Patent Application
20250071957
This application claims priority to Chinese Patent Application No. 202311095400.0, filed on Aug. 25, 2023, which is hereby incorporated by reference in its entirety.
The embodiments relate to the energy field and to an energy storage apparatus and a photovoltaic energy storage system.
With continuous development and wide application of clean energy, energy storage devices that can store electric energy start to be widely used in a plurality of fields. Currently, there are more cabinet-level or container-level energy storage devices, to accommodate more batteries, thereby increasing power density of the energy storage devices and improving electric energy storage capabilities of the energy storage devices.
In the energy storage device, a plurality of batteries of the energy storage device are connected in series and in parallel, and are disposed in a box of the energy storage device, so that the box effectively protects the batteries. During actual use, the batteries generate heat during charging and discharging. Therefore, it needs to be ensured that the batteries are in a normal temperature range, so as to ensure charging and discharging performance and use safety of the batteries. Based on this, a heat dissipation system is usually disposed for the batteries in the energy storage device, to regulate temperatures of the batteries. However, for a heat dissipation system in which a conventional air cooling manner is used, cooling density of the heat dissipation system is limited by the cooling manner, and temperature regulation efficiency is low, which cannot meet a temperature regulation efficiency requirement of the current energy storage device.
The embodiments provide an energy storage apparatus and a photovoltaic energy storage system, to improve temperature regulation efficiency of an energy storage device.
According to a first aspect, the embodiments provide an energy storage apparatus. The energy storage apparatus may include a heat exchange module, a liquid cooling module, a first heat dissipation module, a second heat dissipation module, and a load. The liquid cooling module is configured to perform heat exchange with the load. A housing of the heat exchange module has two cooling interfaces, two first liquid cooling interfaces, and two second liquid cooling interfaces; a heat exchanger and a multi-port valve are disposed inside the heat exchange module; the heat exchanger is connected to the two first liquid cooling interfaces and the two cooling interfaces, and the heat exchanger may implement heat exchange between the first heat dissipation module and the liquid cooling module; and the multi-port valve is connected between the heat exchanger and one first liquid cooling interface, the multi-port valve is connected to one second liquid cooling interface, the multi-port valve may connect or disconnect the first heat dissipation module to or from the liquid cooling module, the multi-port valve may further connect or disconnect the second heat dissipation module to or from the liquid cooling module, and the other second liquid cooling interface is connected to the other first liquid cooling interface. The liquid cooling module may be connected between the two first liquid cooling interfaces, the first heat dissipation module may be connected between the two cooling interfaces, and the second heat dissipation module may be connected between the two second liquid cooling interfaces.
In the solution provided in the embodiments, temperature regulation is performed on the load in a liquid cooling manner. For example, the first heat dissipation module may perform heat exchange with the liquid cooling module by using the heat exchange module, to implement temperature regulation on the load. The second heat dissipation module may directly perform heat exchange with the liquid cooling module, to implement temperature regulation on the load. Compared with an air cooling manner, the liquid cooling manner has higher heat exchange density, higher temperature regulation efficiency for the load, and lower energy consumption. In addition, in the energy storage apparatus provided in the embodiments, components of functions such as heat dissipation, heat exchange, and liquid cooling are modularized, an overall quantity of interfaces is small, a leakage failure rate is low, and space utilization is high. In addition, the energy storage apparatus provided in the embodiments controls the multi-port valve, so that temperature regulation can be performed on the load by using only the first heat dissipation module, or temperature regulation can be performed on the load by using only the second heat dissipation module, or temperature regulation can be performed on the load by using both the first heat dissipation module and the second heat dissipation module. Temperature regulation is flexible, regulation effect is ideal, and energy consumption can be effectively reduced.
In a solution, a housing of the first heat dissipation module has two first heat dissipation interfaces, and the two first heat dissipation interfaces are respectively connected to the two cooling interfaces. A cooler is disposed inside the first heat dissipation module, and the cooler is separately connected to the two first heat dissipation interfaces, so that the cooler is connected to the cooling interface of the heat exchange module.
In a solution, a housing of the second heat dissipation module has two second heat dissipation interfaces, and the two second heat dissipation interfaces are respectively connected to the two second liquid cooling interfaces. A first heat sink is disposed inside the second heat dissipation module, and the first heat sink is separately connected to the two second heat dissipation interfaces, so that the first heat sink is connected to the second liquid cooling interface of the heat exchange module.
In a solution, the first heat dissipation module and the second heat dissipation module may be integrated, so that system integration can be further improved, and space utilization can be improved.
In a solution, a first fan configured to dissipate heat may be disposed inside the first heat dissipation module, and the second heat dissipation module and the first heat dissipation module may share the first fan, so that a structure can be simplified, and costs can be reduced.
In a solution, the energy storage apparatus may further include a heat-generating module. The housing of the heat exchange module may have two heat-generating interfaces, the heat exchanger may be connected to the two first liquid cooling interfaces, the two cooling interfaces, and the two heat-generating interfaces, and the heat exchanger is configured to perform heat exchange between the heat-generating module and the liquid cooling module. The heat-generating module is connected between the two heat-generating interfaces, so that the load is heated.
In a solution, a housing of the heat-generating module has two heating interfaces, and the two heating interfaces are respectively connected to the two heat-generating interfaces. A second heat sink is disposed inside the heat-generating module, and the second heat sink is separately connected to the two heating interfaces, so that the second heat sink is connected to the heat-generating interface of the heat exchange module.
According to a second aspect, the embodiments provide an energy storage apparatus. The energy storage apparatus may include a heat exchange module, a liquid cooling module, a first heat dissipation module, a second heat dissipation module, and a load. The liquid cooling module is configured to perform heat exchange with the load. A housing of the heat exchange module may have two cooling interfaces and two first liquid cooling interfaces; and a heat exchanger may be disposed inside the heat exchange module, the heat exchanger is connected to the two first liquid cooling interfaces and the two cooling interfaces, and the heat exchanger may implement heat exchange between the first heat dissipation module and the liquid cooling module. The liquid cooling module may be connected between the two first liquid cooling interfaces, the first heat dissipation module may be connected between the two cooling interfaces, and the second heat dissipation module may be connected between the liquid cooling module and one first liquid cooling interface.
In the solution provided in the embodiments, temperature regulation is performed on the load in a liquid cooling manner. For example, the first heat dissipation module may perform heat exchange with the liquid cooling module by using the heat exchange module, to implement temperature regulation on the load. The second heat dissipation module may directly perform heat exchange with the liquid cooling module, to implement temperature regulation on the load. Therefore, a system has higher heat exchange density, higher temperature regulation efficiency for the load, and lower energy consumption. In addition, components are modularized, an overall quantity of interfaces in the system is small, a leakage failure rate is low, and space utilization is high. In addition, temperature regulation can be performed on the load by using only the second heat dissipation module alone, or temperature regulation may be performed on the load by using both the first heat dissipation module and the second heat dissipation module. Temperature regulation is flexible, regulation effect is ideal, and energy consumption can be effectively reduced.
In a solution, a housing of the first heat dissipation module has two first heat dissipation interfaces, and the two first heat dissipation interfaces are respectively connected to the two cooling interfaces. A cooler is disposed inside the first heat dissipation module, and the cooler is separately connected to the two first heat dissipation interfaces, so that the cooler is connected to the cooling interface of the heat exchange module.
In a solution, a housing of the second heat dissipation module has two second heat dissipation interfaces, and the two second heat dissipation interfaces are respectively connected to the liquid cooling module and one first liquid cooling interface. A first heat sink is disposed inside the second heat dissipation module, and the first heat sink is separately connected to the two second heat dissipation interfaces, so that the first heat sink is connected between the liquid cooling module and the heat exchange module.
In a solution, a first fan configured to dissipate heat may be disposed inside the first heat dissipation module, and a second fan configured to dissipate heat may be disposed inside the second heat dissipation module. The first heat dissipation module and the second heat dissipation module each use one fan. Air resistance of each fan is small, and power consumption of the first heat dissipation module and the second heat dissipation module is small.
In a solution, the energy storage apparatus may further include a compressor module, and the compressor module is connected between one first heat dissipation interface and one cooling interface. A compressor and a gas-liquid separator that are separately connected to the first heat dissipation module and the heat exchange module in sequence may be disposed inside the compressor module. The compressor may increase a refrigerant from a low pressure to a high pressure, and enable the refrigerant to continuously flow in circulation, thereby discharging heat of the heat exchange module to an external environment. The gas-liquid separator may filter and remove some moisture from the refrigerant, to reduce a workload of the compressor.
In a solution, a heater may be disposed inside the heat exchange module, and the heater is connected between the heat exchanger and one first liquid cooling interface, so that the load is heated.
In a solution, a housing of the liquid cooling module has two heat exchange interfaces, and the two heat exchange interfaces are respectively connected to the two first liquid cooling interfaces. A cold plate is disposed inside the liquid cooling module, the cold plate is configured to perform heat exchange with the load, and the cold plate is separately connected to the two heat exchange interfaces, so that the liquid cooling module performs heat exchange with the load.
According to a third aspect, the embodiments further provide a photovoltaic energy storage system. The photovoltaic energy storage system may include a power generation device, a power conversion device, and the energy storage apparatus in any one of the solutions of the first aspect or the second aspect. The power conversion device is connected between the power generation device and the energy storage apparatus, and the power generation device is configured to store generated electric energy into the load of the energy storage apparatus by using the power conversion device. The photovoltaic energy storage system has high power density, high working stability, and high use safety.
To make the objectives, solutions, and advantages clearer, the following further describes embodiments in detail with reference to the accompanying drawings. However, example implementations can be implemented in a plurality of forms, and should not be construed as being limited to the implementations described herein. Same reference numerals in the accompanying drawings represent same or similar structures, and repeated descriptions thereof are omitted. Words for expressing positions and directions in embodiments are described by using the accompanying drawings as examples. However, changes may be made as required, and all changes shall fall within the scope of the embodiments. The accompanying drawings in embodiments are merely used to show a relative position relationship, and do not represent an actual scale.
Specific details are described in the following description to facilitate understanding of the embodiments. However, embodiments may be implemented in a plurality of other manners different from those described herein, and a person skilled in the art may make similar promotion without departing from the connotation of embodiments. Therefore, the embodiments are not limited to the following implementations.
For ease of understanding, an application scenario of an energy storage apparatus in the embodiments is first described. The energy storage apparatus provided in embodiments may be, but is not limited to, an industrial and commercial energy storage scenario such as a small industrial and commercial industry (for example, a small factory), a medium industrial and commercial industry, a large industrial and commercial industry, a photovoltaic energy storage charging station, and a small and medium-sized microgrid (for example, an island), and a power station scenario such as a photovoltaic-wind energy storage station, a power grid energy storage station, and a large microgrid, to store and release electric energy. During actual application, the energy storage apparatus may be embodied in a form of an energy storage cabinet, an energy storage container, or the like. In a related technology, the energy storage device uses a conventional air cooling heat dissipation system, and temperature regulation efficiency of the conventional air cooling heat dissipation system is low, which cannot meet a temperature regulation efficiency requirement of the energy storage device with high power density. Based on this, embodiments provide an energy storage apparatus, to improve temperature regulation efficiency of an energy storage device.
Refer to
In a possible implementation, a housing of the heat exchange module 100 may have two cooling interfaces 101, two first liquid cooling interfaces 102, and two second liquid cooling interfaces 103, and a heat exchanger 104 and a multi-port valve 105 may be disposed inside the heat exchange module 100. The heat exchanger 104 is connected to the two first liquid cooling interfaces 102 and the two cooling interfaces 101, and the heat exchanger 104 may implement heat exchange between the first heat dissipation module 300 and the liquid cooling module 200. The multi-port valve 105 is connected between the heat exchanger 104 and one first liquid cooling interface 102, and the multi-port valve 105 is connected to one second liquid cooling interface 103. The multi-port valve 105 may connect or disconnect the first heat dissipation module 300 to or from the liquid cooling module 200, and the multi-port valve 105 may further connect or disconnect the second heat dissipation module 400 to or from the liquid cooling module 200. For example, the multi-port valve 105 may connect or disconnect the heat exchanger 104 to or from one first liquid cooling interface 102, to connect or disconnect the first heat dissipation module 300 to or from the liquid cooling module 200. The multi-port valve 105 may connect or disconnect one second liquid cooling interface 103 to or from one first liquid cooling interface 102, to connect or disconnect the second heat dissipation module 400 to or from the liquid cooling module 200. The other second liquid cooling interface 103 is connected to the other first liquid cooling interface 102.
For example, a refrigerant pipeline 106, a first coolant pipeline 107, and a second coolant pipeline 108 may be further disposed inside the heat exchange module 100. During actual application, a refrigerant such as freon or ammonia may flow in the refrigerant pipeline 106, and a coolant such as glycol, glycol solution, or water may flow in the first coolant pipeline 107 and the second coolant pipeline 108. The following first describes specific connection relationships between the interfaces of the housing and various components and pipelines inside the heat exchange module 100.
Two ends of the refrigerant pipeline 106 are respectively connected to the two cooling interfaces 101. Two ends of the first coolant pipeline 107 are respectively connected to the two first liquid cooling interfaces 102. Two ends of the second coolant pipeline 108 are respectively connected to the two second liquid cooling interfaces 103, and a part of the first coolant pipeline 107 is connected in the second coolant pipeline 108, which may be understood as that the first coolant pipeline 107 and the second coolant pipeline 108 have a shared pipeline.
The heat exchanger 104 is connected in the refrigerant pipeline 106 and the first coolant pipeline 107. The heat exchanger 104 may implement heat exchange between a refrigerant in the refrigerant pipeline 106 and a coolant in the first coolant pipeline 107. From a perspective of a module, the heat exchanger 104 may implement heat exchange between the first heat dissipation module 300 and the liquid cooling module 200.
The multi-port valve 105 is connected in the first coolant pipeline 107, and the multi-port valve 105 is connected to a joint between the first coolant pipeline 107 and the second coolant pipeline 108. The multi-port valve 105 is controlled, so that the first coolant pipeline 107 may be connected or disconnected, and the second coolant pipeline 108 may be connected to or disconnected from the first coolant pipeline 107.
In a possible implementation, the liquid cooling module 200 is connected between the two first liquid cooling interfaces 102, and the load 203 (for example, the battery) may be integrated into the liquid cooling module 200. The first heat dissipation module 300 is connected between the two cooling interfaces 101, to implement compression cooling. The second heat dissipation module 400 is connected between the two second liquid cooling interfaces 103 to implement natural cooling.
In the energy storage apparatus provided in embodiments, temperature regulation is performed on the load 203 in a liquid cooling manner. For example, the first heat dissipation module 300 may perform heat exchange with the liquid cooling module 200 by using the heat exchange module 100, to implement temperature regulation on the load 203. The second heat dissipation module 400 may directly perform heat exchange with the liquid cooling module 200, to implement temperature regulation on the load 203. Compared with an air cooling manner, the liquid cooling manner has higher heat exchange density, higher temperature regulation efficiency for the load 203, and lower energy consumption. In addition, in the energy storage apparatus provided in embodiments, components of functions such as heat dissipation, heat exchange, and liquid cooling are modularized, an overall quantity of interfaces is small, a leakage failure rate is low, and space utilization is high. In addition, the energy storage apparatus provided in embodiments controls the multi-port valve 105, so that temperature regulation can be performed on the load 203 by using only the first heat dissipation module 300, or temperature regulation can be performed on the load 203 by using only the second heat dissipation module 400, or temperature regulation can be performed on the load 203 by using both the first heat dissipation module 300 and the second heat dissipation module 400. Temperature regulation is flexible, regulation effect is ideal, and energy consumption can be effectively reduced. For example, when an ambient temperature is high (for example, when the ambient temperature>10° C.), temperature regulation may be performed on the load 203 by using only the first heat dissipation module 300; and when the ambient temperature is low (for example, when the ambient temperature≤10° C.), temperature regulation may be performed on the load 203 by using only the second heat dissipation module 400, so that energy efficiency is high and more energy can be saved. In addition, when the ambient temperature is high (for example, when 10° C.<the ambient temperature<25° C.), temperature regulation may be performed on the load 203 by using both the first heat dissipation module 300 and the second heat dissipation module 400, to reduce energy consumption of the first heat dissipation module 300.
In a possible implementation, a first pump body 109 may be further disposed inside the heat exchange module 100. The first pump body 109 is connected in the first coolant pipeline 107. The first pump body 109 is configured to increase a coolant flow rate in the first coolant pipeline 107, so as to improve heat exchange efficiency of the liquid cooling module 200 for the load 203. For example, heat dissipation efficiency for the load 203 may be improved. An electronic expansion valve 110 may be further disposed inside the heat exchange module 100. The electronic expansion valve 110 is connected to the refrigerant pipeline 106. The electronic expansion valve 110 may adjust a liquid supply amount. For example, the electronic expansion valve 110 may adjust a flow volume of a refrigerant provided by the first heat dissipation module 300 to the heat exchange module 100.
In a possible implementation, a housing of the first heat dissipation module 300 may have two first heat dissipation interfaces 301. During connection, the two first heat dissipation interfaces 301 are respectively connected to the two cooling interfaces 101, to implement connection between the first heat dissipation module 300 and the heat exchange module 100. A cooler 302 may be disposed inside the first heat dissipation module 300. The cooler 302 is separately connected to the two first heat dissipation interfaces 301, to implement connection between the cooler 302 and the heat exchange module 100, and further implement connection between the cooler 302 and the refrigerant pipeline 106. The cooler 302 may cool the refrigerant, so as to implement heat exchange between the refrigerant in the refrigerant pipeline 106 and the coolant in the first coolant pipeline 107 by using the heat exchanger 104. For example, the cooler 302 may be a refrigerant condenser.
In a possible implementation, the energy storage apparatus provided in embodiments n may further include a compressor module 500. The compressor module 500 is connected between one first heat dissipation interface 301 and one cooling interface 101, so that the compressor module 500 is connected between the first heat dissipation module 300 and the heat exchange module 100. A compressor 502 and a gas-liquid separator 503 that are separately connected to the first heat dissipation module 300 and the heat exchange module 100 in sequence may be disposed inside the compressor module 500. The compressor 502 may increase the refrigerant from a low pressure to a high pressure, and enable the refrigerant to continuously flow in circulation, thereby discharging heat of the heat exchange module 100 to an external environment. The gas-liquid separator 503 may filter and remove some moisture from the refrigerant, to reduce a workload of the compressor 502.
A housing of the compressor module 500 may have two compression interfaces 501. During connection, the two compression interfaces 501 are respectively connected to one first heat dissipation interface 301 and one cooling interface 101. Inside the compressor module 500, the compressor 502 and the gas-liquid separator 503 are separately connected to one compression interface 501. In a possible implementation, the compressor module 500 and the first heat dissipation module 300 may be integrated.
In a possible implementation, a housing of the second heat dissipation module 400 may have two second heat dissipation interfaces 401, and the two second heat dissipation interfaces 401 are respectively connected to the two second liquid cooling interfaces 103, to implement connection between the second heat dissipation module 400 and the heat exchange module 100. A first heat sink 402 may be disposed inside the second heat dissipation module 400, and the first heat sink 402 is separately connected to the two second heat dissipation interfaces 401, to implement connection between the first heat sink 402 and the heat exchange module 100, thereby implementing connection between the first heat sink 402 and the second coolant pipeline 108. For example, the first heat sink 402 may be a natural cooling heat sink.
In a possible implementation, the first heat dissipation module 300 and the second heat dissipation module 400 may be integrated, so that integration can be further improved, and space utilization can be improved. As shown in
In a possible implementation, a housing of the liquid cooling module 200 may have two heat exchange interfaces 201. During connection, the two heat exchange interfaces 201 are respectively connected to the two first liquid cooling interfaces 102. A cold plate 202 may be disposed inside the liquid cooling module 200, and the cold plate 202 is separately connected to the two heat exchange interfaces 201. The coolant flows through the cold plate 202, and the cold plate 202 may perform heat exchange with the load 203. For example, the coolant fully performs heat exchange with the load 203 by using the cold plate 202, thereby improving heat exchange efficiency.
In a possible implementation, a heater 111 may be further disposed inside the heat exchange module 100, and the heater 111 is connected between the heat exchanger 104 and one first liquid cooling interface 102. For example, the heater 111 is connected in the first coolant pipeline 107, and the heater 111 may heat the coolant in the first coolant pipeline 107, so as to perform heat exchange on the load 203. For example, the load 203 is heated. In a possible implementation, the heater 111 may be an electric heater 111 suitable for heating the coolant. For example, the heater 111 may use a positive temperature coefficient (PTC) thermistor, which is also referred to as a PTC thermistor or PTC. When the ambient temperature is low, for example, in winter, the load 203 such as the battery needs to be heated, so as to stabilize a temperature of the load 203 in a normal temperature range (for example, around 25° C.) before the load 203 is charged and discharged, thereby ensuring charging and discharging performance and use safety of the load 203, and ensuring an optimal service life of the load 203.
In a possible implementation, the heat-generating module 600 is connected between the two heat-generating interfaces 112. A housing of the heat-generating module 600 has two heating interfaces 601. During connection, the two heating interfaces 601 are respectively connected to the two heat-generating interfaces 112. A second heat sink 602 may be disposed inside the heat-generating module 600, and the second heat sink 602 is separately connected to the two heating interfaces 601. The second heat sink 602 may absorb external heat, and heat the refrigerant in the heat-generating pipeline 113, so as to implement heat exchange between the refrigerant in the heat-generating pipeline 113 and the coolant in the first coolant pipeline 107 by using the heat exchanger 104, and for example, implement heating for the load 203. The second heat sink 602 may be a heat sink that is suitable for heating a refrigerant, such as an evaporator. During actual application, the load 203 may be heated by using both the heater 111 and the heat-generating module 600.
In a possible implementation, a second pump body 603 may be further disposed inside the heat-generating module 600, and the second pump body 603 is connected in the heat-generating pipeline 113. The second pump body 603 may increase a flow rate of the refrigerant in the heat-generating pipeline 113, so as to improve heat exchange efficiency between the refrigerant in the heat-generating pipeline 113 and the coolant in the first coolant pipeline 107, and for example, improve efficiency of heating the load 203. Alternatively, as shown in
In a possible implementation, a housing of the first heat dissipation module 300 has two first heat dissipation interfaces 301. During connection, the two first heat dissipation interfaces 301 are respectively connected to the two cooling interfaces 101, to implement connection between the first heat dissipation module 300 and the heat exchange module 100. A cooler 302 is disposed inside the first heat dissipation module 300, and the cooler 302 is separately connected to the two first heat dissipation interfaces 301. The cooler 302 may cool a refrigerant. The energy storage apparatus may further include a compressor module 500. The compressor module 500 is connected between one first heat dissipation interface 301 and one cooling interface 101, so that the compressor module 500 is connected between the first heat dissipation module 300 and the heat exchange module 100. A compressor 502 and a gas-liquid separator 503 that are separately connected to the first heat dissipation module 300 and the heat exchange module 100 in sequence may be disposed inside the compressor module 500. The compressor 502 may increase the refrigerant from a low pressure to a high pressure, and enable the refrigerant to continuously flow in circulation, thereby discharging heat of the heat exchange module 100 to an external environment. The gas-liquid separator 503 may filter and remove some moisture from the refrigerant, to reduce a workload of the compressor 502.
A housing of the second heat dissipation module 400 has two second heat dissipation interfaces 401, and the two second heat dissipation interfaces 401 are respectively connected to the liquid cooling module 200 and one first liquid cooling interface 102, to implement connection between the second heat dissipation module 400 and the heat exchange module 100. A first heat sink 402 is disposed inside the second heat dissipation module 400, and the first heat sink 402 is separately connected to the two second heat dissipation interfaces 401, to implement connection between the first heat sink 402 and the heat exchange module 100, thereby implementing connection between the first heat sink 402 and a second coolant pipeline 108.
In a possible implementation, a first fan 303 configured to dissipate heat may be disposed inside the first heat dissipation module 300, and a second fan 403 configured to dissipate heat may be disposed inside the second heat dissipation module 400. That is, the cooler 302 and the first heat sink 402 each may use one fan.
In a possible implementation, the energy storage apparatus may include a cabinet body. In this case, the energy storage apparatus may be referred to as an energy storage cabinet. For reference, the first heat dissipation module 300 and the second heat dissipation module 400 may be disposed outside the cabinet body, and a remaining part of the energy storage apparatus may be disposed inside the cabinet body. A load 203 is disposed inside the liquid cooling module 200. During actual application, in addition to a form of a cabinet body, a container may alternatively be used. In this case, the energy storage apparatus may be referred to as an energy storage container.
The energy storage device provided in the foregoing embodiment may be used in various energy storage scenarios. As shown in
It may be understood that various numbers in embodiments are merely used for differentiation for ease of description, and are not used to limit the scope of embodiments. Sequence numbers of the foregoing processes do not mean execution sequences, and the execution sequences of the processes should be determined based on functions and internal logic of the processes.
The foregoing descriptions are merely possible implementations, but are not intended to limit the scope of the embodiments. Any variation or replacement readily figured out by a person skilled in the art shall fall within the scope of embodiments.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202311095400.0 | Aug 2023 | CN | national |
