KR101153218B1 - Cooling Room System Using Module Type Heat Storing Unit - Google Patents

Abstract

An ice heat storage cooling system using a modular heat storage tank according to the present invention includes a housing including an opening formed so that an upper surface thereof is opened in an empty state, a cover covering the opening of the housing, and a partition wall formed to partition the inside of the housing. A housing assembly; A plurality of coils inserted into respective spaces partitioned by the partition walls in the housing, the refrigerants flowing therein, and a plurality of coils, each end of which is connected to one end of the coil and the other end of which is integrated A plurality of supply headers integrated through a pipe and connected to a discharge side of an optional refrigerator, and provided in plurality, each end of which is connected to the other end of the coil and the other end of which is integrated through a return integration pipe And a heat storage assembly including a plurality of return headers connected to the suction side of the refrigerator.
According to the ice heat storage cooling system using the modular heat storage tank according to the present invention, it is differentiated from the existing cylindrical heat storage tank and the shape and configuration to make more efficient use of the space in which the heat storage tank in the building is installed, and at the same time as described above By allowing the coil to be inserted into the housing, a plurality of conventional heat storage tanks may be installed in one housing, thereby increasing the efficiency of cooling.

Description

Cooling Room System Using Module Type Heat Storing Unit

The present invention relates to an ice heat storage cooling system using a modular heat storage tank, and more particularly, to form a partition of an interior of a rectangular-shaped housing into partitions, and a coil, a supply header, and a return header in each space partitioned by the partitions. By inserting the heat storage function individually, it is possible to improve the efficiency of inefficient space utilization by installing a plurality of heat storage tanks in the related art, and to increase the efficiency of ice heat storage by installing a plurality of coils in one housing. And an ice heat storage cooling system using a modular heat storage tank.

In general, ice heat storage cooling system is a state-of-the-art method of cooling buildings by freezing ice in the middle of the night and melting them in the middle of the day without using air-conditioning devices such as air conditioners during the day when electricity consumption is heavy. It is different from air conditioners such as air conditioners because they consume little electricity during the day when cooling. The downside is that the initial installation cost is about 30% more than air conditioning. However, due to the low electricity rate, the annual operating cost is only half, so the investment can be recovered in four years.

The above-mentioned ice heat storage cooling system essentially includes a heat storage tank, and the heat storage tank provides a space for storing ice generated at night.

The principle of the ice heat storage cooling system including the heat storage tank can be largely divided into a static ice making type and a dynamic ice making type.

Among these, in particular, the static contact ice-making type direct contact iced on coil is provided with copper or polyetherline coils in the heat storage tank and filled with water, and then circulates a low temperature brine or refrigerant inside the coils. The ice is frozen, and cooling is performed by circulating the cold water in the heat storage tank to the air conditioner during cooling. Such an external icing type has a merit that the heat transfer area is gradually increased as the icing proceeds to increase the ice making efficiency, and the amount of useful energy is large because the water outside the tube circulates to melt ice during thawing.

However, since the heat storage tank used for the direct contact type external icing type is generally composed of a cylindrical shape, in a general case in which a plurality of heat storage tanks are installed, voids are generated between adjacent heat storage tanks disposed adjacent to each other, thereby reducing space utilization. In addition to the decrease in efficiency, when the heat storage tank is stacked in a double layer, the installation work is cumbersome because other structures must be additionally installed due to the functional problem of the heat storage tank.

In order to solve the above problems, it can be seen that Korean Patent Registration No. 10-0692251 'heat storage structure' is disclosed.

The technique is a rod-shaped heat storage rod having irregularities on the side, and an insertion hole penetrates the inner center to insert the heat storage rod so that the entire heat storage tank does not flow regardless of the main flow of the antifreeze. Concave-convex is formed, including a heat accumulating donut, so that the shape of the heat accumulating donut and the heat storage rod is combined in a grouping frame to be grouped.

According to the above technique, the heat storage donut into which the heat storage rod is inserted may be contributed to the space utilization by a certain amount, but the shape and volume of the grouping frame are limited, and when the plurality of grouping frames are provided, There is a disadvantage that the ice storage heat may not be efficient because heat outside the predetermined level is introduced during the heat exchange process.

Therefore, there is a need to provide an ice heat storage cooling system using a new and advanced modular heat storage tank that solves the above problems and maximizes the efficiency of space utilization and facilitates heat exchange.

The present invention has been made in order to overcome the problems of the above technology, and includes a partition formed to partition the housing and the interior of the housing, the heat storage assembly including a coil is inserted into a plurality of spaces inside the housing partitioned by the partition wall The main purpose is to be able to utilize the space and power more efficiently, even if it is necessary to install a plurality of heat storage tank.

Another object of the present invention is to allow the partition wall to be detachably configured with the inner wall of the housing to enable more efficient space partitioning.

Still another object of the present invention is to allow the cover to be openably coupled to the opening of the housing and at the same time to include a through hole formed so that the supply integration pipe and the return integration pipe connected to the coil through one side of the cover. It is to facilitate the use and repair of the heat storage tank.

A further object of the present invention is to allow the supply header and the return header to be coupled to each other to extend, so that the coil provided in a form surrounding the outside of the supply header and the return header can be more stably stacked. .

A further object of the present invention is to maintain a stable state of the stacked coil including a support formed to extend from one side of the outer peripheral surface of the supply header and the return header to the bottom surface of the housing.

It is a further object of the present invention to form a plurality of check valves at a branch point between the supply integration pipe and the supply header, and to provide a controller for controlling the respective check valves individually, This allows the refrigerant to flow in and prevents more power loss than necessary.

In order to achieve the above object, an ice heat storage cooling system using a modular heat storage tank according to the present invention, a housing including an opening formed so that the upper surface is opened in an empty state, a cover covering the opening of the housing, and the interior of the housing A housing assembly including a partition wall defining partitions to form a plurality of spaces, a plurality of coils inserted into the respective spaces, the refrigerants flowing therein, and a plurality of coils, one end of each of the coils And a plurality of supply headers, each of which is integrated through a supply integrating pipe and connected to a discharge side of an arbitrary refrigerator, and a plurality of supply headers, each end of which is connected to the other end of the coil and each of the other ends is returned. A plurality of return headers are integrated through the integrated tube and connected to the suction side of the refrigerator. A heat storage assembly; characterized in that consisting of.

In addition, the inner wall of the housing is further provided with a plurality of guide slits formed in a predetermined depth extending in the height direction and spaced apart from each other, and protruding to correspond to the guide groove in the portion in contact with the housing in the partition wall The guide protrusion formed is further provided, and the guide protrusion is inserted into the guide slit in a sliding manner so that the partition wall can be detached from the inside of the housing.

In addition, the partition wall is provided with a plurality of widths different from each other, the guide slits are formed on each of the surfaces spaced apart from each other by a predetermined interval, so that the guide protrusions are formed on both ends of the width direction, Characterized in that each partition can be coupled to each other puzzle type.

In addition, the cover is coupled to the opening and the opening of the housing, characterized in that the one side of the cover is further provided with at least one or more through-hole formed to pass through the supply integration pipe and the return integration pipe.

Additionally, the supply header and the return header may further include a first coupling portion formed at each end thereof, and a second coupling portion configured to be assembled and coupled with the first coupling portion at each other end thereof. The supply header and the return header may be extended in the longitudinal direction as a connection between the first coupling part and the second coupling part so that the coils may be stacked and provided.

In addition, one end of each of the supply header and the return header is coupled to one end of the supply header and the outer circumferential surface of the return header, and the other end is a support that is fixed in contact with the bottom surface of the housing; Supporting each of the supply header and the return header to prevent the coil from contacting the inner wall of the housing or the partition wall.

Additionally, the supply integrating pipe may be configured to group the supply headers by branching the supply headers into a plurality of branches such that each branch end is connected to a predetermined number of supply headers of the respective supply headers. A plurality of check valves are further formed at each branch point branched into a plurality of controllers, and a controller configured to individually control the respective check valves by transmitting a signal via an arbitrary cable to the outside of the housing; It is further included, characterized in that the grouping of the supply header to control the group to selectively enter the refrigerant therein.

Ice heat storage cooling system using a modular heat storage tank according to the present invention,

1) It is easy to utilize the space in the area where the heat storage tank is arranged,

2) The bulkhead location can be adjusted freely, adding efficiency to the space utilization in the housing,

3) By providing a hole in the cover, the supply header and the return header can be reliably connected to the external device in the housing,

4) It is possible to control the refrigerant flowing through each coil individually to prevent power loss,

5) It is possible to assemble the coils more stably by allowing each supply header and each return header to be assembled to each other.

1 is a perspective view showing the basic configuration of an ice heat storage cooling system using a modular heat storage tank according to the present invention.
Figure 2 is an exploded perspective view showing a schematic configuration of the ice heat storage cooling system according to the present invention.
Figure 3 is a perspective view showing a partition wall and its detachable structure according to the present invention.
Figure 4 is a perspective view showing the configuration of the heat storage assembly according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The accompanying drawings are not drawn to scale and wherein like reference numerals in the various drawings refer to like elements.

The ice heat storage cooling system consists of a freezer that produces cold heat, a heat storage tank that stores cold heat, and an air conditioner that uses cold heat, and operates the freezer at night time to store cold heat in the heat storage tank, and stops the freezer during the day. Cooling heat is circulated in an air conditioner or a fan coil to be used for cooling. The ice heat storage cooling system using the modular heat storage tank according to the present invention is a heat storage tank used for the above-described ice heat storage cooling system. In a state in which a plurality of coils 210 circulated in a counter flow method are inserted and arranged, ice is formed on the outside of the coil 210 or ice formed by melting ice formed therein, such as a building. It can be used for cooling.

In particular, the ice heat storage cooling system using the modular heat storage tank according to the present invention is characterized by the basic feature to enable more efficient space utilization by changing the shape and structure of the heat storage tank provided in the conventional cylindrical.

1 is a perspective view showing the basic shape of the ice heat storage cooling system using a modular heat storage tank according to the present invention, Figure 2 is an exploded perspective view showing a schematic configuration of the ice heat storage cooling system according to the present invention.

As can be seen from Figures 1 to 2, the ice heat storage cooling system using a modular heat storage tank according to the present invention comprises a housing assembly including a housing 110, a cover 120 and a partition wall 130, a coil 210, It consists of a heat storage assembly that includes a supply header 220 and a return header 230.

As described above, the housing assembly includes a housing 110, a cover 120, and a partition wall 130, and the housing 110 includes a coil 210 formed to flow brine or water therein. As a basic frame of the heat storage tank that accommodates the heat storage function, the inside is formed to have an empty rectangular parallelepiped shape, and is formed to include an opening having an upper surface.

The material of the housing 110 is preferably made of a heat insulating material such as concrete or a high density polyethylene filled with a urethane foam therein to facilitate the process of freezing and thawing.

The opening provided on the upper surface of the housing 110 is provided with a cover 120 for opening and closing the opening, and the cover 120 is formed in a shape such as a plate having a size similar to that of the opening so that the opening is provided. It is configured to open and close the.

That is, one side of the cover 120 is opened or closed in such a manner as to be rotatably coupled to one surface of the opening of the housing 110 (using a hinge or a hinge), or as shown in FIG. The contact portion 121 vertically extended downward from the circumference of the cover 120 may be included in the 120, so that the contact portion 121 may wrap and compress the circumferential side portion of the opening. . The cover 120 is formed of the same material as the housing 110 to have a function of thermal insulation.

The partition 130 is provided to partition the inside of the housing 110, and has a shape such as a plate having a predetermined size, and uses a plurality of partitions 130 to form a plurality of spaces inside the housing 110. It can be divided into (110a), but it will be more preferable to insert a plurality of partitions 130 in the interior of the housing 110 after combining the plurality of partitions 130 according to the size and shape of the space (110a) to be divided (Fig. 3).

The partition wall 130 is inserted in the longitudinal direction inside the housing 110 to allow the internal space 110a of the housing 110 to be divided into a plurality of spaces 110a, such a partition wall 130 By allowing the coil 210 to be individually inserted into each of the plurality of spaces 110a partitioned into the plurality of spaces, a plurality of heat storage tanks, which are conventionally configured and used, function as a plurality of the storage tanks.

Therefore, the material of the partition 130 is preferably provided with a heat insulating material, such as the material of the housing 110, so that each of the partitioned space (110a) is insulated from each other to serve as a heat storage tank individually.

The partition wall 130 may be provided to be fixed inside the housing 110, but may be configured to be detachable for the usefulness of the more flexible housing 110. The guide slit 111 and the guide protrusion 131 may be further configured to the 110 and the partition wall 130, respectively.

3 is a perspective view showing a partition wall 130 and its detachable structure according to the present invention.

As shown in FIG. 3, the guide slit 111 is provided at one side of the inner wall of the housing 110 and is provided with a guide protrusion 131 provided at a portion of the partition wall 130 that is in contact with the housing 110. It can be coupled in a sliding manner.

Referring to the detailed shape of the guide slit 111, it is embedded in a predetermined depth from one side of the inner side wall of the housing 110 to extend in the height direction, that is, at various inner specific portions of the opening of the housing 110 It is embedded and extends in the longitudinal direction.

The guide slit 111 may be formed to be recessed in a shape similar to 'ㅁ', but in a shape such as a 'T' shape or a 'ㄹ' shape so as to be more stably coupled with the guide protrusion 131. It would be more desirable to achieve this to improve the bonding force.

The guide slit 111 is formed spaced apart at regular intervals along the inner circumference of the opening to vertically extend in the longitudinal direction to adjust the insertion position of the partition wall 130 is partitioned by the partition wall 130 It is desirable to be able to flexibly change the number and size of the 110a.

The guide protrusion 131 is formed in a size and a shape corresponding to the guide slit 111 at both ends of the vertical side of the partition 130 to be coupled to the guide slit 111 in a sliding movement manner. .

In this case, the partition wall 130 is cut so as to correspond to the size and shape of the guide slit 111 when the insert is inserted into the housing 110 in a state formed to have a predetermined level of thickness to the housing 110. It is preferable to form it.

In addition, in order to partition the internal space of the housing 110, a plurality of partition walls 130 are formed by forming coupling slits 132 on both surfaces of the partition walls 130 provided with a plurality of states having different widths from each other. The coupling slit 132 formed on the partition wall 130 may also be coupled to a predetermined depth such as the guide slit 111 formed on the inner wall of the housing 110. It is formed extending in the direction (vertical direction) to be formed spaced apart from each other by a predetermined interval.

An embodiment of the guide slit 111, the guide protrusion 131, and the coupling slit 132 will be described. In the state where the housing 110 is disposed, the guide protrusion 131 provided in the partition wall 130 is provided. Is positioned to correspond to the opening side introduction end of any one of the guide slit 111 of the plurality of guide slits 111 provided in the housing 110, and then sliding the partition 130 in a sliding manner by pushing downward By doing so, the inner space 110a of the housing 110 can be partitioned.

At this time, as described above, the barrier ribs 130 may be coupled to each other to have a specific shape before being inserted into the housing 110, and the coupling slit formed on the barrier rib 130 having a long width. The guide protrusion 131 provided at one end in the width direction of the barrier rib 130 having a relatively short width to one of the 111 in a sliding manner is combined so that the plane has a shape similar to the 'T'. Thereafter, the plurality of partitions 130 may be coupled to each other at random by a user in the same manner, thereby forming a space 110a having more various sizes and shapes.

In addition, the above-described method may be applied to divide the inner space 110a of the housing 110 into a plurality of layers. For example, by partitioning the partition 130 into a plurality of layers to be inserted into the inside of the housing 110, the space 110a of the housing 110 may be partitioned in various ways and more coils may be provided in each space 110a. Insert 210 to further increase the utility of the heat storage tank. In this case, it is assumed that the transverse plate dividing the layers in the partition wall 130 is provided with a through hole formed so that each header provided in the upper layer and each header provided in the lower layer can be connected to each other.

The housing assembly consisting of the housing 110, the cover 120, and the partition wall 130 is differentiated from the shape and configuration of an existing cylindrical heat storage tank, and at the same time makes it possible to more efficiently use the space in which the heat storage tank in the building is installed. By allowing the coils 210 to be inserted into the spaces 110a partitioned by the partition walls 130 described above, a plurality of conventional heat storage tanks are installed in one housing 110, so that the efficiency of cooling can be improved. It has the advantage of increasing.

4 is a perspective view showing a detailed configuration of the heat storage assembly according to the present invention.

Referring to FIG. 4, the heat storage assembly includes a coil 210, a supply header 220, and a return header 230, a supply integration tube 240, and a return integration tube 250. 210 is a hollow tube and is formed such that a refrigerant such as brine flows therein, and is inserted into a plurality of spaces 110a partitioned by the partition wall 130 in the housing 110. It is provided to be wound in a vortex form so as to adjust the temperature of the refrigerant flowing inside the coil 210 to allow the water or the like to freeze or thaw outside the coil 210. .

In order to circulate the refrigerant flowing inside the coil 210, the heat storage assembly includes a supply header 220 connected to the discharge side of an optional refrigerator (not shown), and a return header 230 connected to the suction side. It is provided, one end of the coil 210 is connected to the supply header 220, the other end is connected to the return header 230. That is, the refrigerant flows through the supply header 220 from the refrigerator provided outside the housing 110 and flows along the inside of the coil 210 and then flows back to the refrigerator through the return header 230. As a result, the refrigerant inside the coil 210 is circulated.

In particular, the supply header 220 and the return header 230 is provided in the longitudinal direction along the side of the center portion of the coil 210 is formed by curling as shown in Figure 1 as if the shaft of the coil 210 By such a function, the coil 210 can be more stably arranged.

In this case, as shown in FIG. 4, the supply header 220 and the return header 230 are assembled and connected in the longitudinal direction (longitudinal direction), respectively, to extend their height. The coil 210 provided in a form surrounding the outside of the 230 may be maintained in a more stable stacked state, which is the coil 210 is being standardized to a specific size and released to the coil 210. There was a cost and space constraints on the use, so that the supply header 220 and the return header 230 can be assembled and assembled, respectively, so that the height of the coil 210 can be arbitrarily extended as desired. This is because it is very useful in terms of installation cost and efficiency of the housing 210 as compared with installing a plurality of heat storage tanks for the coil 210 that is standardized and released.

In order to accomplish the above object, the first and second coupling parts 221 and 222 may be provided at both ends of the supply header 220 and the return header 230, respectively, and the first coupling part 221 may be provided. And the second coupling portion 222 may be made in a threaded manner as shown in the figure, but a number of known in the range that can serve the purpose of allowing the refrigerant to penetrate the inside, such as sliding, ticking method It can be connected to male and female by means of connecting means.

By providing the first and second coupling parts 221 and 222, two or more coils 210 may be more stably stacked in each space 110a in which the inside of the housing 110 is partitioned. Since the height of the coil 210 can be adjusted based on a standardized unit, the size of the housing 110 can be flexibly manufactured, and accordingly, the efficiency of an ice storage cooling system using a modular heat storage tank according to the present invention can be adjusted. have.

Additionally, when the lengths of the supply header 220, the return header 230, and the coil 210 are extended as a combination of the first and second coupling parts 221 and 222, the bottom surface of the housing 110 is stable. As the coil 210 is not fixed, the coil 210 may be bent and may come into contact with the sidewall of the housing 110 to significantly reduce ice storage efficiency.

In order to solve this problem, the support header 220 and the return header 230 may be further provided with a support that serves to support each, the support is made of a material having a certain strength once the It is connected to one side of the outer circumferential surface of the supply header 220 and the return header 230, and the other end is configured to contact the bottom surface of the housing, and serves to support the supply header and the return header not to be inclined easily .

Each of the headers 220 and 230 is in contact with the support is preferably a portion having a certain level in order to ensure the support force.

Since the support is provided, the coil 210 supported by the supply header 220 and the return header 230 may be more stably erected inside the space 110a to solve the problem of deterioration of ice storage heat efficiency. It is.

The supply integration pipe 240 and the return integration pipe 250 are pipes integrating the supply header 220 and the return header 230 respectively connected to the plurality of coils 210, respectively, and the supply header 220. Is connected to the discharge side of the refrigerator via the supply integration pipe 240, and the return header 230 is connected to the suction side of the refrigerator via the return integration pipe 250.

The supply integration pipe 240 and the return integration pipe 250 may be formed as a single pipe by integrating all of the supply header 220 and the return header 230, each of which consists of a plurality, but one end is divided into a plurality Each branch stage may be configured to integrate only a certain number of headers of the supply header 220 and the return header 230. For example, when the coil 210 is inserted into each space 110a by dividing the internal space of the housing 110 into six spaces 110a by the partition wall 130, the supply integration pipe 240 ) Is provided with three branch stages so as to integrate two supply headers 220 of the six supply headers 220 connected to the respective coils 210, or three of the six supply headers 220. It is provided with two branch stages integrating the supply header 220, the one end is controlled by the check valve 310 and the controller 300 to be described later, the supply integration pipe 240 branched into the three or two By doing so, each group can be operated individually.

Referring to the operation of the heat storage tank including the heat storage assembly briefly, the coolant cooled to a low temperature due to the operation of a refrigerator (not shown) provided on the outside of the housing 110 to cool the coolant is the supply integrated pipe 240 By passing through the branch to each supply header 220 is introduced into the coil 210 provided in each of the plurality of spaces (110a) partitioned inside the housing 110, the introduced refrigerant flows along the coil 210 While absorbing heat from the surrounding water to freeze the water in the outer space of the coil (210). Subsequently, the return header 230 is integrated into the return integration pipe 250 to operate the external ice-cold storage device while undergoing a process of recycling the refrigerant to the cooler.

Since the coil 210, the supply header 220, and the return header 230 are well-known techniques mainly used in the conventional ice storage cooling system, a detailed description thereof will be omitted.

Referring to FIGS. 1 and 2 again, the configuration and operation of the cover 120 will be described in detail. The cover 120 serves to detachably cover the opening of the housing 110 as described above. It has a plate shape to seal the housing 110, in this case, the supply integration pipe 240 and the return integration pipe 250 for integrating the supply header 220 and the return header 230, respectively, the housing There is a problem that it is difficult to pass to the outside of (110).

Therefore, the cover 120 has a plurality of throughholes 122, preferably two or more, having a size enough to penetrate the supply integration pipe 240 and the return integration pipe 250, so that the supply integration pipe The 240 and the return integration pipe 250 may be stably connected to the freezer provided outside the housing 110 in the housing 110.

The diameter of the through hole 122 is formed to be slightly larger than the diameter of each of the supply integration pipe 240 and the return integration pipe 250 so that each of the integration pipe can penetrate the through hole 122 without damage. Since the inside of the housing 110 must be kept airtight so as to be insulated from the outside of the housing 110, the supply integration pipe 240 and the return integration pipe 250 respectively open the through hole 122. After penetrating, it is most preferable to finish the peripheral portion of the through hole 122 with a material having heat resistance and elasticity.

As shown in FIG. 1, the through hole 122 may be formed as two through holes having a larger size to allow both of the plurality of supply integration pipes 240 and the return integration pipe 250 to pass therethrough. As shown in FIG. 2, one through-hole 122 may be provided per supply integration pipe 240 and the return integration pipe 250, and may be provided in two multiples of the number of coils.

The ice storage heat storage system using the modular heat storage tank configured as described above arbitrarily partitions the inside of the housing 110 of a heat insulating material formed in a rectangular parallelepiped shape by using the partition wall 130, and the heat storage in each of the partitioned spaces 110a. By disposing the assembly, the space can be used more efficiently and at the same time, it can be formed in a modular form so that the ice storage can be made more easily by integrating a conventional heat storage tank.

As described above, the ice heat storage cooling system using the modular heat storage tank according to the present invention is provided when a plurality of heat storage assemblies are included in one housing 110 so that a large amount of cooling heat is required, such as midsummer. However, even when only a small amount of cooling heat is required, such as early summer or early autumn, all of the plurality of heat storage assemblies provided in the housing 110 are operated to bring power loss by using more power than necessary.

In order to solve the above problems, the ice heat storage cooling system using a modular heat storage tank according to the present invention may further include a group control assembly.

5 is a cross-sectional view showing the configuration of a group control assembly according to the present invention.

As can be seen from Figure 5, the group control assembly is composed of a check valve 310, a cable 320 and a controller 300, the check valve 310, the supply integrated pipe 240 and the It is formed at the point where the supply header 220 is branched, that is, the point where a plurality of the supply header 220 is integrated into the supply integrating pipe 240, opening and closing the branch point to each supply header 220, the refrigerator In the role of individually controlling the refrigerant flowing through the supply integration pipe 240 is introduced into each of the supply header 220.

In this case, as described above, each supply header 220 may be individually controlled, but the side connected to the supply header 220 in the supply integration pipe 240 in order to allow the user to more easily adjust the amount of power. It is more preferable to group the feed headers 220 so that each branch end is connected to two, four, or nine feed headers 220 of the plurality of supply headers so as to branch the stages to control each group. .

The controller 300 is provided outside the housing 110, and preferably inside the refrigerator to control the respective check valves 310, and the check valve 310 and the cable 320. It is connected via) to deliver the signal.

In other words, the controller 300 individually controls each of the check valves 310 so that when a large amount of cooling heat is not required, only the supply header 220 of some of the plurality of supply headers 220 is refrigerant. To prevent the loss of more power than necessary.

Since the electrical configuration of the controller 300 is a known technique, a detailed description thereof will be omitted.

As described so far, the configuration and operation of the ice heat storage cooling system using the modular heat storage tank according to the present invention have been expressed in the above description and the drawings, which are merely examples, and the spirit of the present invention is not limited to the above description and the drawings. And, of course, various changes and modifications are possible within the scope without departing from the spirit of the present invention.

110: housing 110a: space
111: guide slit 120: cover
121: close contact 122: through hole
130: partition 131: guide projection
210: coil 220: supply header
221: first coupling portion 222: second coupling portion
230: return header 240: supply integration pipe
250: return integration pipe 260: support
300: controller 310: check valve
320: cable

Claims (7)

An ice heat storage cooling system using a modular heat storage tank,
A housing including an opening formed to open the upper surface in an empty state;
A cover covering the opening of the housing;
A housing assembly including a partition wall defining an interior of the housing to form a plurality of spaces;
A plurality of coils inserted into the respective spaces and formed to allow a refrigerant to flow therein;
A plurality of supply headers provided in plurality, each end of which is connected to one end of the coil, and the other end of which is integrated through a supply integration pipe and connected to the discharge side of any refrigerator;
It is provided with a plurality of each end is connected to the other end of the coil and each other end is integrated with a return integration pipe through the heat storage assembly including a plurality of return headers connected to the suction side of the refrigerator;
The supply header and the return header,
A first coupling portion is further formed at each end, and a second coupling portion formed to be assembled with the first coupling portion is further provided at each other end.
The coil is provided in a stack such that the supply header and the return header extend in the longitudinal direction as a connection between the first coupling portion and the second coupling portion,
On one side of each of the supply header and the return header,
A supporter having one end coupled to one side of the outer circumferential surface of the supply header and the return header and the other end fixed to be in contact with the bottom surface of the housing;
And holding each of the supply header and the return header so that the coil does not come into contact with the inner wall or the partition wall of the housing. The method of claim 1,
On the inner wall of the housing,
It is further provided with a plurality of guide slits formed in a predetermined depth and extending in the height direction, spaced apart from each other by a predetermined interval,
In a portion of the partition that is in contact with the housing,
Further provided with a guide protrusion protruding to correspond to the guide slit,
The guide protrusion is inserted into the guide slit in a sliding manner to allow the partition wall to be detachable in the interior of the housing, ice heat storage cooling system using a modular heat storage tank. The method of claim 1,
The cover is coupled to the opening of the housing so as to be openable,
On one side of the cover,
Ice storage heat storage cooling system using a modular heat storage tank, characterized in that further provided with at least one through-hole formed to pass through the supply integration pipe and the return integration pipe. The method of claim 1,
The supply integration pipe,
The feed header is grouped into a plurality of stages connected to the supply header such that each branch stage is connected to a predetermined number of supply headers of the respective supply headers,
At each branch point where the supply integration pipe branches into a plurality,
A plurality of check valves are additionally formed,
On the outside of the housing,
The controller further includes a controller for individually controlling each of the check valve by transmitting a signal via any cable,
Ice heat storage cooling system using a modular heat storage tank, characterized in that for grouping the supply header to selectively control the refrigerant flow into the inside. delete delete delete

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