JP3260894B2 - Cold water production system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a chilled water production system and, more particularly, to a winter chilled water production system using a cooling tower.

[0002]

2. Description of the Related Art In recent years, the environment where indoor cooling is required even in winter, such as a computer installation room, is increasing. Methods of performing indoor cooling in the winter, such as a method of using a refrigerator to obtain cold water and forming a cool air with an air conditioner or a fan coil unit as in the summer, or a method of directly introducing outside air into the room and blowing air Is conventionally known.

However, the method of cooling by the same method as in summer has a problem in running cost, and in the case of outside air cooling, there is a problem in installation of an outside air introduction air passage and switching of an air conditioner. The solution was sought.

[0004] In view of such technical problems, the applicant of the present application has previously disclosed in Japanese Patent Publication No. 57-43823, a chilled water pipe and a chilled water pipe connected by switching valves, and in winter, chilled water is circulated through a cooling tower, and the outside air is used. A method for producing cold water is proposed.

[0005] However, in the above-mentioned apparatus, since the cold water flows through the cooling tower, there is a possibility that the cold water may contaminate the air-conditioner coil and the like. As described above, in consideration of the problem of cold water contamination, it is difficult to employ an open-type cooling tower in the above-described apparatus, and in fact, it can be applied only to a closed-type cooling tower. Further, for the same reason, it is difficult to adopt the above-described apparatus even when the cold water pipe is an open type. Further, in the above apparatus, a long chilled water circulation system that connects the cooling tower and the air conditioner in winter must be formed only by the chilled water pump, and thus the head of the chilled water pump tends to be large, which is a problem. Was.

[0006]

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above-mentioned problems of the conventional chilled water production system, and has as its object to use the outside air as a chilled heat source to reduce the power source. Significant savings are possible, even in the winter season, it is possible to carry out indoor cooling using existing equipment, and furthermore, without increasing the head of the chilled water pump, open cooling towers and open chilled water An object of the present invention is to provide a new and improved cold water production system that can be applied to piping without any problem.

[0007]

According to the present invention, in order to solve the above-mentioned problems, according to the present invention, feed cooling water from a cooling tower is selectively supplied to either a heat exchanger or a refrigerator by switching valve means. A cooling water circulation system configured to be able to send and return return water from the heat exchanger or the refrigerator to the cooling tower by switching valve means; and Alternatively, it is possible to send cold water from one of the refrigerators to the load by switching the valve means, and return the cold water returned from the load by switching the valve means to either the heat exchanger or the refrigerator. on the other hand, the load side chilled water circulation system which is configured to be able to return, in a cold water-producing system consisting of, the cooling water circulation system
May bypass the cooling tower and short-circuit the
Possible valve means are provided, the valve means flowing through the system.
Is a temperature control valve that opens and closes according to the temperature of the cooling water.
In the load side chilled water circulation system, the heat exchanger or the chiller
The chiller and the load are connected in a closed system, and in summer, the valve means is switched so that cooling water from the cooling tower is sent to the refrigerator and cooling water returned from the refrigerator is returned to the cooling tower. The valve means is switched so that the chilled water from the refrigerator is sent to the load and the returned chilled water from the load is returned to the refrigerator. In winter, the cooling water from the cooling tower is sent to the heat exchanger and the heat exchange is performed. The valve means is switched to return the return cooling water from the heat exchanger to the cooling tower, and the valve means is switched to send the chilled water from the heat exchanger to the load and return the chilled water from the load to the heat exchanger. A cold water production system is provided.

Further, according to the present invention, the cooling water is supplied to the outside.
Cooled to 5 ° C. to 10 ° C. by air
The water is heat-exchanged with the cold water in the heat exchanger.
C. cold water is produced. Also, the above cold
The cooling tower cooling water temperature is controlled by turning on the cooling tower fan.
Or by controlling the number of revolutions
And features. Furthermore, the temperature control valve is
A detour bypassing the cooling tower, and returning the cooling water to the cooling tower
The return line has a temperature control valve
Between the junction of the detour and the return line and the cooling tower
It is characterized by being provided.

[0009]

As described above, according to the present invention, the cooling water cooled by the outside air using the cooling tower installed outdoors is
It is possible to form a cooling water circulation system that selectively supplies and recovers heat from the heat exchanger or the refrigerator, and selectively sends the cold water supplied from the heat exchanger or the refrigerator to the load side and from there. It is possible to form a cold water circulation system for recovery. Therefore, in summer, it is possible to switch the valve means so as to form a cooling water circulation system that connects the cooling tower with the refrigerator and a cooling water circulation system that connects the refrigerator with the load. On the other hand, in winter, it is possible to switch the valve means so as to form a cooling water circulation system that connects the cooling tower and the heat exchanger, and a cooling water circulation system that connects the heat exchanger and the load. .

As a result, according to the present invention, it is possible to avoid cold water contamination, so that the present invention can be applied to an open-type cooling tower, and also in winter, the cold water circulation system and the cooling water circulation can be used. Since the system employs two circulation systems, the head of the circulation drive pump can be reduced.

Further, by providing a route bypassing the cooling tower by the temperature control valve and opening and closing the temperature control valve according to a change in the temperature of the cooling water, the temperature of the cooling water can be easily controlled. is there.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a chilled water production system configured according to the present invention will be described in detail with reference to the accompanying drawings. As shown in FIG. 1, the chilled water production system according to the present invention includes a cooling water circulation path A that connects the cooling tower 1 and the heat exchanger 8 or the refrigerator 5, a load 15 such as an air conditioner, and the heat exchanger 8 or The cooling water circulation path B communicates with the refrigerator 5.

As shown, the cooling water circulation path A is a path for circulating cooling water between the cooling tower 1 installed on the roof of a building and the heat exchanger or the refrigerator. Cooling tower 1
However, as described below, according to the present invention, it is possible to freely select and employ not only a closed cooling tower but also an open cooling tower.

In the cooling tower 1, for example, 5 ° C.
The cooling water cooled to 10 ° C. can be sent to the condenser of the refrigerator 5 via the cooling water pump 3 and the first valve means 4 by the supply line 2. Further, a branch path 6 is provided downstream of the cooling water pump 3, and the branch path 6 communicates with the heat exchanger 8 through the second valve means 7, and the cooling water is transferred to the heat exchanger 8. 8 can also be sent. In addition, as the heat exchanger 8, it is possible to employ a plate-type heat exchanger having excellent heat exchange efficiency.

Similarly, the return line 9 of the cooling water from the refrigerator 5 communicates with the cooling tower 1 via the third valve means 10 so that the cooling water from which the cooling heat has been removed in the refrigerator 5 is removed. It is possible to return to the cooling tower 1. The return line 9 communicates with the branch passage 25 on the way, and the branch passage 25 is connected to the fourth branch.
The heat exchanger 8 is connected to the heat exchanger 8 through the valve means 11 so that the cooling water from which heat has been deprived in the heat exchanger 8 can be returned to the cooling tower 1.

In addition, a short circuit path ( upstream in the present application) is provided upstream of the cooling water pump 3, that is, between the cooling water pump 3 and the cooling tower 1.
In the specification, this is also referred to as a “detour” . The short circuit 12 is provided with a return pipe downstream of the refrigerator 5 and the heat exchanger 8 via the first temperature control valve 13. It is in contact with Road 9. Further, the return pipe 9 is provided with a second temperature control valve 14 between the junction of the short circuit 12 and the return pipe 9 and the cooling tower 1.

As described above, the cooling water circulation path of the cooling water production system according to the present invention is configured. Next, the heat exchanger 8 or the refrigerator 5 is connected to the load 15 such as an air conditioner,
A chilled water circulation route B that can circulate chilled water in the meantime
Will be described.

As shown, in the chilled water circulation path B, chilled water supplied from the heat exchanger 8 can be sent to the load 15 through the supply pipe 17 via the fifth valve means 16. Similarly, the supply line 17 is provided with a branch line 19,
It is configured such that cold water from the refrigerator 5 can be supplied to the supply pipe line 17 through the branch line 19 via the sixth valve means 18.

The chilled water returned from the load 15 can be returned to the heat exchanger 8 by a return line 22 via a chilled water pump 20 and a seventh valve means 21. Further, the return pipe 22 is provided with a branch passage 23, and the cold water can be returned to the refrigerator 5 via the eighth valve means 24 through the branch passage 23.

The chilled water production system according to the present invention is configured as described above, and by appropriately switching the first to eighth valve means, an optimal energy-saving operation can be performed using existing equipment.

In the summer season, the second valve means 7, the fourth valve means 11, the fifth valve means 16 and the seventh valve means 21
Of the cooling tower 1 and the load 15 by closing the first valve means 4 , the third valve means 10, the sixth valve means 18 and the eighth valve means 24, respectively.
It is possible to form two circulating systems that communicate with the refrigerator 5.

By switching the valve in this manner, the cooling water cooled in the cooling tower 1 is sent to the refrigerator 5 by the cooling water pump 3 through the supply pipe 2 and the cold water cooled in the refrigerator is branched into the branch path. By sending to the load side via 19 and the supply line 17, a forward path of cold heat transfer is formed.

Similarly, the chilled water returned from the load side is sent to the refrigerator 5 by the chilled water pump 20 through the return line 22 and the branch line 23, and the cooling water heated in the refrigerator is returned to the return line 9. Is sent to the cooling tower 1 through which the heat is radiated, thereby forming a return path for cold heat transfer.

As described above, in the summer, according to the chilled water production system according to the present invention, it is possible to use the refrigerator 5 to perform the indoor cooling by the cold heat thereof, similarly to the ordinary cooling equipment. It is.

In winter, contrary to summer, the second valve means 7, the fourth valve means 11, the fifth valve means 16 and the seventh valve means 21 are opened, and the first valve means is opened. Means 4 , the third valve means 10, the sixth valve means 18 and the eighth
Of the cooling tower 1 by closing the respective valve means 24 of the cooling tower 1
It is possible to form two circulation systems that connect the load 15 and the heat exchanger 8 instead of the refrigerator 5 as in summer.

By switching the valve in this manner, the cooling water cooled in the cooling tower 1 is sent to the heat exchanger 8 by the cooling water pump 3 via the supply pipe line 2 and the branch path 6, unlike in summer, By sending the cold water that has been heat-exchanged and cooled in the heat exchanger 8 to the load side via the supply pipe 17, a forward path of cold heat transfer is formed.

Similarly, the chilled water returned from the load side is sent to the heat exchanger 8 by the chilled water pump 20 via the return pipe 22, and the chilled water to which the heat has been transferred in the heat exchanger 8 is supplied to the branch passage 25. And, it is sent to the cooling tower 1 via the return pipe 9 and radiates heat there, thereby forming a return path of cold heat transfer.

As described above, according to the present invention, even in the winter season, the cooling water is cooled to, for example, 5 ° C. to 10 ° C. by the outside air using the cooling tower 1 installed outdoors, and the heat It is possible to produce cold water of, for example, 7 ° C to 12 ° C by exchanging heat with cold water in an exchanger. At that time, in the present invention, since the cold water is produced by using the outside air temperature as the cold heat source, it is possible to greatly save the power source.

Further, since cold water can be produced in winter only by replacing a refrigerator used in summer with, for example, a plate-type heat exchanger, existing equipment can be used as it is. It is possible to save energy.

Further, according to the present invention, even in winter operation, the cold water circulation system and the cooling water circulation system are separated from each other, so that the contamination of the cold water does not become a problem, and therefore, even if the cooling tower is a closed cooling tower. An open cooling tower can be freely selected and adopted. Also, during winter driving,
Since only the chilled water circulation system needs to be circulated by the chilled water pump, it is possible to prevent the head of the chilled water pump from becoming too large.

In the normal operation of the chilled water production system according to the present invention, the first temperature control valve 13 is closed and the second temperature control valve 14 is opened to circulate the chilled water. Is too low, the first temperature control valve 13 is opened and the second temperature control valve 14 is closed, whereby the cooling tower 1 can be operated in a bypass operation. It is possible to optimally control the temperature of the cooling water. Note that the temperature control of the cooling water can also be performed by controlling on / off of the fan of the cooling tower 1 or controlling the number of rotations. When performing such temperature control, according to the present invention, it is possible to use an automatic control system when using a summer refrigerator, and it is possible to optimally control the temperature even in winter by changing the set temperature. It is.

[0032]

As described above, according to the present invention, the chiller used in the summer can be replaced with a plate heat exchanger even in the winter, without causing the problem of cold water contamination and the head of the chilled water pump. Optimum indoor cooling can be performed with energy saving.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a cold water production system according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Cooling tower 3 Cooling water pump 4 1st valve means 5 Refrigerator 7 2nd valve means 8 Heat exchanger 10 3rd valve means 11 4th valve means 12 Detour 13 First temperature control valve 14th 2 temperature control valve 16 5th valve means 18 6th valve means 21 7th valve means 24 8th valve means

──────────────────────────────────────────────────続 き Continuation of front page (56) References JP-A-62-196534 (JP, A) JP-A-61-128042 (JP, A) JP-A-2-197780 (JP, A) JP-A-56-196 40033 (JP, A) JP-A-63-297967 (JP, A) JP-A-61-128043 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) F24F 5/00 F25B 1 / 00 F25D 11/00 F25D 16/00

Claims (4)

(57) [Claims] 1. The cooling water sent from a cooling tower can be selectively sent to one of a heat exchanger and a refrigerator by switching valve means, and the heat exchanger or the cooling apparatus can be selectively switched by switching valve means. A cooling water circulating system configured to be able to return the return cooling water from the refrigerator to the cooling tower, and sending cold water from either the heat exchanger or the refrigerator by switching valve means. A load-side chilled water circulation system configured to be able to be sent to the load, and configured to be able to return the returned chilled water from the load to one of the heat exchanger or the refrigerator by switching the valve means. In the chilled water production system constituted by :
It is possible to short-circuit the outgoing path and the return path by bypassing the cooling tower
Valve means are provided, the valve means providing cooling through the system
A temperature control valve that opens and closes according to the temperature of water.
In the side chilled water circulation system, with the heat exchanger or the refrigerator
The load is connected in a closed system, and in summer, the valve means is switched so that cooling water from the cooling tower is sent to the refrigerator and return cooling water from the refrigerator is returned to the cooling tower,
The valve means is switched so that the chilled water from the refrigerator is sent to the load and return chilled water from the load is returned to the refrigerator.
In winter, the valve means is switched so that the cooling water from the cooling tower is sent to the heat exchanger and the return cooling water from the heat exchanger is returned to the cooling tower, and the cold water from the heat exchanger is sent to the load. A chilled water production system, wherein a valve means is switched so that chilled water returned from a load is returned to the heat exchanger. 2. The cooling water is heated to 5 ° C. to 10 ° C. by outside air.
The cooled cooling water is cooled by the heat exchanger.
Heat exchange with cold water produces 7 ° C to 12 ° C cold water.
The chilled water production system according to claim 1, wherein: 3. The temperature control of the cooling tower cooling water is performed by the cooling tower cooling water.
Control the on / off or rotation speed of the tower tower
2. The method according to claim 1, wherein
3. The cold water production system according to 2. 4. The temperature control valve bypasses the cooling tower.
And a return line for returning the cooling water to the cooling tower.
The return line temperature control valve is
Provided between the junction of the return line and the cooling tower
The method according to claim 1, 2 or 3, wherein
Cold water production system.