KR200497114Y1 - Energy storage power station and heat dissipation device thereof - Google Patents

Abstract

The present application provides a heat dissipation device of an energy storage power station, wherein the heat dissipation device includes a central air conditioner, an indoor unit of the central air conditioner supplies air to the battery compartment through an air supply duct, and the air supply duct is linear and has a step shape in the straight extension direction of the air supply duct, and the cross-sectional area of each step gradually decreases in the direction away from the indoor unit. The air supply duct has a stepped shape with a cross-sectional area that is linear and gradually decreases in the direction away from the indoor unit, which can make the air volume and air velocity of each air outlet on the air supply duct more uniform, and in the battery compartment. It is advantageous for uniform cooling of all batteries in the The present application additionally provides an energy storage station using the above heat dissipation device, and the batteries are cooled in a uniform manner, avoiding different decay of the batteries and eliminating the risk of ignition or even explosion of the batteries.

Description

Energy storage power station and its heat dissipation device {ENERGY STORAGE POWER STATION AND HEAT DISSIPATION DEVICE THEREOF}

This application relates to the field of battery heat dissipation technology in energy storage power stations, and more particularly to a heat dissipation device of an energy storage power station and an energy storage power station.

In energy storage power stations, batteries are placed in battery compartments (such as containers or buildings). A large amount of heat is generated during the charging and discharging process of the battery, which causes the temperature of the battery cell and the temperature of the surrounding environment to be too high and non-uniform. A high-temperature environment accelerates the decay of a battery, and non-uniform temperature will cause different decay of different batteries, which in turn will cause a risk of ignition or even explosion of the batteries.

Currently, room-type energy storage power stations use a central air conditioner to cool the battery compartment. The central air conditioner has a number of indoor units, which are distributed on the roof of the battery compartment, each indoor unit being energized by and exchanging heat with the centralized outdoor unit. The error supply duct of the indoor unit is bent many times, and the cross section is uniform everywhere, so that the air volume and air velocity of the air outlets at different positions of the error supply duct are different, and the batteries in the battery compartment can be uniformly cooled. does not exist.

In summary, the technical problem to be solved that a person skilled in the art would like to achieve is how to improve the uniformity of the air volume and air velocity of each air outlet on the air supply duct. will be.

In light of this, the present application provides a heat dissipation device of an energy storage power station, wherein the air supply duct has a step shape that is linear and gradually decreases in cross-sectional area, which is The air volume and air velocity of each air outlet on the bed can be made more uniform, and it is advantageous for uniform cooling of all batteries in the battery compartment. The present application additionally provides an energy storage power station. By using the heat dissipation device, all of the batteries can be cooled in a uniform manner, avoiding different decay of the batteries, and eliminating the risk of ignition or even explosion of the batteries.

In order to achieve the above object, the following technical solutions are provided according to the present application.

The heat dissipation device of an energy storage power station includes a central air conditioner. The indoor unit of the central air conditioner supplies air to the battery compartment through the air supply duct, the air outlet is open on one side of the air supply duct facing downward, the air supply duct is linear and has a step shape. and the cross-sectional area of each step gradually decreases in a direction away from the indoor unit.

Preferably, in the heat dissipation device, the axes of each step of the air supply duct coincide with each other, and the air supply duct is symmetrical along the axis of the air supply duct.

Preferably, in the heat dissipation device, an air guild curtain is fixed to an air outlet of the air supply duct.

Preferably, in the heat dissipation device, an outdoor unit of the central air conditioner is in a one-to-one correspondence with an indoor unit.

Preferably, in the heat dissipation device, the central air conditioner is controlled by a controller of the central air conditioner according to an operation strategy of start-stop and charge-discharge of the battery preset by a battery management device in the energy storage power station.

Preferably, in the heat dissipation device, the controller is connected with a temperature sensor, and the temperature sensor is used to detect the environmental temperature of the battery compartment.

The central air conditioner is controlled by the controller to operate to maintain the ambient temperature of the battery compartment at the storage temperature of the battery when the battery is not operating; The central air conditioner is controlled by a controller to operate to ensure that the ambient temperature of the battery compartment meets the requirements of the operating ambient temperature of the battery when the battery is operating.

Preferably, in the heat dissipation device, the ambient temperature of the battery compartment is pre-cooled or pre-cooled by the controller to the operating ambient temperature of the battery before the battery operates according to the operation strategy of charge-discharge and start-stop of the battery. It is heated.

Preferably, in the heat dissipation device, the controller is connected to the data collector, and the controller is signalally connected to the Internet; Before the battery is charged or discharged, parameters of the ambient temperature are obtained by the controller through the temperature sensor, parameters of the volume of the battery compartment and parameters of the operating ambient temperature of the battery are obtained according to the data collector, The time for heating or cooling the ambient temperature to the operating ambient temperature is calculated, and the air conditioner is pre-started to heat or cool the surroundings of the battery compartment according to the calculated data.

The time for heat exchange between the remaining temperature and the ambient is calculated by the controller according to the parameter of the meterological temperature obtained from the Internet and the parameter of the ambient temperature obtained from the temperature sensor. Before the charge-discharge of the battery is finished, the central air conditioner is controlled to shut down in advance according to the time, and the operating ambient temperature of the battery is maintained by the residual temperature of the surroundings.

When the battery is in the storage state, the central air conditioner is controlled by the controller to start and stop according to the parameters of the wake-up temperature and the parameters of the ambient temperature, and the ambient temperature is adjusted to remain within the range of the storage ambient temperature of the battery. .

Preferably, in the heat dissipation device, the controller is configured to transmit an air conditioner failure signal and an ambient temperature signal to the battery management device.

Preferably, in the heat dissipation device, the controller of the central air conditioner communicates with the fire control device of the energy storage power station and the central air conditioner is controlled by the controller to stop running when the fire alarm signal of the fire control device is obtained. .

The energy storage power station includes a heat dissipation device, and the heat dissipation device is a heat dissipation device according to any one of the above technical solutions.

The present application provides a heat dissipation device of an energy storage power station, wherein the heat dissipation device includes a central air conditioner. The indoor unit of the central air conditioner supplies air to the battery compartment through the air supply duct, the air supply duct is linear and has a step shape in the straight extension direction of the air supply duct, and the cross-sectional area of each step is in the direction away from the indoor unit. is gradually reduced to

The air supply duct has a stepped shape with a cross-sectional area that is linear and gradually decreases in the direction away from the indoor unit, which can make the air volume and air velocity of each air outlet on the air supply duct more uniform, and in the battery compartment. It is advantageous for uniform cooling of all batteries in the

The present application additionally provides an energy storage station. By using the heat dissipation device described above, all batteries are cooled in a uniform manner, avoiding differential decay of the batteries and eliminating the risk of ignition or even explosion of the batteries.

BRIEF DESCRIPTION OF THE DRAWINGS To describe the embodiments of the present application and the technical solutions in the prior art more clearly, the drawings referred to for explaining the technical solutions in the prior art will be briefly described hereinafter. Obviously, the drawings in the following description are merely some examples of the present application, and to those skilled in the art to which the present invention belongs, other drawings are obtained based on the drawings provided without any creative effort. It can be.
1 is a layout diagram of a heat dissipation device of an energy storage power station according to an embodiment of the present application.
2 is a schematic diagram of an assembly of a battery rack and a heat dissipation device in a battery compartment according to an embodiment of the present application.
3 is a schematic diagram showing the structure of a heat dissipation device according to an embodiment of the present application.
4 is a perspective view showing the structure of a heat dissipation device according to an embodiment of the present application.
5 is a top view of a battery compartment according to an embodiment of the present application.
6 is a schematic diagram of communication of a controller according to an embodiment of the present application.

The present application provides a heat dissipation device of an energy storage power station, wherein the air supply duct has a step shape that is linear and gradually decreases in cross-sectional area, which makes the air volume and air velocity of each air outlet on the air supply duct more uniform. It is advantageous for uniform cooling of all batteries in the battery compartment. The present application additionally provides an energy storage station. By using the heat dissipation device described above, all batteries are cooled in a uniform manner, avoiding differential decay of the batteries and eliminating the risk of ignition or even explosion of the batteries.

Technical solutions in the embodiments of the present application will be clearly and completely described below with reference to drawings in the embodiments of the present application. The described embodiments are not all embodiments, but only some of the embodiments of the present application. Based on the embodiments of the present application, all other embodiments made by a person skilled in the art to which the present invention pertains fall within the scope of the present application.

1 to 6 , an embodiment of the present application provides a heat dissipation device of an energy power station, including a central air conditioner. The indoor unit of the central air conditioner provides air to the battery compartment through the air supply duct 104; The air supply duct 104 is linear and has a step shape in the linear extension direction of the air supply duct 104, and the cross-sectional area of each step gradually decreases in the direction away from the indoor unit. An air outlet is open on one side of the air supply duct 104 facing downward.

The air supply duct 104 has a step shape with a linear and gradually decreasing cross-sectional area, which can make the air volume and air velocity of each air outlet on the air supply duct 104 more uniform, and all indoor batteries (10) is advantageous for uniform cooling.

Each step in the air supply duct 104 has a columnar structure, and the axes of each step coincide with each other, and the axis is the axis of the air supply duct 104 . The air supply duct 104 is symmetrical along the axis of the air supply duct 104, which can additionally ensure uniformity of air volume and air velocity at all air outlets. An air outlet is provided at each step in the air supply duct 104, and the cross-sectional area of each step is rectangular.

The air guide curtain 105 is fixed to the air outlet of the air supply duct 104. The air guide curtain 105 is disposed in the vertical direction of the air supply duct 104.

In application, the two battery racks may be disposed opposite to each other (ie, the rear surfaces of the batteries 10 on the battery racks are adjacent to each other), and the gap between the two battery racks A gap is located directly below the air supply duct 104, and both ends of the gap in the horizontal direction are closed by baffles 11. Through this arrangement, the air guide curtain 105 allows airflow to flow vertically downward instead of obliquely downward, resulting in flow through the batteries 10 on the battery racks. The airflow rate and the flow rate are the same, thus achieving the same effect of cooling the batteries 10 everywhere and accurately cooling the batteries. In the solution according to this embodiment, the air from the air conditioner first enters the gap area between the two battery racks, and then from the gap between the batteries 10 on the battery racks to the front end of the batteries 10. flow and then return to the air return port of the indoor unit 102 to avoid turbulence due to the interaction between the airflows and between the airflows and the wall of the battery compartment; The air supply duct 104 is matched with an air guide curtain 105 to effectively improve the air flow path in the battery compartment, to prevent the flow from returning air without cooling the battery 10, thereby It can improve the utilization rate of the air outlet of the air conditioner, save energy, and additionally save energy without heating or cooling the whole environment of the battery compartment. In addition, the solution according to the present application adopts a solution in which cold air enters the rear of the battery rack and hot air comes out from the front, resulting in a better effect of alternating cold and hot air circulation. Additionally, in the solution according to the present application, when the battery compartment room is enlarged, it can be repeated in an array according to the above solution, and the airflow of the central air conditioner will not cause more complicated fluid interference, Thus reproducibility is enhanced.

The outdoor units 101 and indoor units 102 of the central air conditioner have a one-to-one correspondence with each other (ie, the number of outdoor units 101 and indoor units 102). is the same, and each outdoor unit 101 is connected to a different indoor unit 102). Also, the outdoor unit 101 and the corresponding indoor unit 102 are arranged nearby, resulting in a reduction in the length of the air conditioning duct 103 for connecting the outdoor unit 101 and the indoor unit 102. and energy consumption can be reduced. The air conditioning duct 103 is fixed on the indoor unit cover 121 of the indoor unit 102 and communicates with the indoor cover unit 121; An air recovery port facing downward is provided on the indoor unit cover 121 . There are at least two central air conditioners in the battery compartment, and when one central air conditioner fails, the other central air conditioner can continue to operate, reducing the effect of temperature increase or decrease.

In the heat dissipation device of the above embodiment, the controller 106 of the central air conditioner is in signal connection with the battery management device of the energy storage power station. The central air conditioner is controlled by the controller 106 according to the operation strategy of start-stop and charge-discharge of the battery preset by the battery management device in the energy storage power station.

The controller 106 is connected with a temperature sensor for detecting the ambient temperature of the battery compartment; When the battery 10 is not operating, the central air conditioner is controlled by the controller 106 to operate to maintain the ambient temperature of the battery compartment at the storage temperature of the battery 10; When the battery 10 is operating, the central air conditioner is controlled by the controller 106 to operate to ensure that the ambient temperature of the battery compartment meets the requirements of the operating ambient temperature of the battery 10, thereby powering effectively save

The ambient temperature of the battery compartment is determined by the controller 106 before the battery 10 operates according to the charge-discharge and start-stop operating strategies of the battery 10 to ensure that the battery 10 operates at the proper temperature. by pre-cooling or pre-heating to the operating ambient temperature of the battery 10, thereby prolonging the service life of the battery 10.

In addition, the controller 106 is connected to the data collector, and the controller 106 is signalally connected to the Internet; Before the battery 10 is charged or discharged, parameters of the ambient temperature are obtained by the controller 106 via a temperature sensor, parameters of the volume of the battery compartment and parameters of the operating ambient temperature of the battery are obtained according to the data collector, , the time T1 for heating or cooling the ambient temperature to the operating ambient temperature of the battery is calculated, and the air conditioner is pre-started to heat or cool the surroundings of the battery compartment according to the calculated data (i.e., the battery 10 ) is charged and discharged, the air conditioner is turned on to heat or cool the surroundings of the battery compartment.

Before the charging and discharging of the battery 10 is finished, the remaining temperature and the time T2 for heat exchange between the surroundings are parameters of the meterological temperature obtained from the Internet and parameters of the ambient temperature obtained from the temperature sensor. It is calculated by the controller 106 according to The central air conditioner is controlled to shut down in advance according to time T2 (that is, the central air conditioner is controlled to stop at time T2 before the battery 10 stops discharging), and the operating ambient temperature of the battery is the remaining ambient temperature ( maintained by residual temperature).

When the battery 10 is in the storage state, the central air conditioner is controlled by the controller 106 to start and stop according to the parameter of the wake-up temperature and the parameter of the ambient temperature, and the ambient temperature is the storage ambient temperature of the battery 10 is adjusted to remain within the range of

In the heat dissipation device according to this embodiment, the controller 106 predicts that the wake-up temperature and the ambient temperature will rise or fall outside the operating or storage temperature range of the battery 10 according to the preset operating strategy of charge-discharge of the battery. ) determines, the ambient temperature of the battery compartment is either pre-cooled or pre-heated by the controller 106 .

Preferably, in the heat dissipation device according to the above embodiment, the controller 106 is in signal connection with the fire control device of the energy storage power station. When the alarm start signal of the fire control device is obtained, the central air conditioner is controlled by the controller 106 to stop operation to prevent the air flow from aggravating the fire spread. The smoke detector 202 of the fire control device is mounted on the air return port of the indoor unit 102 to improve the speed and accuracy of the smoke detector 202 obtaining smoke information. In case the central air conditioner fails and shuts down, air conditioner failure information is sent by the controller 106 to the battery management device, so that the battery management device can control the battery 10 to stop charging and discharging; , thereby reducing operational hazards. The temperature sensor may transmit ambient temperature parameters to the battery management device via the controller 106 . When the ambient temperature exceeds the operating temperature of the battery 10, the battery 10 is controlled by the battery management device to stop charging and discharging, thereby improving the safety of operation of the energy storage power station.

The fire control device is a fire control cabinet 204, and a fire gas tank 203 is placed in the battery compartment; The fire pipes 201 of the battery compartment are distributed and provided to a plurality of fire sprinklers 205, which sprinklers 205 can spray fire-fighting medium at multiple points simultaneously, and quickly can fill the battery compartment with firefighting media, effectively and timely eliminate the fire hazard; When the controller detects the alarm start signal fed back by the fire control device, the central air conditioner is controlled by the controller to stop, so as to prevent the airflow from the air conditioner from affecting the extinguishing work of the extinguishing medium.

The controller 106 of the central air conditioner, the fire control device and the battery management device communicate with the cloud platform through the wireless transmission module of the inverter, and the ambient temperature of the battery compartment, the fire situation and the battery operation status are monitored in real time. In case of abnormality, the cloud platform will send an alarm action simultaneously with the on-site alarm action, adjust the control strategy of the air conditioner and charge-discharge and shutdown of the battery, as well as implement fire extinguishing; or To eliminate misjudgments and stop erroneous fire extinguishing actions, the above three control devices can be manually operated in the background to implement manual operation.

An embodiment of the present application further provides an energy storage power station comprising a heat dissipation device, wherein the heat dissipation device is a heat dissipation device according to the above embodiment, which ensures that the batteries can be cooled in a uniform manner, Different decay of the batteries can be avoided and the risk of ignition or even explosion of the batteries can be eliminated. Of course, the energy storage power station according to this embodiment also has other effects of the heat dissipation device according to the above embodiment, which will not be described in detail herein.

The above embodiments have been described in an incremental manner. Each of these embodiments focuses primarily on explaining the differences of each embodiment relative to other embodiments, and references may be made among these embodiments with respect to the same or similar parts.

According to the above description of the presented embodiments, a person of ordinary skill in the art to which the present invention pertains may implement or implement this application. Various modifications to these embodiments are obvious to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit and scope of the present application. can Thus, this application is not limited to the embodiments presented herein, but is to be accorded the widest scope according to the principles and novel features presented herein.

10: battery
11: baffle
101: outdoor unit
102: indoor unit
121: indoor unit cover
103: air conditioning duct
104: air supply duct
105: air guide curtain
106: controller
201: fire pipe
202 Smoke detector
203: fire gas tank
204: fire control cabinet
205: fire sprinkler

Claims (11)

As an energy storage power station,
Battery racks and batteries disposed on the battery racks; and
a heat dissipation device;
The heat dissipation device,
a central air conditioner, wherein an indoor unit of the central air conditioner supplies air to a battery compartment through an air supply duct, the air outlet of which is directed downward; open on one side of the duct,
The axis of the air supply duct is linear and the air supply duct has a step shape in the linear extension direction of the air supply duct, and the cross-sectional area of each step gradually decreases in a direction away from the indoor unit,
Each of the two battery racks are disposed opposite to each other, and a gap between the two battery racks is located directly under the air supply duct, and both ends of the gap in the horizontal direction are baffles closed by, so that airflow flows vertically downward instead of obliquely downward from the air supply duct,
Energy storage power station. According to claim 1,
the axes of each step of the air supply duct coincide with each other, and the air supply duct is symmetrical along the axis of the air supply duct;
Energy storage power station. According to claim 1,
An air guild curtain is fixed to the air outlet of the air supply duct.
Energy storage power station. According to claim 1,
The outdoor unit of the central air conditioner has a one-to-one correspondence with the indoor unit,
Energy storage power station. According to claim 1,
wherein the central air conditioner is controlled by a controller of the central air conditioner according to an operating strategy of charge-discharge and start-stop of a battery preset by a battery management device in the energy storage power station.
Energy storage power station. According to claim 5,
the controller is connected to a temperature sensor, the temperature sensor being used to detect the environmental temperature of the battery compartment;
The central air conditioner is controlled by the controller to operate to maintain the ambient temperature of the battery compartment at the storage temperature of the battery when the battery is not operating, and the central air conditioner operates at the storage temperature of the battery when the battery is operating. controlled by the controller to operate to ensure that the ambient temperature of the battery compartment meets the requirements of the operating ambient temperature of the battery;
Energy storage power station. According to claim 6,
The ambient temperature of the battery compartment is pre-cooled or pre-heated by the controller to the operating ambient temperature of the battery before the battery operates according to the operation strategy of charge-discharge and start-stop of the battery.
Energy storage power station. According to claim 7,
The controller is connected to a data collector, the controller is signally connected to the Internet, before the battery is charged or discharged, the parameter of the ambient temperature is obtained by the controller through the temperature sensor, and the battery compartment A parameter of the volume of and a parameter of the operating ambient temperature of the battery are obtained according to the data collector, the time for heating or cooling the ambient temperature to the operating ambient temperature of the battery is calculated, and the air conditioner is pre-started to heat or cool the periphery of the battery compartment according to the calculated data,
Before the charge-discharge of the battery is finished, the time for heat exchange between the remaining temperature and the ambient is a parameter of the meterological temperature obtained from the Internet and the ambient temperature obtained from the temperature sensor. calculated by the controller according to a parameter of , the central air conditioner is controlled to shut down in advance according to the time, and the operating ambient temperature of the battery is maintained by the residual temperature of the ambient;
When the battery is in the storage state, the central air conditioner is controlled by the controller to start and stop according to the parameter of the wake-up temperature and the parameter of the ambient temperature, wherein the ambient temperature is equal to the storage ambient temperature of the battery. adjusted to remain within the range,
Energy storage power station. According to claim 6,
Wherein the controller is configured to transmit an air conditioner failure signal and an ambient temperature signal to the battery management device.
Energy storage power station. According to claim 1,
wherein a controller of the central air conditioner communicates with a fire control device of the energy storage power station and the central air conditioner is controlled by the controller to stop running when a fire alarm signal of the fire control device is obtained.
Energy storage power station. delete