to it may cause a chain reaction of the battery storage system, resulting in an fire or explosion accident.
It is possible to solve the safety problem of the BESS (battery energy storage station) by increasing the insulating material and strength, however it will increase the cost of the full battery storage station and is not conducive to the large-scale promotion and application of energy storage. The safety of containerized energy storage system needs to be dealt with from the aspects of system plan, material selection, security design, etc., in order to comprehensively take into fiancé of the two important indicators of safety and cost. At present, the main safety technologies and measures adopted by battery energy storage systems are: new modular energy storage technology, aerogel thermal insulation materials, traditional electrical protection, thermal management and efficient fire safety systems.
1. Modular battery storage technology
The first-generation lithium battery simply connects the battery packs in series into clusters, and the second-generation lithium battery adds some intelligent battery management units on the basis of the first-generation lithium battery. However, a series of problems such as the high voltage of the DC bus in the lithium battery system and the risk of battery insulation, the uneven discharge between clusters, and the inability to mix the echelon batteries cannot be completely solved, which puts a question mark on the safe and stable application of the lithium battery. New modular energy storage, each battery module corresponds to a BMS battery management system, equipped with multiple functions such as electrical and physical double isolation, automatic exit of faulty modules, battery insulation failure warning, etc., to ensure the safety and reliability of lithium batteries.
Aerogel is a solid material with nano porous network structure and filled with gaseous dispersion medium in the pores, which is the lightest solid in the world. Aerogel is recognized as the lightest known solid material in the world, and it is a new generation of high-efficiency and energy-saving thermal insulation materials. Aerogel has the characteristics of high flame retardant performance, light volume and low consumption, and has become the best choice for power battery cell insulation materials. It has been adopted by battery companies and new energy vehicle manufacturers. Aerogel fire and heat insulation material is used between the cells and the upper cover of the module and PACK. The safety design at the module level is mainly about isolation, which is the heat insulation and fire insulation design of the module. The thermal runaway management of the module mainly relies on the aerogel between the single cells. The aerogel is encapsulated by PET, and the overall thermal conductivity is small, which can well delay the heat transfer between the cells level of security.
3. Electrical Protection of Battery Energy Storage System
Protections of Battery Energy Storage System: DC side is divided into DC energy storage unit protection zone, DC connection unit protection zone and confluence zone; AC side is divided into AC filter protection zone and transformer protection zone. There are overlapping parts between adjacent protection zones, ensuring that all electrical equipment is within the protection scope. The division of the protection zone is closely related to the configuration of the relay protection. On the one hand, the types of electrical equipment in the protection zone are different, and the characteristics of electrical and non-electrical quantities after a fault are different; on the other hand, the coordination of adjacent protection zones varies with protection. There are also huge differences in divisions. Therefore, the configuration and coordination of the protection of the BESS are based on the protection zone.
Protection configuration of DC energy storage unit: over-voltage protection, thermal protection and over-current protection, voltage and current change rate protection, charging protection; DC connection unit protection configuration: configuration of fuse, low-voltage DC circuit breaker, low-voltage DC isolation switch and mid-span Battery protection, for multiple battery energy storage units, the DC connection units should be connected as far as possible to avoid loss of more power supply capacity in the event of failure; bidirectional converter (PCS) protection configuration: input and output side overvoltage protection, over-frequency and under-voltage protection Frequency protection, phase sequence detection and protection, anti-islanding protection, overheat protection, overload and short circuit protection.
4. Lithium Battery Thermal Management
In order to fulfill the environmental conditions of the project site and the normal use of the battery pack and supporting equipment under the operating conditions of the system, the container conducts thermal management control through the following aspects, mainly including air conditioning (HVAC), thermal management design, thermal insulation layer, etc.. Thermal management system for the temperature in the container can ensure the proper operation of the battery pack and supporting electrical equipment.
The temperature control scheme in the container is as follows: the temperature of each set point in the container is monitored in real time through the temperature probe. When the temperature of the set point is higher than the set start temperature of the air conditioner, the air conditioner operates the refrigeration function, and the special air duct is used to control the temperature of each set point in the container. The interior of the container is cooled, and when the temperature reaches the lower limit of the set value, the air conditioner stops working. When the temperature of the set point is lower than the set start temperature of the air conditioner, the air conditioner operates the heating function, and heats the interior of the container through a special air duct. When the temperature reaches 15°C, the air conditioner stops working.
During the operation of the lithium battery, due to the existence of the internal electrochemical reaction and the influence of the increase of the ambient temperature, the temperature of the inner cavity of the battery will increase and the reaction will be intensified; while in the alpine area, due to the influence of the low temperature of the environment, the reaction speed in the battery will also be reduced. The former can lead to thermal runaway that can cause premature battery failure and safety issues, and the latter can also reduce the battery’s charge-discharge capacity and efficiency.
5. Container Fire Suppression
Compared with lead-acid batteries, lithium batteries of the same volume have higher density and more energy storage. After deflagration and fire, the flame will be jet-like, and the temperature of the fire source will be higher. At the same time, a large amount of toxic and harmful gases will be released, so there are more potential safety hazards. When fighting a lithium battery fire, firstly, put out the open flame in time to avoid the rapid spread of the fire; secondly, reduce the thermal runaway reaction rate, so that the heat generated by the internal thermal runaway reaction of the lithium battery is released in an orderly manner; The fire reignited and spread rapidly.
Fire suppression devices are integrated in the container, and most of them adopt a structure of no less than three levels, including early warning, alarm and action, and fire-fighting system devices, including detection controllers, fire control boxes, sound and light alarm bells/lights, temperature and salt fog sensors, SF6 gas fire extinguishing device. The installation principle of the detection controller should be close to the battery pack. Combined with the actual rack structure, the top space on the battery cabinet can be selected for installation the fire extinguisher device adopts cabinet type fire extinguisher and aerosol fire extinguishing device. Among them, the cabinet type gas is installed in the battery room, and the aerosol automatic fire extinguishing series devices are installed in the electrical room, modules and racks.
The container is equipped with gas fire-fighting device for lithium batteries. Once the smoke sensor and temperature sensor detect the high temperature fire fault signal, the container can notify the user through sound and light alarm and remote communication, and at the same time, cut off the running lithium battery storage system. After 30 seconds, the fire fighting device released gas to extinguish the fire. Significant instructions are required on the escape door in the container: Please leave the container within 30S after the fire alarm signal sounds.
Aerosol automatic fire extinguishing device is a new type of hot aerosol fire extinguishing device for lithium-iron battery energy storage systems, which is a breakthrough product in the field of fire protection with ultra-high fire extinguishing efficiency and reliability. When a fire occurs, the fire-extinguishing agent is activated by electric activation or temperature-sensing activation, and a large amount of sub-nano-scale solid-phase particles and inert gas mixtures are rapidly produced, which are completely submerged in the form of high-concentration smoke. It acts on every corner of the fire, and through the multiple functions of chemical inhibition, physical cooling and diluting oxygen, the fire is quickly and efficiently extinguished, and it is non-toxic to the environment and personnel.
Aerosols can also achieve three-level fire protection for large scale battery storage system, using single battery racks as protection units, using centralized gas detection and sampling analysis, and detecting changes in the chemical composition of lithium batteries in real time through the detectors preset in each battery PACK box. The chip analyzes and calculates the changes of various parameters, and conducts effective early fire suppression and prevention for the cells in the battery box to prevent the battery thermal runaway expansion of the lithium battery and the explosion of the energy storage cabinet. The first is battery module fire protection: according to the capacity size of the battery module and the capacity of the battery cell, installing aerosol on the battery module can effectively extinguish the first fire of the lithium battery cell (the first level of protection). Effective fire extinguishing method can minimize thermal runaway loss; second, lithium battery cabinet fire protection: install aerosol in the battery cabinet, with a protective space of 3m, which can effectively extinguish the second re-ignition or electrical fire in the battery cabinet (second level). The third is the fire protection of the storage container: the aerosol group can be installed in the container as the overall protection, as the fire suppression of the whole container (third pole protection). With the first and second level of protection, the third pole protection activation chance is greatly reduced, improving the overall fire safety.