KR20160094048A - Heat-exchange Tank Module - Google Patents

Abstract

According to the present invention, a heat exchanging tank module of a purifier where attachment and detachment between a main body module and a cover module and attachment and detachment between the cover module and a cold water pipe are easily performed is disclosed. According to one embodiment, the heat exchanging tank module comprises: the main body module having a tank case storing a cooling pipe therein; and the cover module having a tank cover sealing the tank case and having a cold water pipe inserted into the tank case through the tank cover to exchange heat with the cooling pipe. The main body module and the cover module are coupled by using a locking method.

Description

[0001] Heat-exchange tank module [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat exchange tank module for a water purifier in which a body module, a cover module, and a cover module and a cold water pipe are easily detachable.

A water purifier is a device that filters raw water by physical or chemical method to remove impurities and then supplies it. The water purifier can cool the purified water as well as the purified water at room temperature to generate cold water and then supply it.

In recent years, an ice-cooling-water-type water purifier is used in which the cooling device cools the fluid in the ice storage-type cooling bath and the cold water pipe through which the purified water passes is cooled by the cooling device.

On the other hand, foreign matter penetrates into the cold water pipe, and cold water may be contaminated. In addition, since the unfiltered material contained in the cold water adheres to the inner surface of the cold water pipe, the water inside the cold water pipe may be re-contaminated.

However, in the integrated assembly structure of the cold water pipe and the cold water heat exchange tank, it is impossible to replace the cold water pipe, so that even if the pollutant is attached to the inside of the cold water pipe,

The present invention provides a heat exchange tank module for a water purifier in which detachment of the body module, the cover module, and detachment of the cover module and the cold water pipe is facilitated.

A heat exchange tank module according to the present invention includes: a main body module including a tank case for receiving a cooling pipe therein; And a cover module including a tank cover for sealing the tank case and a cold water pipe inserted into the tank case through the tank cover and performing heat exchange with the cooling pipe, or in a locking manner.

In addition, the tank case may include a case locking engagement hole at least at one side thereof, and at least a part of the locking portion provided in the cover module may be coupled through the case locking engagement hole.

In addition, the locking portion may be moved through a sliding method and coupled to the case locking engagement hole.

Further, the locking portion may be rotated about one end fixed to the tank cover and coupled to the case locking engagement hole.

In addition, at least a part of the locking part provided in any one of the tank case and the tank cover may be hooked to the other one of the tank case or the tank cover.

Further, the cold water pipe may include a connecting portion sealing member formed at an end portion thereof.

The cold water pipe may have a diameter of 7 mm to 9 mm.

Further, the cooling pipe may be spaced apart from the inner wall of the tank case by 5 mm to 15 mm.

In addition, the cooling pipe may have a gap between the cores of 5 mm to 15 mm.

The connecting portion of the cold water pipe may be an orifice.

In addition, the cover module may include an agitating device for agitating the heat transfer medium accommodated in the tank case.

The stirring device may include a stirring motor for transmitting power to the inside of the heat exchange tank module; A stirring impeller connected to a driving shaft of the stirring motor to perform stirring; And a stirring net surrounding the stirring impeller along the stirring impeller axis.

Further, the stirring impeller has an end located at a point 1/3 to 1/2 of the height of the heat transfer medium from the bottom of the tank case.

The apparatus may further include a leakage sensor for detecting leakage of water on the tank cover.

The apparatus may further include a temperature sensor for sensing a temperature inside the tank case.

The heat exchange tank module according to the present invention includes a body module and a cover module, wherein the locking part formed on the cover module is coupled to the tank case and the coupling hole formed on the tank cover, so that the body module and the cover module can be easily coupled have.

Further, the cover module includes a cold water pipe and a tank cover, wherein the pipe connection formed at the cold water pipe end is coupled to the joint portion on the tank cover, so that the cold water pipe and the tank cover can be easily joined and separated.

Accordingly, if necessary, the main module and the cover module can be separated, and the cold water pipe and the tank cover of the cover module can be separated from each other, thereby facilitating the cleaning and replacement of the cold water pipe.

1 is an exploded perspective view of a heat exchange tank module according to an embodiment of the present invention.
2 is an exploded perspective view of a cover module according to an embodiment of the present invention.
3 is a sectional view taken along the line A-A 'in a state where the heat-exchanging tank module of FIG. 1 is engaged.
FIG. 4A is an enlarged view of a portion B before the heat-exchanging tank module of FIG. 1 is engaged. FIG.
Fig. 4B is an enlarged view of a portion B in a state where the heat-exchanging tank module of Fig. 1 is engaged. Fig.
5A is a view illustrating a state before a main body module and a cover module are coupled in a heat exchange tank module according to another embodiment of the present invention.
5B is a view illustrating a state in which a main body module and a cover module are coupled in a heat-exchange tank module according to another embodiment of the present invention.
6A is a view illustrating a state in which a main body module and a cover module are coupled in a heat exchange tank module according to another embodiment of the present invention.
FIG. 6B shows a modification of the heat-exchanging tank module according to FIG. 6A.
7 is a cross-sectional view of a heat exchange tank module according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

1 is an exploded perspective view of a heat exchange tank module according to an embodiment of the present invention. 2 is an exploded perspective view of a cover module according to an embodiment of the present invention. 3 is a cross-sectional view taken along the line A-A 'in a state where the tank module of FIG. 1 is engaged. Figs. 4A and 4B are enlarged views of a portion B before and after the heat exchange tank module of Fig. 1 is engaged. Fig.

1 to 4B, a heat exchange tank module 100 according to an embodiment of the present invention includes a main body module 110 and a cover module 120. [

The main body module 110 includes a tank case 111 and a cooling pipe 112. In addition, the main body module 110 may further include a heat transfer medium drain pipe 113.

The tank case 111 has a substantially hexahedral shape. The tank case 111 has a space therein and has an opening at the top. The tank case 111 has a case locking engagement hole 111b in a case locking engagement portion 111a formed on at least one side of the upper portion thereof. The case locking engagement part 111a protrudes upward from the tank case 111 and the case locking engagement hole 111b is formed in a hole shape inside the case locking engagement part 111a do. In addition, the tank case 111 receives the heat transfer medium together with the cooling pipe 112 in a space provided therein.

The cooling pipe 112 is formed in a substantially coil shape along the inner wall surface of the tank case 111. The coolant cooled by the cooling device (not shown) flows through the cooling pipe inlet portion 112a, transfers cool air to the cold water pipe 122 thermally connected to the cooling pipe 112 while flowing along the cooling pipe 112, And flows out through the outlet portion 112b. In order to efficiently perform heat exchange in the tank case 111, the cooling pipe 112 must secure a sufficient total area of contact with the heat transfer medium, and the heat transfer medium must have a sufficient flow rate to receive cold air do. For this purpose, the cooling pipe 112 may be spaced 5 mm to 15 mm from the inner wall of the tank case 111. The flow rate of the heat transfer medium in the space between the cooling pipe 112 and the inner wall surface of the tank case 111 can be secured to a certain level or more. In addition, when the width is 15 mm or less, the total area of the cooling pipe 112 contacting the heat transfer medium can be secured to a certain level or more. For this reason, the interval between the cooling pipes 112 may be 5 mm to 15 mm. The flow rate of the heat transfer medium in the space between the coils of the cooling pipe 112 can be secured to a certain level or more. In addition, when the width is 15 mm or less, the total area of the cooling pipe 112 contacting the heat transfer medium can be secured to a certain level or more.

The heat transfer medium serves as a medium to allow the cold water delivered by the cooling pipe 112 to be received by the cold water pipe 122.

The heat transfer medium drain pipe 113 discharges the heat transfer medium received in the tank case 111 to the outside of the tank case 111.

The cover module 120 includes a tank cover 121, a cold water pipe 122, a joint portion 124, and a locking portion 128. The cover module 120 may further include a sealing member 122, a temperature sensing sensor 125, a water leakage sensor 126, and a heat transfer medium injection unit 127.

The tank cover 121 has a shape corresponding to the opening of the tank case 111 and is coupled to the opening of the tank case 111. The tank cover 121 has a cover locking engagement hole 121b formed in at least one side of the cover locking engagement portion 121a. The cover locking engagement portion 121a may extend from the side surface of the tank cover 121 to the upper or lower direction of the tank cover 121. [ The case locking engagement hole 111b and the cover locking engagement hole 121b correspond to each other in position and shape.

The cold water pipe 122 is coupled to the lower surface of the tank cover 121. Further, the cold water pipe 122 is formed in a substantially coil shape. The raw water purified by the water purifier (not shown) flows through the cold water pipe inlet 122a and receives cool air from the cooling pipe 112 thermally connected to the cold water pipe 122 while flowing along the cold water pipe 122, And flows out through the cold water pipe outlet portion 122b. The cold water pipe 122 may have a diameter of 7 mm to 9 mm. 7 mm or more, it is possible to prevent the raw water in the cold water pipe 122 from being excessively cooled. In addition, when the thickness is 9 mm or less, the total area of the cooling pipe 112 contacting the heat transfer medium can be secured to a certain level or more.

The cold water pipe 122 has a pipe connecting portion 122c at an end portion connected to the joint connecting portion 124c of the joint portion 124. [ The pipe connection portion 122c may have an orifice shape in order to prevent an excessive flow rate from being passed through the pipe connection portion 122c. This minimizes the decrease of the flow rate at the low flow rate and maximizes the decrease of the flow rate at the high flow rate, thereby reducing the temperature variation of the cold water by reducing the fluctuation of the flow rate depending on the raw water pressure.

The sealing member 123 has a shape corresponding to the tank cover 121 at the lower end of the tank cover 121. In addition, the upper end of the opening of the tank case 111 may have a shape corresponding to the opening of the tank case 111. That is, the sealing member 122 is positioned between the tank case 111 and the tank cover 121 to keep the connection between the tank case 111 and the tank cover 121 more tightly, Thereby preventing the material inside the tank case 111 from flowing out or preventing the material outside the tank case 111 from being introduced into the tank case 111.

The end of the joint portion 124 is engaged with the ends of the water purification apparatus (not shown) and the cold water pipes 122, The purified water flows into the cold water pipe 122 through the joint inlet 124a and the purified water flows out from the cold water pipe 122 through the joint outlet 124b. The joint portion 124 has a joint connecting portion 124c. The inner surface shape of the joint connecting portion 124c corresponds to the outer shape of the pipe connecting portion 122c having the connecting portion sealing member 122d.

Therefore, the cold water pipe 122 can be separated from the cover module 120 having the joint 124, so that the cold water pipe 122 can be cleaned and replaced, if necessary.

The temperature sensor 125 is formed on the tank cover 121. A part of the lower end of the temperature sensor 125 is accommodated in the heat transfer medium to sense the temperature. The sensed temperature is transmitted to a temperature control unit (not shown).

The water leakage sensor 126 is formed on the tank cover 121 in proximity to the joint portion 124. The water leakage sensor 126 detects the occurrence of water leakage from the joint part 124. The sensed signal is transmitted to a leakage control unit (not shown).

The locking part 128 is formed around the upper surface of the tank cover 121. The locking portion 128 includes a locking body portion 128a and a locking engagement portion 128b. The locking engagement portion 128b extends from the locking body portion 128a in the direction of the cover locking engagement hole 121b. The locking part 128 has a space in the locking body part 128a for the convenience of sliding movement of the body module 110 and the cover module 120 for coupling and separation, As shown in Fig. In addition, the locking body 128a may be thicker than the locking engagement portion 128b in the vertical direction. The ends of the locking engagement portion 128b correspond to the cover locking engagement hole 121b in position and shape, respectively. The locking portion 128 is configured such that when the locking body portion 128a is moved, the locking engagement portion 128b is engaged with the case locking engagement hole 111b and the cover locking engagement hole 121b ) Through which the lock is made.

Therefore, the cover module 120 and the cold water pipe 122 can be separated from each other, if necessary, and the cold water pipe 122 (122) ) Can be cleaned and replaced.

The heat transfer medium injection unit 127 has a hole shape as viewed from the upper surface of the tank cover 121. The heat transfer medium injection unit 127 has an inner wall surface having a predetermined length from the lower surface of the tank cover 121 toward the inside of the tank case 111 and a mark 127a is formed at an end of the inner wall surface . When the heat transfer medium is injected from the outside of the heat exchange tank module 100 into the inside of the heat exchange tank module 100, the indication line 127a can easily confirm an appropriate amount of the heat transfer medium to the naked eye.

The cover module 120 may include an agitator 130 for agitating the heat transfer medium for efficient heat exchange between the cooling pipe 112 and the cold water pipe 122.

The stirring device 130 includes a stirring motor 131, a stirring impeller 132, and a stirring mesh 133.

The stirring motor 131 is installed on the tank case 121 so that a drive shaft is directed to the inside of the tank case 121. The stirring motor 131 is connected to a separate power source to transmit the power from the power source to the stirring impeller 132.

The stirring impeller 132 is coupled to the driving shaft of the stirring motor 131 in parallel and passes through the inside of the coil of the cooling pipe 112 and the cold water pipe 122. The stirring impeller 132 may be of a furnace type, a propeller type, a screw type, or a turbine type. The stirring impeller 132 serves to help the cold air transferred from the cooling pipe 112 to be transmitted to the cold water pipe 122 through the heat transfer medium by uniformly stirring the heat transfer medium. The end of the stirring impeller 132 may be located at a position 1/3 to 1/2 of the height of the heat transfer medium from the bottom of the tank case 111. The heat transfer medium in the tank case 111 can form a flow flow for securing not only sufficient stirring in the horizontal direction but also sufficient stirring in the vertical direction. In addition, when the volume of the heat transfer medium is 1/2 or less, it is possible to prevent the water surface of the heat transfer medium from being excessively entangled due to the flow of the flow due to the driving of the stirring impeller 132.

The stirring mesh 133 is formed to surround the stirring impeller 132 along the axis of the stirring impeller 132. If the heat transfer medium is excessively cooled, fine ice particles may be formed. When the ice particles collide with the stirring impeller 132, noise may be generated and heat transfer efficiency due to stirring may be reduced. Accordingly, the stirring net 133 prevents the impingement of the stirring impeller 132 from the ice particles and generates a uniform flow, thereby enabling efficient heat exchange.

Hereinafter, the structure of the heat-exchanging tank module according to an embodiment of the present invention will be described in more detail with reference to Figs. 4A and 4B.

4A and 4B, in a state where the main body module 110 and the cover module 120 are separated from each other, the case locking engagement portion 111a and the cover locking engagement portion 121a are disposed adjacent to each other And the case locking defect hole 111b and the cover locking engagement hole 121b are disposed so as to correspond to each other in position and shape. The locking coupling part 128b slidably moves the locking main body part 128a in a direction passing through the case locking engagement hole 111b and the cover locking engagement hole 121b, The cover module 120 is coupled. Accordingly, the locking main body 128a, the case locking engagement hole 111b, and the cover locking engagement hole 121b are disposed in order, and the locking engagement portion 128b, which is connected to the locking body portion 128a, The case locking engagement portion 111a and the cover locking engagement portion 121a are moved in the vertical direction through the case locking engagement hole 111b and the cover locking engagement hole 121b, It can be fixed so as not to be detached. When the opening of the tank case 111 is larger than the tank cover 121 according to the engaged state, the locking body portion 128a, the cover locking engagement hole 121b, and the case locking engagement hole 111b, They may be arranged in order. Also, the main body module 110 and the cover module 120 are separated by sliding in the opposite direction to the case of coupling the locking body portion 128a.

As described above, the heat-exchanging tank module 100 according to an embodiment of the present invention easily slides and separates the body module 110 and the cover module 120 by sliding the locking part 128 .

Hereinafter, the structure of a heat exchange tank module according to another embodiment of the present invention will be described.

5A and 5B are perspective views of a heat exchange tank module according to another embodiment of the present invention before and after the heat exchange tank module is coupled.

The same reference numerals are used for the components having the same configurations and functions as those of the previous embodiment. Hereinafter, the difference between the first embodiment and the configuration will be mainly described.

5A and 5B, locking portion 228 includes locking body portion 228a and locking engagement portion 228b. The locking body portion 228a is fixed on the tank cover 121 and functions as a rotary shaft for rotating the locking engagement portion 228b. The locking engagement portion 228b extends from the locking body portion 228a in a bar shape. The case locking engagement portion 211a and the cover locking engagement portion 221a are disposed adjacent to each other while the main body module 110 and the cover module 120 are coupled to each other, The cover locking engagement holes 221b are disposed so as to correspond in position and shape to each other. The case locking engagement portion 211a and the cover locking engagement portion 221a may be opened at one side to receive the locking engagement portion 228b. The locking coupling portion 228b is rotated about the locking main body portion 228a in the direction in which the locking locking engaging hole 211b and the cover locking locking hole 221b pass, The cover module 120 is engaged. Accordingly, the locking body 228a, the case locking engagement hole 211b, and the cover locking engagement hole 221b are disposed in order, and the locking engagement portion 228b, which is connected to the locking body portion 228a, The case locking engagement portion 211a and the cover locking engagement portion 221a are moved in the vertical direction through the case locking engagement hole 211b and the cover locking engagement hole 221b so that the locking portion 228, As shown in FIG. When the opening of the tank case 111 is larger than the tank cover 121 according to the engaged state, the locking main body portion 228a, the cover locking engagement hole 221b, and the case locking engagement hole 211b, They may be arranged in order. Also, the main body module 110 and the cover module 120 are separated by rotating in the opposite direction to the case of coupling the locking engagement portion 228b.

As described above, the heat-exchange tank module according to another embodiment of the present invention rotates the locking engagement portion 228b about the locking body portion 228a, thereby rotating the body module 110 and the cover module 120 Can be easily combined and separated.

Hereinafter, the structure of a heat exchange tank module according to another embodiment of the present invention will be described.

6A is a perspective view of a heat exchange tank module according to another embodiment of the present invention.

Referring to FIG. 6A, the case locking engagement portion 311a is formed in a hook shape toward the upper portion of the tank case 311. The case locking engagement portion 311a is hooked adjacent to the upper portion of the tank cover 321 in a state where the body module 310 and the cover module 320_ are coupled to each other so that the tank case 311 and the tank cover 321 may be fixed in the vertical direction.

FIG. 6B shows a modification of the heat-exchanging tank module according to FIG. 6A.

6A, when the opening of the tank case 311 is smaller than that of the tank cover 321, the case locking engagement portion 311a 'is formed on at least one surface of the tank cover 321 as a downwardly hooked shape . In this case, the hook is hooked on a side surface of the tank case 311 so as to be adjacent to a groove or a projection formed at a position corresponding to the hook.

As described above, the heat-exchanging tank module according to another embodiment of the present invention can be easily coupled to the body module 310 and the cover module 320 by hooking the case-locking engagement portion 311a. Can be separated.

Hereinafter, the structure of a heat exchange tank module according to another embodiment of the present invention will be described.

7 is a cross-sectional view of a heat exchange tank module according to another embodiment of the present invention.

3, the bent joint 124 is connected to the cold water pipe 122 through the pipe connecting part 122c having the connecting part sealing member 122d in FIG. 3 . In FIG. 7, the cold water pipe 122 is connected to the water purification unit (not shown) through a pipe connection part 422c.

7, the pipe connecting portion 422c has a curved shape in which one end is coupled to the cold water pipe 122 and the other end is coupled to the water purifier (not shown). Accordingly, the pipe connecting portion 422c connects the cold water pipe 122 and the water purifier (not shown). The pipe connecting portion 422c is made of a rubber material having elasticity and frictional force. This allows the coupling between the tank cover 121, the cold water pipe 122 and the water purifier (not shown) to be more tightly maintained. That is, the pipe connecting portion 422c of FIG. 7 performs the role of the joint portion 124 and the connecting portion sealing member 122d of FIG. 3, so that the number of parts is reduced and the cover module 120 is separated, The coupling becomes easy. In addition, the number of the connecting parts for managing leakage between components is also reduced, and the management of the heat-exchanging tank module 100 is facilitated.

Meanwhile, in order to increase the fastening force between the pipe connecting portion 422c and the cold water pipe 122, an outer portion of the pipe connecting portion 422c, into which the one end of the cold water pipe 122 is inserted, is fixed with a cable tie 422e . In order to increase the fastening force between the pipe connecting portion 422c and the water purifying device (not shown), the outside of the portion of the pipe connecting portion 422c into which the one end of the water purifier (not shown) is inserted is connected with a cable tie 422f Can be fixed. Also, the cable ties 422e and 422f may be fixed using a clamp.

As described above, since the number of parts of the heat exchange tank module according to another embodiment of the present invention is reduced, it is easy to replace, clean, and manage the cold water pipe.

The present invention is not limited to the above-described embodiments, but may be modified in various ways within the spirit and scope of the present invention as set forth in the following claims. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100; Heat exchange tank module
110; Body module
111; Tank case
112; Cooling pipe
120; Cover module
121; Tank cover
122; Cold water pipe
124; Joint part
129; Locking portion
130; Stirring device

Claims (17)

A main body module including a tank case for accommodating a cooling pipe therein; And
And a cover module including a tank cover for sealing the tank case and a cold water pipe inserted into the tank case through the tank cover and performing heat exchange with the cooling pipe,
Wherein the main body module and the cover module are coupled in a locking manner. The method according to claim 1,
Wherein the tank case has a case locking engagement hole on at least one side thereof,
Wherein at least a part of the locking portion provided on the cover module is coupled through the case locking engagement hole. 3. The method of claim 2,
Wherein the locking portion is moved through a sliding manner and is coupled to the case locking engagement hole. 3. The method of claim 2,
Wherein the locking portion is rotated about one end fixed to the tank cover and is coupled to the case locking engagement hole. The method according to claim 1,
Wherein at least a part of the locking part provided in either the tank case or the tank cover is hooked and coupled to the other one of the tank case or the tank cover. The method according to claim 1,
And the cold water pipe is connected to the outside of the cover module through a joint part connected to one end. 7. The heat exchange tank module of claim 6, wherein the cold pipe includes a heat sealing member formed at an end thereof. 8. The method of claim 7,
And the joint portion and the connecting portion sealing member are integrally formed. The method according to claim 1,
Wherein the cold water pipe has a diameter of 7 mm to 9 mm. The method according to claim 1,
Wherein the cooling pipe is spaced from the inner wall of the tank case by 5 mm to 15 mm. The method according to claim 1,
Wherein the cooling pipe has a gap between the cores of 5 mm to 15 mm. The method according to claim 1,
Wherein the connecting portion of the cold water pipe has an orifice shape. The method according to claim 1,
Wherein the cover module includes a stirring device for stirring the heat transfer medium received in the tank case. 14. The method of claim 13,
The stirring device
A stirring motor for transmitting power to the inside of the heat exchange tank module;
A stirring impeller connected to a driving shaft of the stirring motor to perform stirring; And
And a stirring net surrounding the stirring impeller along the stirring impeller axis. 15. The method of claim 14,
Wherein the stirring impeller has an end located at a position 1/3 to 1/2 of the height of the heat transfer medium from the bottom of the tank case. The method according to claim 1,
Further comprising a leakage sensor for detecting leakage of water on the tank cover. The method according to claim 1,
And a temperature sensor for sensing a temperature inside the tank case.

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