KR200396520Y1 - Cooling Unit With Pin Coil-Typed Evaporator - Google Patents

Abstract

The present invention relates to a cold water supply apparatus, and more particularly, in a cold water supply apparatus, a cold water storage tank for storing and supplying cold water, a water level control unit for maintaining a water level of the cold water storage tank, and the cold water storage tank Located below the predetermined water level in the interior, it constitutes a plate fin type evaporator connected to the refrigerant pipe and by supplying the high temperature water recovered to the storage tank to the surface of the evaporator to supply the cold water cooled according to the heat exchange water. It relates to a cooling unit (cold water supply device).

Through this design, the heat exchange efficiency is significantly increased compared to the conventional pipe type cold water supply device, and the damage of the compressor is reduced by stabilizing the refrigeration cycle even when load changes, and the storage tank and the evaporator are integrated. In combination, no additional field piping between the storage tank and the cold water supply is required, which simplifies site installation.

Description

Cooling Unit With Pin Coil-Typed Evaporator

The present invention relates to a cold water supply device, and more particularly, significantly increases heat exchange efficiency compared to a conventional cold water supply device in the form of a pipe and stabilizes the refrigeration cycle even under load fluctuations, thereby reducing damage due to compressor burnout. The present invention relates to a cold water supply device that can simplify the installation of a site by additionally combining the storage tank and the evaporator without the need for additional field piping between the storage tank and the cold water supply device.

In general, a cold water supply device, which supplies cold water to a cooling device for medical equipment (MRI, CT) and an equipment that requires cooling water in industrial laser, food, pharmaceutical, and chemical plant production processes, includes a pump, Compressor, condenser and evaporator are built in. The configuration of a general cold water supply device is to form cold water supplied to a device requiring cooling by using an evaporator in the form of a spiral tube as shown in FIG. Is adopted by supplying it to the customer or supplying it through a storage tank.

The heat exchanger manufactured by bending multiple layers in the form of a spiral tube as in the related art has a problem in that the size of the evaporator is larger than the heat transfer area and the heat exchange efficiency is lowered.

In order to solve the problems of the prior art as described above, it is an object of the present invention to provide a cold water supply device that can reduce the damage caused by compressor burnout by stabilizing the refrigeration cycle even under load fluctuations, reducing the size of the evaporator It is an additional purpose to improve heat exchange efficiency.

In addition, another object of the present invention is to provide a cold water supply device that can be easily installed on the site by simply combining the storage tank and the evaporator, the equipment can be configured simply.

In order to achieve the object as described above, the present invention

In cold water supply apparatus,

A cold water storage tank for storing cold water and supplying the cold water;

A water level control unit for maintaining the water level of the cold water storage tank at a predetermined level;

A plate fin type evaporator located below the predetermined water level in the cold water storage tank and connected to a refrigerant pipe;

A cold water pipe having one end connected to a cold water recovery port, the other end connected to the cold water storage tank, and one end connected to the cold water storage tank, and the other end connected to a cold water supply port. It provides a cold water supply characterized in that.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a cold water supply apparatus, in the cold water supply apparatus, a cold water storage tank (10) for storing and supplying cold water, a water level control unit (31) for maintaining a water level of the cold water storage tank (10), Located below the predetermined water level in the cold water storage tank 10, the plate fin type evaporator 24 connected to the refrigerant pipe, one end is connected to the cold water (hot) recovery port 12 and the other end is the cold water storage Cold water recovery pipe 13 is connected to the tank 10 and one end is connected to the cold water storage tank 10 and the other end comprises a cold water pipe having a cold water supply pipe 34 is connected to the cold water supply port. .

A preferred embodiment thereof is as shown in FIG. That is, unlike a common cold water supply device, the refrigerant pipe and the evaporator are disposed in a cold water storage tank 10 for storing and supplying cold water so that the heat medium range becomes the entire cold water storage tank to maintain a large heat capacity according to load fluctuations. In order to reduce the temperature change of the whole cold water and to increase the heat transfer efficiency from the evaporator to the cold water, the evaporator type is a plate fin type evaporator in which a plate-type cooling fin is further attached to the tube. That is, an evaporator having a plate fin as shown in FIGS. 3 and 4 is used, and a float valve or a water level control having an equivalent function is provided so that the evaporator is always in contact with cold water. . The plate fin type evaporator may apply various known plate fin type heat exchangers, and the water level control unit may apply various well-known level control units in addition to those described above.

Preferably, the plate fin type evaporator may use a fin plate type configured by bending the refrigerant pipe in a constant plane as shown in FIG. 3 to form a planar shape, or a pin for bending the refrigerant pipe in a coil shape and attaching a plate pin thereto. It can be configured in the form of a coil type. In addition, the material of the evaporator may be made of aluminum in its entirety, or the refrigerant pipe may be made of copper (Cu) and the cooling fin may be made of aluminum, and preferably, all of the refrigerant pipe and the cooling fin are made of copper to ensure corrosion resistance. Good to do. In addition, in the case of a frame for supporting the evaporator in the tank, it is preferable to configure the stainless steel in consideration of corrosion resistance.

In addition, the plate fin coil-type evaporator is submerged in addition to the partition except for the evaporator can be reduced the appearance and heat exchange efficiency due to the fluid passing through the heat exchange only. Since the contents thereof are well known technologies, detailed description thereof will be omitted.

The constant level does not necessarily mean a level in which the evaporator is submerged in cold water, and may be any level that allows the evaporator to come in contact with the cold water as required by the cold water supply device.

In addition, the plate fin type evaporator as described above is integrally formed by the cooling fin as described above, so it is easy to configure the module, the heat exchanger includes a module consisting of at least two plate fin evaporators, these It can be configured to combine, and through this it is possible to take a way to separate and replace only the corresponding module during maintenance has the advantage of easy maintenance.

Therefore, the evaporator may be configured as a stack type evaporator formed by stacking a plurality of plate fin type heat exchangers in the form of a plate or a plate fin type heat exchanger in the form of a coil as shown in FIG. 3.

In addition, the outlet end of the cold water recovery pipe is configured in the form of a plurality of outlets for discharging cold water to the front of the laminated heat exchanger or the first stage heat exchanger when the evaporator is a plate fin type heat exchanger of a flat plate type. Preferably, the lamination may be preferably stacked side by side in the longitudinal or transverse direction, in this case the front side is the front or rear in the vertical direction, in the case of horizontal lamination the upper or lower surface is the front Becomes One embodiment of longitudinal stacking and thus discharge from the front is shown in FIG. 6. Through this, it is possible to facilitate the heat exchange between the cold water recovered at a high temperature and the evaporation period. In this case, the discharge of the cold water is basically made in the water according to the relationship between the evaporator and the cold water level, and in some cases, only part of the cold water may be submerged.

In addition, when the evaporator is a coil-type plate fin type heat exchanger, the outlet end of the cold water recovery pipe may include a plurality of outlets for discharging cold water outward from the inside of the stacked heat exchanger or the first heat exchanger. It may be configured as, the lamination may be preferably stacked side by side in the vertical direction or left and right directions. Through this, it is possible to facilitate the heat exchange between the cold water recovered at a high temperature and the evaporation period.

In addition, such a plurality of stacked evaporators may be preferably coupled in parallel as shown in Figure 5 and have a configuration including a manual or automatic opening and closing valve at the inlet or outlet of each module. In this case, even if a certain module is blocked, the operation of the equipment can be made continuously, and if a certain module is leaked, there is an advantage that the continuous operation of the equipment is possible by closing only the module using the open / close valve.

In another preferred form, the heat exchanger for each layer of the stacked evaporator can control the cooling efficiency by controlling the number of evaporators operated and the flow rate of the refrigerant flowing into each evaporator, as shown in FIG. The outlet and the refrigerant inlet and outlet may be configured to each have a valve for controlling the refrigerant inlet flow rate.

As described above, according to the cold water supply apparatus of the present invention, a refrigerating cycle even under load fluctuations by significantly increasing the heat exchange efficiency compared to the conventional cold water supply apparatus in the form of a pipe and bringing the heat capacity to the entire cold water stored. By stabilizing the effect of reducing the damage caused by frequent intermittent operation of the compressor, it is effective to reduce the temperature change of the stored cold water.

In addition, by combining the storage tank and the evaporator integrally, the cold water supply unit is integrally formed to simplify the equipment, and additional field piping and secondary supply pump between the storage tank and the cold water supply unit are not required, thereby simplifying the site installation. It can reduce the size of the evaporator and improve the heat exchange efficiency.

The present invention described above is not limited to the detailed description and drawings of the above-described invention, and those skilled in the art can be variously modified without departing from the spirit and scope of the present invention described in the utility model registration claims below. Modifications and variations are also included within the scope of the present invention.

1 is a photograph of an example of a spiral heat exchanger used in a conventional cold water supply device.

2 is a system schematic diagram of an embodiment of a cold water supply device of the present invention.

3 is a partially exploded perspective view of a plate fin type evaporator applied to the present invention.

Figure 4 is an enlarged perspective view showing a portion of one embodiment of a plate fin type evaporator applied to the present invention.

5 is a view schematically showing an embodiment of a coupling method of a stacked evaporator applied to a cold water supply device of the present invention.

FIG. 6 is a view schematically showing another embodiment of the combined method of the stacked evaporator applied to the cold water supply device of the present invention and the case of the outlet stage injection method from the side.

Explanation of symbols on main parts of drawing

5: refrigerant circulation tube 6: cooling plate fin

7: through-hole 8: U-shaped band

10: storage tank 11: cold water supply unit

12: cold water recovery port 13: cold water recovery piping

15 pump 16 injection hole

21 condenser 22 compressor

23: receiver tank 24: evaporator (plate fin type)

25 expansion valve 31 float valve (water level control)

32: over-drain piping 33: drain piping

34: cold water supply pipe 35: water supply pipe

36: direct piping

Claims (5)

In cold water supply apparatus, A cold water storage tank for storing cold water and supplying the cold water; A water level control unit for maintaining the water level of the cold water storage tank at a predetermined level; A plate fin type evaporator located below the predetermined water level in the cold water storage tank and connected to a refrigerant pipe; A cold water pipe having one end connected to a cold water recovery port, the other end connected to the cold water storage tank, and one end connected to the cold water storage tank, and the other end connected to a cold water supply port. Cold water supply characterized in that. The method of claim 1, The evaporator is a plate fin type heat exchanger having a flat plate type or a stacked evaporator formed by stacking a plurality of the same, and the outlet end of the cold water return pipe includes a plurality of outlets for discharging cold water to the front of the heat exchanger. Cold water supply. The method of claim 1, The evaporator is a coil-type plate fin type heat exchanger or a laminated evaporator formed by stacking a plurality of the same, and the outlet end of the cold water return pipe is formed of a plurality of outlets for discharging cold water outward from the coil of the heat exchanger. Cold water supply characterized in that. The method according to claim 2 or 3, The frame of the evaporator is stainless steel, the plate fin is cold water supply, characterized in that the copper. The method according to claim 2 or 3, The heat exchanger for each layer of the multi-layer evaporator is provided with a separate refrigerant inlet and outlet, each of the refrigerant inlet and outlet comprises a valve for controlling the refrigerant inlet flow rate.