KR102112144B1 - A Module Type Air Conditioning System for ESS - Google Patents

Abstract

The present invention relates to a modular air conditioning system for ESS, and more specifically, by combining an air circulation device on one surface of the ESS housing, to supply cold air into the ESS housing, and the air circulation devices coupled to the plurality of ESS housings It is possible to receive cold air through close coupling, and by cooling the air to one side of the air circulation device, the cooling device supplied to the air circulation device is tightly coupled to enable efficient supply of cold air in each ESS housing, and ESS The present invention relates to a modular air conditioning system that makes it easy to install, expand, and change the air conditioning system for a device.

Description

A module type air conditioning system for ESS}

The present invention relates to a modular air conditioning system for ESS, and more specifically, by combining an air circulation device on one surface of the ESS housing, to supply cold air into the ESS housing, and the air circulation devices coupled to the plurality of ESS housings It is possible to receive cold air through close coupling, and by cooling the air to one side of the air circulation device, the cooling device supplied to the air circulation device is tightly coupled to enable efficient supply of cold air in each ESS housing, and ESS The present invention relates to a modular air conditioning system that makes it easy to install, expand, and change the air conditioning system for a device.

In general, ESS (Energy Storage System) refers to a storage device that stores excess power generated by a power plant and transmits it temporarily when power is insufficient. In recent years, large-scale ESS devices have been constructed in small sizes to accommodate general customers such as buildings, factories, and homes. In many cases, it is used for blackout preparation or peak power reduction.

Recently, as interest in new and renewable energy has rapidly increased due to the imbalance of power supply and demand, development of technologies that utilize the new and renewable energy through ESS to store and utilize it at the required time has been continuously developed. have.

In particular, the ESS market continues to grow as the installation of ESSs in public buildings that are newly built is obligatory, and the installation of ESSs in energy savings is also increasing in private buildings.

When installing an ESS in a building, etc., the battery rack for storing energy in the battery rack of the ESS as shown in the patent document below, BMS managing the battery, PCS converting power, and the like are accommodated. It is accepted for operation.

At this time, a large amount of heat is generated from the battery of the ESS system, and excessive heat may have a fatal effect on the entire ESS system. Currently, only the entire space in which the ESS system is accommodated is cooled. There is a problem in that cooling for each battery accommodated in the battery rack is not properly performed.

(Patent literature)

Publication Patent Publication No. 10-2016-0094216 (published 08. 09. 2016) "ESS Battery RACK"

The present invention was made to solve the above problems,

An object of the present invention is to provide a modular air conditioning system that enables efficient cooling of an ESS device in each ESS housing, and makes it easy to install, expand, and change the air conditioning system for the ESS device.

An object of the present invention is to provide a modular air conditioning system that enables the installation of an efficient air conditioning system suitable for the power capacity of the ESS device accommodated in each ESS housing.

The present invention is implemented by an embodiment having the following configuration in order to achieve the above object.

According to an embodiment of the present invention, the modular air conditioning system according to the present invention includes an ESS housing that provides a plurality of internal spaces to accommodate ESS devices in each space; An air circulation device coupled to one surface of the ESS housing to supply cold air in the ESS housing; A cooling device that cools the air and supplies it to the air circulation device, and the air circulation devices respectively coupled to the plurality of ESS housings are coupled and connected detachably to receive cold air from one cooling device.

According to another embodiment of the present invention, in the modular air conditioning system according to the present invention, the number of air circulation devices receiving cold air from one cooling device is the power of the ESS device accommodated in the ESS housing combined with the air circulation device. It is characterized in that it is determined by summing the capacity.

According to another embodiment of the present invention, in the modular air conditioning system according to the present invention, the air circulation device is formed with a width corresponding to one surface of the ESS housing and coupled to the enclosure; It is formed in the enclosure, cold air flows into one side and is supplied into the ESS housing, and the remaining cold air flows out to the other side; and includes, and the cold air supply unit to transfer cold air to the air circulation device connected to the other side It is characterized by.

According to another embodiment of the present invention, in the modular air conditioning system according to the present invention, the cold air supply unit includes a cold air supply duct forming a flow path through which cold air flows from one side to the other, and an ESS housing at one point of the cold air supply duct. It characterized in that it comprises a cold air supply pipe to form a passage connected to the inside, and cold air supply means formed on the cold air supply pipe to supply cold air from the cold air supply duct into the ESS housing.

According to another embodiment of the present invention, in the modular air conditioning system according to the present invention, each of the cold air supply ducts of the air circulation devices adjacent to each other is characterized in that communicating with each other so as to deliver cold air.

According to another embodiment of the present invention, in the modular air conditioning system according to the present invention, the cooling device is in close contact with the air circulation device and the heat exchange means for cooling the air supplied to the air circulation device And, from the cold air circulation pipe and the cold air circulation pipe connected to the cold air supply unit to form a path through which the cooled air is transferred to the air circulation device, and the outside air inlet pipe for introducing the outside air into the housing to be cooled by the heat exchange means. It characterized in that it comprises a cold air blowing means for supplying cold air to the cold air supply.

According to another embodiment of the present invention, in the modular air conditioning system according to the present invention, the outside air inlet pipe is characterized in that it comprises a fine dust filter to filter out fine dust from the outside air.

According to another embodiment of the present invention, in the modular air conditioning system according to the present invention, the air circulation device further includes a heat recovery unit that absorbs heat discharged from each ESS housing and recovers it to a cooling device. It is characterized in that the heat recovery parts of each air circulation device are connected to each other so that the absorbed heat can be recovered by the cooling device at the same time.

According to another embodiment of the present invention, in the modular air conditioning system according to the present invention, the heat recovery unit is formed in the enclosure, and the heat recovery duct to recover the heat from the ESS housing to be recovered to the cooling device side; A hot air suction pipe branched at a point of the hot air recovery duct to form a path through which hot air is sucked from the ESS device; It is formed on the hot air suction pipe and includes a hot air suction means for absorbing hot air, and the hot air recovery ducts of the air circulation devices adjacent to each other are in communication with each other so as to be able to transfer the sucked hot air.

According to another embodiment of the present invention, in the modular air conditioning system according to the present invention, the air circulation device is connected to the cold air supply unit and the hot air recovery unit to be supplied to the ESS housing from the cold air supply unit and the remaining cold air to the hot air recovery unit Further comprising an air circulation unit that is combined with the heat absorbed by the air to be recovered by the cooling unit, the air circulation unit to be formed in the air circulation unit of the far end and the cooling unit among the plurality of air circulation units connected to the cooling unit It is characterized by.

According to the present invention, the following effects can be obtained according to the configuration, combination, and use relationship described above with respect to the present embodiment.

The present invention combines an air circulation device on one side of the ESS housing so that cold air is supplied into the ESS housing, and the air circulation devices coupled to the plurality of ESS housings are tightly coupled to each other so that cold air can be delivered. By cooling the air on one side, the cooling devices supplied to the air circulation device are tightly coupled to enable efficient supply of cold air in each ESS housing, and it is very easy to install, expand, and change the air conditioning system for the ESS device. There is an effect that can be made.

The present invention has an effect of enabling efficient cooling of each ESS device by determining the number of air circulation devices receiving cold air from one cooling device according to the capacity of the ESS battery or the like accommodated in the ESS housing.

According to the present invention, the air circulation device is formed of an outer portion formed in a width corresponding to the ESS housing and a cold air supply portion in the outer portion, so that each ESS housing is closely adhered to, and the outer portion is also in close contact to allow circulation of cold air through the cold air supply portion. It has the effect.

The present invention provides cold air to each ESS housing and absorbs heat from the ESS housing, and the absorbed heat is recovered by a cooling device to cool, and is supplied to each ESS housing, thereby further providing an ESS device. It has the effect of enabling efficient cooling.

According to the present invention, the cooling air supply unit for supplying cold air to each ESS housing and the heat recovery unit for absorbing and recovering heat from each ESS housing are connected to each other so that cooling air is not discharged to the outside at the end of the air circulation device, so that cooling is performed. There is an effect that enables efficient driving of the device.

1 is a block diagram of a modular air conditioning system according to an embodiment of the present invention
Figure 2 is a block diagram of the air circulation device of Figure 1
3 is a block diagram of the cooling device of FIG. 1
Figure 4 is a reference diagram showing the flow of cold air by Figure 1
5 is a cross-sectional view showing the internal configuration of the ESS housing of FIG. 1;
Figure 6 is a reference diagram showing the flow of cold air through the vertical cold flow path of Figure 5
Figure 7 is a reference diagram showing the flow of cold air through the horizontal cold flow path of Figure 5
8 is a block diagram showing the configuration of a control unit of a modular air conditioning system according to an embodiment of the present invention
9 is a block diagram of a modular air conditioning system according to another embodiment of the present invention
10 is a block diagram of the air circulation device of FIG. 9;
11 is a block diagram of the cooling device of FIG. 9;
12 is a reference diagram showing the flow of cold air and heat by FIG. 9;
13 is a block diagram showing an air circulation system of a modular air conditioning system according to another embodiment of the present invention
14 is a reference diagram showing a combined state of the air circulation device according to FIG. 13;

Hereinafter, preferred embodiments of a modular air conditioning system for an ESS according to the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, when it is determined that a detailed description of known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. Throughout the specification, when a part “includes” a certain component, it means that the component may further include other components, not exclude other components, unless otherwise stated. The terms "... unit", "... module", etc. refer to a unit that processes at least one function or operation, and may be implemented by hardware or software or a combination of hardware and software.

When describing a modular air conditioning system for an ESS according to an embodiment of the present invention with reference to FIGS. 1 to 8, the modular air conditioning system is provided with a plurality of internal spaces to accommodate the ESS device E in each space. ESS housing (5) to be possible; An air circulation device (1) coupled to one surface of the ESS housing (5) to supply cold air into the ESS housing (5); A cooling device (3) coupled to the air circulation device (1) to cool and supply air to the air circulation device (1); It includes a control unit 7 for controlling the supply of cold air.

The modular air conditioning system according to the present invention enables efficient cooling for each ESS device E accommodated in the ESS housing 5, and enables the system to be installed and operated very easily. The modular air conditioning system allows the air circulation device 1 for circulating the air cooled by the cooling device 3 to be detachably coupled to one surface of the ESS housing 5 accommodating the plurality of ESS devices E. Then, the cool air is supplied into the ESS housing 5 together with the combination of the air circulation device 1. In addition, the cooling device 3 for supplying cold air is installed on one side of the ESS housing 5 to be in close contact with and coupled to the ESS housing 5 and the air circulation device 1, and the air circulation device 1 together with the combination Supply cold air to the ESS housing 5 to be delivered. In particular, the air circulation devices 1 coupled to each ESS housing 5 are also tightly coupled to each other so that cold air can be delivered, and through this, a plurality of air circulation devices 1 from one cooling device 3 ) And ESS housing (5) to be supplied with cold air to facilitate installation and efficient cooling. At this time, the number of the air circulation device 1 and the ESS housing 5 connected to one cooling device 3 can be determined according to the capacity of the ESS devices E accommodated in each ESS housing 5. . In the present invention, the ESS device E may mean a battery capable of storing energy, and may include devices such as BMS and PCS necessary for the operation of the ESS device E. Accordingly, the modular air conditioning system calculates the power capacity of the ESS devices E accommodated in each ESS housing 5 to predict the heat generation amount, and through this, the air circulation receiving cold air from one cooling device 3 By determining the number of devices 1 and ESS housing 5, an efficient cooling system can be constructed. In addition, by connecting and installing the ESS housing 5 in which the cooling device 3 and the air circulation device 1 are combined according to the determined number, and repeatedly installing the cooling device 3 and the ESS housings 5 adjacently, It is possible to accommodate a large number of ESS devices (E) in a given space, yet it is possible to enable efficient cooling for each ESS device (E), each cooling device (3), air circulation device (1) and Since it is sufficient to just tightly combine the ESS housings 5, it is possible to make the installation, management and operation of the air conditioning system very easy.

The air circulation device (1) receives cold air from the cooling device (3), and is configured to transfer the supplied cold air into the ESS housing (5), to be coupled to one surface of each ESS housing (5). The air circulation device 1 can be coupled to any position, such as an upper side, a lower side, and one side of the ESS housing 5, but is preferably configured to be seated and coupled to the upper surface of the ESS housing 5 to construct a simple device. This is possible, and it is possible to make a stable and convenient combination. In addition, since cold air is generally flowed to the lower side, the air circulation device 1 is installed on the upper surface of the ESS housing 5 so that the cold air can flow to the lower side so as to minimize energy consumed in supplying the cold air. You may. In addition, the air circulation devices 1 coupled to each ESS housing 5 can be in close contact with each other, and through this, the circulation of cold air can be made between the air circulation devices 1 to be coupled. As described, the number of air circulation devices 1 coupled according to the power capacity of the ESS devices E accommodated in the ESS housing 5 may be calculated. The air circulation device (1) forms an outer shape of the air circulation device (1) as shown in Figure 2, and the enclosure 11 coupled to the ESS housing (5); It may be formed in the enclosure portion 11, cold air is introduced into one side is supplied into the ESS housing (5), the remaining cold air is supplied to the other side cold air supply (12).

The enclosure 11 may be formed to be coupled to one surface of the ESS housing 5, preferably an upper side of the ESS housing 5, and the shape of a rectangular parallelepiped having a width corresponding to the width of the ESS housing 5 It can be formed as. The enclosure 11 may be formed in various shapes, but may be formed to have a width corresponding to the ESS housing 5 in order to enable close / combination with an adjacent air circulation device 1. Accordingly, when the ESS housing 5 is in close contact, the enclosure 11 of each air circulation device 1 coupled to each ESS housing 5 can also be brought into close contact with each other. Therefore, the cold air supply pipe 122 to be described later formed in the enclosure 11 is connected to each other with close contact of the enclosure 11 to allow circulation of cold air. The enclosure 11 is seated and coupled to the ESS housing 5 on its lower side, and on one side, the enclosure 11 is in close contact with the enclosure 11 or the cooling device 3 of an adjacent air circulation device 1 to be coupled. It can be configured to be coupled and separated through a separate fastening means (not shown).

The cold air supply unit 12 is formed in the enclosure 11 to circulate cold air, and is configured to supply cold air to the ESS housing 5 on which the enclosure 11 is seated. ) To receive the cooled air, transfer the supplied cold air to each ESS housing (5), and circulate the remaining cold air to the adjacent air circulation device (1). Therefore, as shown in FIG. 4, the cold air supply unit 12 of the air circulation device 1 'coupled to be in close contact with the cooling device 3 receives cold air directly from the cooling device 3 to the ESS housing 5 Supply, the remaining remaining cold air to be supplied is transferred to the cold air supply unit 12 of the air circulation device 1 ′ coupled to be in close contact with the corresponding air circulation device 1 ′, and the air circulation device 1 located at the most distal end The cold air supply 12 of '' ') allows the remaining cold air to be discharged to the outside. Therefore, the system enables efficient cooling of a plurality of ESS housings 5 with one cooling device 3, and at the same time, discharges the remaining cold air to the outside to cool the space where the ESS housings 5 are installed. It should also be possible. The cold air supply unit 12 is a cold air supply pipe connected to the ESS housing 5 branched at a point of the cold air supply duct 121 and the cold air supply duct 121 forming a passage through which cold air flows, as illustrated in FIG. 2. (122), the cold air supply pipe 122 may include a cold air supply means 123 for supplying the cold air to the ESS housing (5).

The cold air supply duct 121 is formed to pass through the other side from one side of the enclosure 11 to form a passage through which cold air circulates. On one side, a cold air inlet 121a through which cold air flows is formed, and the cold air is provided on the other side. The cold air outlet 121b may be formed, and the cold air supply pipe 122 is branched to the ESS housing 5 at one point between the cold air inlet 121a and the cold air outlet 121b, so that the ESS housing ( 5) so that cold air can be supplied. The cold air inlet 121a may be formed such that the cold air circulation pipe 34 to be described later of the cooling device 3 communicates with each other, or the cold air outlet 121b of the other air circulation device 1 is closely connected to each other. The cold air inlet 121b may be in close contact with or connected to the cold air inlet 121a of the other air circulation device 1, or may be in communication with the outside so that cold air is discharged to the outside. Therefore, only by closely coupling the cooling device 3 and the air circulation device 1, the circulation and supply of cold air can be made to each ESS housing 5, and the cooling air is discharged to the outside. Can be.

The cold air supply pipe 122 is configured to be branched from one point of the cold air supply duct 121 toward the ESS housing 5, and a path through which cold air flowing through the cold air supply duct 121 is supplied to the ESS housing 5 To form. The cold air supply pipe 122 is preferably branched to the lower side of the cold air supply duct 121 to be connected to the lower ESS housing 5, and is configured to communicate with the cold air intake 52 to be described later of the ESS housing 5 can do. In addition, the cold air supply means 123 is formed on the cold air supply pipe 122 so that the cold air flowing through the cold air supply duct 121 flows into the cold air supply pipe 122 to be supplied to the ESS housing 5.

The cold air supply means 123 is formed on the cold air supply pipe 122 so that cold air is supplied to the ESS housing 5 side, and various methods may be applied, but it is formed of a blower fan, etc., thereby providing a cold air supply duct 121 In the ESS housing (5) it can be made to generate the flow of air. As described above, since the cold air is generally flowed from the upper side to the lower side, it is possible to reduce power consumed in the operation of the cold air supply means 123 as the cold air supply pipe 122 is formed from the upper side to the lower side.

The cooling device 3 is configured to supply cooled air to the air circulation device 1 and the ESS housing 5, so that cooling can be performed by introducing outside air, and the cooled air is tightly coupled. It is transferred to the cold air supply duct 121 of the air circulation device 1 so that it can be supplied to each ESS housing 5. To this end, the cooling device 3 includes a housing 31 forming an outer shape as shown in FIG. 3, a heat exchange means 32 for cooling air through heat exchange, an outside air inlet pipe 33 for introducing outside air, It may include a cold air circulation pipe (34) forming a path through which the cooled air is delivered to the air circulation device (1), and a cold air blowing means (35) for supplying cold air through the cold air circulation pipe (34). have.

The housing 31 is configured to form the outer shape of the cooling device 3, and is formed in a shape corresponding to the outer shape of the ESS housing 5 and the air circulation device 1, so that close coupling can be achieved. have. Accordingly, the cold air circulation pipe 34 and the cold air supply pipe 122 of the air circulation apparatus 1 are coupled with the housing 31 in close contact with and coupled to the ESS housing 5 to which the air circulation apparatus 1 is coupled. It can be connected to allow circulation and supply of cold air. In addition, a heat exchange means 32, an outside air inlet pipe 33, a cold air circulation pipe 34, and a cold air blowing means 35 are formed in the housing 31.

The heat exchange means 32 is configured to cool the outside air flowing through the outside air inlet pipe 33, and various methods for cooling air, such as a cooler, may be applied. The air cooled by the heat exchange means 32 is transferred to the air circulation device 1 through the cold air circulation pipe 34.

The external air inlet pipe 33 is configured to connect external heat exchange means 32 to allow external air to flow in, and to cool the air by introducing air in a space in which the ESS housing 5 is accommodated. By allowing the cool air supplied to the housing 5 to be discharged to the outside through the air circulation device 1, it is possible to have a cooling effect on the space in which the ESS housing 5 is accommodated. In addition, a fine dust filter 331 capable of filtering out fine dust or the like is formed on the outside air inlet pipe 33, so that fine dust contained in the outside air can be prevented from entering the ESS housing 5, , It is possible to prevent the occurrence of problems such as arc generation and overheating in the ESS device (E) by fine dust, and in addition, it is also possible to have an air purification effect for a certain space in which the ESS housing (5) is accommodated.

The cold air circulation pipe 34 is configured to allow air cooled through the heat exchange means 32 to be delivered to the air circulation device 1, one end of which is connected to the heat exchange means 32 and the other end of the cooling device ( It is formed to communicate with the outside of 3). The other end of the cold air circulation pipe 34 communicating with the outside is in contact with the cold air inlet 121a of the adjacent air circulation device 1, through which air cooled through the heat exchange means 32 is an air circulation device (1) is transferred to the cold air supply duct 121 to be supplied to each ESS housing (5).

The cold air blowing means 35 is formed on the cold air circulation pipe 34 to generate a flow of air from the cooling device 3 to the air circulation device 1, and may be formed by a blowing fan or the like. Therefore, the cold air passing through the cold air circulation pipe 34 can be delivered to each connected air circulation device 1, and through the cold air supply means 123 formed in each cold air supply pipe 122 to each ESS housing 5 Is supplied.

4 is a view showing a process in which cold air is supplied by using a modular air conditioning system according to an embodiment of the present invention. When air is introduced through the outside air inlet pipe 33, fine by a fine dust filter 331 As dust is filtered, it is cooled by the heat exchange means 32, and the cooled air is transferred to each air circulation device 1 through the cold air circulation pipe 34 and the cold air supply duct 121, and each air circulation device 1 ) Is supplied to each ESS housing 5 through the cold air supply pipe 122. In addition, the remaining cold air is discharged to the outside from the most distal air circulator (1`` '), and may have a cooling effect on the external space.

The ESS housing 5 is configured to accommodate a plurality of ESS devices E. The ESS housing 5 is divided into areas by the rack shelf 51 to accommodate the ESS devices E. The ESS housing 5 can be divided into a plurality of areas by a rack shelf 51 formed in a horizontal direction as shown in FIG. 5, and can accommodate the ESS devices E in each area. A flow path through which cold air flows is formed in between, so that efficient cooling of each ESS device E is possible. The ESS housing 5 may preferably receive cold air supplied from the air circulation device 1 formed on the upper side, and allow cold air to flow from the upper side to the lower side along one surface of the ESS housing 5, and each ESS Cooling may be performed by forming a flow path of cold air in a horizontal direction between the spaces in which the device E is accommodated. To this end, the ESS housing 5 includes a plurality of rack shelves 51 formed in a horizontal direction to form a plurality of spaces in which the ESS device E is seated; A cold air intake port 52 formed to penetrate the ESS housing 5 and supplied with cold air; A vertical cooling flow path (53) formed in a vertical direction on one side in the ESS housing (5) to flow the cold air flowing through the cold air intake (52); It is formed to penetrate horizontally on the rack shelf (51), and is formed to communicate with the vertical cold flow path (53), a horizontal cold flow path that allows cold air supplied through the vertical cold flow path (53) to flow. (54); may include.

The rack shelf 51 is configured to form a space in which the ESS device E is accommodated, and a plurality of rack shelves 51 may be spaced apart at regular intervals. Accordingly, ESS devices E are inserted and accommodated between the rack shelves 51, and a flow path for cooling air is formed on the rack shelves 51 to cool the surrounding ESS devices E. In addition, the rack shelf 51 may be formed to be spaced apart from the ESS housing 5 so that a vertical cold flow path 53 is formed on one surface, preferably the ESS housing 5 from the rear of the ESS housing 5 It is formed to be spaced apart from the inner surface of the ESS, so that the vertical cooling flow path 53 is formed along the rear surface of the ESS housing 5.

The cold air intake 52 has a configuration through which cold air flows into the ESS housing 5, and preferably can be formed at a point at the top of the ESS housing 5. The cold air intake 52 is formed to be connected to the cold air supply pipe 122 of the air circulation device 1 so that cold air can be supplied, and is preferably formed to pass through a point on the rear side of the ESS housing 5. Can be.

The vertical cold flow path 53 is configured to form a passage through which the cold air flowing through the cold air intake 52 moves along the vertical direction on one surface of the ESS housing 5, and the ESS device E through the front surface It is possible to insert, and to be able to stably support the inserted ESS device (E) from both sides, it is preferable to be formed along the rear surface of the ESS device (E). However, the present invention is not limited thereto, and the vertical cold flow path 53 may be formed at various positions capable of vertical movement of the cold air. The cooling air flowing along the vertical cooling flow path 53 flows into a plurality of horizontal cooling flow paths 54 formed in the horizontal direction to cool the upper and lower ESS devices E, and each horizontal cooling flow path In order to induce the inflow of cold air to 54, a cold air induction member 531 is included, and an additional blowing means 532 is further formed to allow the cold air to reach the bottom of the ESS housing 5 Can be.

The cold air induction member 531 is configured to easily flow cold air flowing along the vertical cold flow path 53 into each horizontal cold flow path 54, where each horizontal cold flow path 54 is connected. It is formed to be formed on one side of, and may be formed to be bent to protrude upward. The cold air induction member 531 is formed to be inclined downward from the upper side toward the inner wall of the ESS housing 5 and the guide plate 531a which is inclined downward from the upper side toward the horizontal cold flow path 54. It may include a flow forming plate (531b).

Accordingly, as shown in FIG. 6, the cold air that strikes the induction plate 531a among the cold air flowing from the upper side to the lower side along the vertical cold flow path 53 flows toward the horizontal cold flow path 54 and flow formation. The cold air hitting the plate 531b hits the side wall to form an irregular flow. Therefore, the cold air passing between the cold air induction member 531 and the side wall flows not only in the vertical direction, but by colliding with the flow forming plate 531b and the side wall to form an irregular flow, while descending and hitting the guide plate 531a again It is possible to hit, and through this, the cold air can be uniformly introduced into each of the horizontal cooler flow paths 54.

The additional blowing means 532 is formed on the vertical cold flow path 53 to move the cold air to the lower side, and may be configured as a blowing fan. The cold air flowing through the vertical cold flow path 53 generates a flow to the lower side by the cold air supply means 123, but as the flow into each horizontal cold flow path 54 is made, its power is weakened and the ESS housing (5) ) Since the flow of cold air may not be achieved to the bottom, an additional blowing means 532 is provided to uniformly flow the cold air to the horizontal cooling flow path 54 at the bottom. In addition, the additional blowing means 532 can be controlled by the operation of the additional blowing control module 73 to be described later of the control unit 7, the temperature measuring module located below the additional blowing means 532 The operation can be adjusted according to the temperature measured by (71). This will be described later.

The horizontal cold flow path 54 is formed on the rack shelf 51 to form a space in which cold air flows in the horizontal direction, and cools the upper and lower ESS devices E accommodated in the rack shelf 51. Make it possible. The horizontal cold flow path 54 may be formed through the rack shelf 51 as shown in FIG. 6, but is not limited thereto, and by forming a separate structure on the upper or lower side of the rack shelf 51. It is also possible to form a flow space for cold air. The horizontal cooling flow path 54 is connected to the vertical cooling flow path 53, so that cold air flowing through the vertical cooling flow path 53 can be introduced, and the other side of the ESS housing 5 is external. The communicating air outlet 541 is formed so that the inflow of cold air into the horizontal cold flow path 54 can be made more effectively. In other words, as the other side of the horizontal cooling flow path 54 communicates with the outside through the air outlet 541, the pressure of the other side is lowered to cool the air flowing through the vertical cooling flow path 53 naturally to the horizontal cooling flow path ( 54). In addition to this, the horizontal cold flow path 54 may be formed to have a smaller inner diameter as it goes toward the air outlet 541 at a point connected to the vertical cold flow path 53 as shown in FIGS. 6 and 7. Through this, the flow rate of the cold air becomes faster as it goes toward the air outlet 541, so that the inflow of cold air from the vertical cold flow path 53 to the horizontal cold flow path 54 can be made more effectively. In addition, the horizontal cooler flow path 54 is formed to be divided into a plurality, so that the cooling of each ESS device E can be performed in a wider area while further smoothing the flow of cold air.

The control unit 7 is configured to control the supply of cold air using a modular air conditioning system. As shown in FIG. 8, the temperature measurement module 71 measures the temperature in the ESS housing 5, and the temperature of the cold air The addition of the air volume control module 72 for adjusting the air volume, the additional air volume control module 73 for controlling the operation of the additional air blowing means 532, the heat exchange control module 74 for controlling the temperature of the cold air, and the cooling device 3 It may include a cooling device additional request module 75 for requesting.

The temperature measurement module 71 is configured to measure whether the cooling by the air conditioning system is properly performed by measuring the temperature in the ESS housing (5), when the temperature in the ESS housing (5) is higher than the set temperature It is possible to control the amount of air blow by the cold air blowing means 35, or to control the cold air supply means 123 of each air circulation device 1, but nevertheless, if the cooling is not performed below a set temperature, the operation of the heat exchange means 32 It is possible to lower the temperature of cold air by adjusting. In addition, if the temperature of the ESS housing 5 does not fall below the set temperature even though the temperature of the cold air is lowered to the set lower limit, it means that too much ESS housing 5 is connected to one cooling device 3. In other words, the installation of the cooling device 3 and the ESS housing 5 can be performed again. In addition, the temperature measurement module 71, as shown in FIG. 5, the temperature at the upper side of the additional blowing means 532 and the lower side of the additional blowing means 532, respectively, the first measurement module 711 and the second It can be measured by the measurement module 712, if the temperature measured by the first measurement module 711 is normal, or only the temperature measured by the second measurement module 712 exceeds the set value. By operating the additional blowing means 532, more cold air can be supplied to the bottom side of the ESS housing 5.

The air volume control module 72 is configured to control the amount of cold air supplied to each ESS housing 5, and controls the operation of the cold air blowing means 35 of the cooling device 3 or the air circulation device 1 It is possible to adjust the operation of the cold air supply means 123. When the temperature measured by the temperature measurement module 71 exceeds a set value, the air volume control module 72 controls the operation of the cold air blowing means 35 so that more cold air is supplied to the entire system. Can be lowered. In addition, preferably, the air volume control module 72 compares the temperature measured in each ESS housing 5 with a set value and cools the air circulation device 1 only for the ESS housing 5 exceeding the set value. By controlling the operation of the supply means 123, more cold air can be supplied to the corresponding ESS housing 5 only. Therefore, the air volume control module 72 increases the air volume of the cold air supply means 123 connected to the specific ESS housing 5 exceeding a set value, and then increases the air volume to the maximum, but the total air volume does not drop It can be controlled to increase, and if this does not drop the temperature can be controlled to further lower the temperature of the cold air.

The additional ventilation control module 73 is configured to control the operation of the additional ventilation means 532, and compares the temperature measured by the first measurement module 711 and the second measurement module 712 as described above. When the temperature by the second measurement module 712 exceeds the set value, the additional blowing means 532 is operated first to lower the temperature of the ESS housing 5 located below the additional blowing means 532, After that, the process of controlling the temperature of the cold air is performed after adjusting the total amount of air blown.

The heat exchange control module 74 adjusts the operation of the heat exchange means 32 when the temperature measured by the temperature measurement module 71 does not fall below a set value even though the air volume is increased by the air volume control module 72. To lower the temperature of the cold air.

The cooling device additional request module 75 is a cooling device when the temperature measured by the temperature measurement module 71 does not fall below a set value even though the temperature of the cold air is lowered to the lower limit by the heat exchange control module 74. Generate a signal requesting the addition of 3). This system calculates the amount of heat generated according to the power capacity accommodated in the ESS housing (5) and calculates the number of air circulation devices (1) and ESS housings (5) connected to one cooling device (3). Since the heat generation amount can be changed depending on the operation of (E) and the surrounding environment, if the temperature of the ESS housing (5) exceeds the set value for the control of the air volume and cold air temperature, a signal requesting the addition of the cooling device (3) is sent. It is to be generated, thereby reducing the number of ESS housings 5 connected to the corresponding cooling device 3 and allowing the additional cooling device 3 to be installed. At this time, the system is sufficient to simply place the air circulation device 1 on the ESS housing 5 and to be in close contact with the other air circulation device 1, so that the system can be changed very easily and quickly.

When describing a modular air conditioning system according to another embodiment of the present invention with reference to FIGS. 9 to 12, the modular air conditioning system is the same as the one embodiment, the air circulation device (1), cooling device (3), ESS It includes a housing (5) and a control unit (7), but additionally absorbs heat generated in the ESS housing (5) to allow cooling. To this end, the air circulation device 1 includes a heat recovery unit 13 that recovers heat from the ESS housing 5 and sends it to a cooling device, and the cooling device 3 cools the recovered heat by cooling The returned air is sent again, and the ESS housing 5 includes a hot air outlet 55 for discharging the generated heat to the air circulation device 1. Therefore, hereinafter, only portions that are different from one embodiment will be described.

The air circulation device 1 further includes a heat recovery unit 13 for recovering heat from the ESS housing 5, and the heat recovery unit 13 is provided with a cold air supply unit 12 as shown in FIG. Together, it is to be formed in the enclosure 11.

The hot air recovery unit 13 sucks heat from the ESS housing 5 and sends it to the cooling device 3, and the cooling device 3 cools it and cools it again through the cold air supply unit 12 to each ESS device E ). Therefore, in the present embodiment, cooling is performed by absorbing heat generated from the ESS housing 5, thereby enabling more efficient cooling of the ESS devices E accommodated in the ESS housing 5, and ESS housing. (5) By inhaling the outside air of the space in which it is accommodated so that cooling is performed, it is possible to simultaneously cool the surrounding space. To this end, the heat recovery unit 13 is formed in a horizontal direction in the enclosure 11 as shown in FIG. 10 to form a flow path through which heat is recovered from the heat recovery duct 131 and the ESS housing 5 It may include a hot air suction pipe 132 that provides a path for inhaling heat, and a hot air suction means 133 formed on the hot air suction pipe 132 to suck hot air.

The hot air recovery duct 131 is formed in the horizontal direction like the cold air supply duct 121, and at one end, a hot air inlet 131a is formed so that hot air sucked from the ESS housing 5 flows in, and hot air is provided at the other end. The outlet 131b is formed so that the heat introduced through the hot air inlet 131a and the hot air suction pipe 132 can be recovered to the cooling device 3 side. The heat recovery duct 131 heats the cooling device 3 in close contact with and combines the air circulation device 1 with the cooling device 3 or the adjacent air circulation device 1 like the cold air supply duct 121. It is connected to the intake pipe 36 or the heat recovery duct 131 of the adjacent air circulation device 1 so that the transfer of the sucked heat can be achieved. In other words, the hot air outlet 131b is connected to the hot air inlet 131a of the adjacent air circulation device 1 or the hot air inlet pipe 36 of the cooling device 3 so that the sucked hot air is recovered to the cooling device 3 side. The hot air inlet 131a is connected to the hot air outlet 131b of the adjacent air circulation device 1 or opened to the outside, and air introduced from the outside and hot air sucked from the ESS housing 5 are introduced. It is to be transferred to the hot air outlet (131b).

The hot air suction pipe 132 is branched from the hot air recovery duct 131 toward the ESS housing 5 to form a path through which the hot air is sucked from the ESS housing 5, and is formed on the upper side of the ESS housing 5 It is preferred. Since heat is generally moved from the lower side to the upper side, the heat generated from the bottom side of the ESS housing 5 rises over time and rises to the top of the ESS housing 5. Therefore, by forming the hot air suction pipe 132 on the upper side of the ESS housing 5 to inhale the hot air, the heat accumulated in the ESS housing 5 is circulated and cooling by circulation of cold air can be made more efficiently. .

The hot air suction means 133 is formed on the hot air suction pipe 132 to generate a flow of heat from the ESS housing 5 to the hot air recovery duct 131, and may be formed by a blowing fan or the like. Accordingly, the heat collected on the upper side of the ESS housing 5 by the operation of the hot air suction means 133 is sucked into the hot air recovery duct 131 along the hot air suction pipe 132 and transferred to the cooling device 3.

Unlike the exemplary embodiment, the cooling device 3 does not separately form the outside air inlet pipe 33, receives the heat sucked through the heat recovery unit 13, cools it, and cools the air through cold air circulation. To circulate through the pipe 34 back to the air circulation device (1). Therefore, the heat generated from the ESS housing 5 is cooled by the cold air supplied by the cold air supply unit 12 and recovered by the cooling device 3 to allow cooling to occur, thereby being relatively performed by the cold air supply unit 12. As a result, even if less cold air is supplied, it is possible to have a better cooling effect. To this end, the cooling device 3 additionally includes a hot air inlet pipe 36 and a hot air inlet means 37.

The hot air inlet pipe 36 is configured such that one end is connected to the heat exchange means 32, and the other end is opened to the outside of the housing 31, and the other end of the hot air inlet pipe 36 is connected to the heat recovery duct 131. It is connected so that the heat recovered can be introduced. The hot air inlet pipe 36 is connected to the hot air recovery duct 131 together with the housing 31 in close contact with and coupled to the air circulation device 1 like the cold air circulation pipe 34, and heat exchange means Allow cooling by (32).

The hot air inflow means 37 is formed on the hot air inlet pipe 36 to suck the heat toward the cooling device 3, and the hot air sucked through the hot air intake pipes 132 of each air circulation device 1 It is possible to have a flow toward the cooling device 3 so that cooling by the heat exchange means 32 can be achieved.

The ESS housing (5) is formed through the hot air outlet (55) on the upper surface of the ESS housing (5) so that heat rising from the ESS housing (5) can be discharged upward through the hot air outlet (55), The hot air suction pipe 132 is connected to the hot air outlet 55 so that hot air can be sucked into the hot air recovery duct 131. In addition, a dust filter 551 is formed on the hot air outlet 55 to prevent the fine dust accumulated in the ESS devices (E) from entering the system, through which the fine dust accumulated in the ESS device (E) It can be removed and blocked from entering the ESS device E again.

When the process of circulating cold and warm air according to this embodiment is described with reference to FIG. 12, cold air is supplied to each ESS housing 5 through the cold air supply pipe 122 as shown in FIG. 12 (a). , Heat is sucked from each ESS housing 5 through the heat suction pipe 132. And, as shown in Figure 12 (b), the cold air that has passed through the cold air circulation pipe 34 of the cooling device 3 is transferred to the cold air supply duct 121 of each air circulation device 1, and each ESS housing 5 It is supplied to the ESS housing (5) through the cold air supply pipe 122 connected to, and is supplied to each ESS housing (5) and the remaining cold air is discharged to the outside. In addition, as shown in FIG. 12 (c), heat is sucked from each ESS housing 5 through the hot air suction pipe 132 and transferred to the hot air inlet pipe 36 through the hot air recovery duct 131, and hot air The hot air flowing into the inlet pipe 36 is cooled by the heat exchange means 32 and is again supplied to each ESS device E through the cold air circulation pipe 34.

Referring to the modular air conditioning system according to another embodiment of the present invention with reference to FIGS. 13 to 14, the air conditioning system has the same configuration as the air conditioning system according to another embodiment, with the difference shown in FIG. 13. As described above, the air circulation unit 14 is further included.

The air circulation unit 14 allows the cooling air to be discharged to the outside and heat is not sucked from the outside as in another embodiment of the present invention on the air circulation device 1, so that circulation can be performed only inside the system. Therefore, the air circulation unit 14 passes through the cold air supply duct 121 so that the cold air supply duct 121 of the cold air supply unit 12 and the hot air recovery duct 131 of the hot air recovery unit 13 are connected to each other. The cool air can be circulated through the heat recovery duct 131 to the cooling device 3. Therefore, the air circulation unit 14 improves the cooling efficiency of the air conditioning system itself by allowing the remaining cool air supplied to each ESS housing 5 to be used to cool the heat sucked through the heat recovery unit 13 again. Can be done. To this end, the air circulation unit 14 is formed to be formed only in the air circulation device 1 located at the most end of the air circulation device 1 connected to one cooling device 3, as shown in FIG. , It is possible to have a structure that is supplied to each ESS housing (5) and the remaining cold air is recovered through the heat recovery unit 13 to the cooling device (3) again.

In the above, the applicant has described various embodiments of the present invention, but these embodiments are only one embodiment of implementing the technical idea of the present invention, and any modification or modification of the invention as long as the technical idea of the present invention is implemented It should be interpreted as being within the scope of.

1: Air circulation device
11: Enclosure 12: Cold air supply 121: Cold air supply duct
121a: cold air inlet 121b: cold air outlet 122: cold air supply pipe
123: cold air supply means 13: hot air recovery unit 131: hot air recovery duct
131a: hot air inlet 131b: hot air outlet 132: hot air intake pipe
133: hot air suction means 14: air circulation unit
3: Cooling system
31: housing 32: heat exchange means 33: outside air inlet pipe
331: fine dust filter 34: cold air circulation pipe 35: cold air blowing means
36: hot air inlet 37: hot air inlet
5: ESS housing
51: rack shelf 52: cold air intake 53: vertical cold flow path
531: cold air induction member 531a: guide plate 531b: flow forming plate
532: additional blowing means 54: horizontal cold flow path 541: air outlet
55: hot air outlet 551: dust filter
7: Control
71: temperature measurement module 711: first measurement module 712: second measurement module
72: air flow control module 73: additional air flow control module 74: heat exchange control module
75: Cooling system additional request module

Claims (10)

An ESS housing that provides a plurality of internal spaces to accommodate ESS devices in each space; An air circulation device coupled to one surface of the ESS housing to supply cold air in the ESS housing; Cooling device for cooling the air to supply to the air circulation device; includes,
The air circulation devices coupled to the plurality of ESS housings are coupled and connected detachably to receive cold air from one cooling device.
The number of air circulation devices receiving cold air from one cooling device is determined by summing the power capacity of the ESS device accommodated in the ESS housing combined with the air circulation device,
The air circulation device includes an enclosure formed to be coupled to a width corresponding to one surface of the ESS housing; A cold air supply unit formed in the enclosure, and supplied with cold air to one side to be supplied into the ESS housing, and the remaining cold air to be discharged to the other side; It includes a heat recovery unit that absorbs heat emitted from each ESS housing and recovers it with a cooling device.
The cold air supply unit includes a cold air supply duct forming a flow path through which cold air flows from one side to the other, and a cold air supply pipe forming a passage connected to the ESS housing at a point of the cold air supply duct, and cold air supply formed on the cold air supply pipe It includes a cold air supply means for supplying cold air from the duct into the ESS housing,
The hot air recovery unit is formed in the enclosure, and a hot air recovery duct that recovers hot air from the ESS housing and recovers it to the cooling device side; A hot air suction pipe branched at a point of the hot air recovery duct to form a path through which hot air is sucked from the ESS device; It is formed on the hot air suction pipe and includes a hot air suction means for sucking hot air,
The cold air supply duct and the hot air recovery duct of the adjacent air circulation devices are in communication with each other so that cold air and hot air can be circulated,
The air circulation unit further includes an air circulation unit that connects the cold air supply unit and the hot air recovery unit to be supplied to the ESS housing from the cold air supply unit and is combined with the heat absorbed by the hot air recovery unit to be recovered by the cooling unit.
The air circulation unit is a modular air conditioning, characterized in that it is formed in the air circulation device at the far end of the plurality of air circulation devices connected to the cooling device so that the cold air supply duct and the heat recovery duct are connected in the enclosure. system.
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