KR20050018829A - A cold and hot water purifier with multilateral uniform rapid cooling function - Google Patents

Abstract

PURPOSE: To provide a cold/hot water purifier with polyhedral uniform rapid cooling function, wherein refrigerant pipes are evenly formed in the whole space inside a cold water tank so that purified water of the cold water tank is contacted with refrigerant of the refrigerant pipes directly and polyherally to rapidly cool the purified water within a short time. CONSTITUTION: In a cold/hot water purifier for cooling the purified water through heat exchange of purified water in a cold water tank(10) with refrigerant of refrigerant pipes(20a,20b), the cold/hot water purifier with polyhedral uniform rapid cooling function is characterized in that the refrigerant pipe(20a) for circulating refrigerant is connected to the upper side of a cooling body(32) which is constructed in a refrigerant-free pipe structure with being continuously arranged along the upper side or the lower side of cooling plates(30), the cooling plates integrally formed in multilayers around the cooling body in a central inner part of the cold water tank, and in which a refrigerant channel(36) is formed so that refrigerant passes through the refrigerant channel, and the refrigerant pipe(20b) for circulating refrigerant is connected to the lower side of the cooling body again so that refrigerant is circulated through the refrigerant pipes extended along the cooling body and a cooling plate(34) and contacted with purified water of the cold water tank directly and polyhedrally.

Description

Cold and hot water purifier with multi-sided uniform rapid cooling function {A cold and hot water purifier with multilateral uniform rapid cooling function}

The present invention relates to a cold and hot water purifier that has dramatically increased the overall contact area between the purified water of the cold water tank and the refrigerant pipe in which the refrigerant is circulated. More specifically, the refrigerant tube in which the refrigerant is circulated is cooled in a vertical direction having no refrigerant pipe structure. The contact area of the coolant pipe to the water in the cold water tank can be structurally increased by extending and extending the entire cooling plate in the horizontal direction as well as the rod, so that it can rapidly cool a large amount of water uniformly in a short time. It relates to a cold and hot water purifier having.

Cold and hot water purifier is basically composed of a water purifying unit for purifying water, a cold and hot water unit for storing the purified water as cold and hot water, and a control unit for controlling the operation signal of the cold and hot water purifier. Through the water tank above the cold water tank, the cold water is introduced into the cold water tank, and is heat-exchanged by the cold refrigerant in the refrigerant pipe mounted in a circulation structure, thereby cooling to a predetermined temperature. In addition, the water flows back into the cold water tank by the amount of outflow of the cooled water from the cold water tank.

When the indirect cooling method is applied to cool the purified water flowing into the cold water tank as described above, as shown in FIG. 2A, the refrigerant pipes 20a and 20b are wound around the outside of the cold water tank 10 to a predetermined length. By cooling the water in the cold water tank 10 by acting as an evaporator. However, the indirect cooling method has a slight amount depending on the capacity of the reservoir (not shown) as the water in the cold water tank 10 increases as the inflow into the cold water tank 10 increases as the outflow water to the outside of the cold water tank 10. In addition, the inflow and outflow water are mixed with each other, the water temperature rises sharply, and there is a limit that the variation of the water temperature occurs in the inside and outside of the cold water tank 10 and the upper and lower temperatures due to the indirect cooling method.

In addition, in the case of the direct cooling method introduced to improve the limitation of the indirect cooling method, as shown in FIG. 2B, the endothermic cylinder 40 having the refrigerant pipes 20a and 20b inserted therein is installed inside the cold water tank 10. The water of the purified cold water tank 10 may be directly heat-exchanged by the endothermic cylinder 40 to be cooled, which, unlike indirect cooling, utilizes all of the cooling heat transferred from the refrigerant pipes 21a and 21b. As a result, the cooling efficiency is higher than that of the indirect cooling method.

However, in both direct and indirect cooling methods up to now, when a large amount of cooled water in the cold water tank 10 is discharged in a short time, the limitation of the cooling structure that the lukewarm water that is not cooled is inevitably leaked is not overcome. . Because most of the space of the cold water tank 10 in which water is stored is limited to the direct cooling function by the horizontal cooling plate 30 protruding into a plurality of spiral layers with respect to the central vertical cooling rod (heat absorbing cylinder). there was.

That is, since the refrigerant is circulated only toward the endothermic cylinder 40 at the side of the cold water tank 10 or the center of the cold water tank 10, most of the internal space of the cold water tank 10 in which the plurality of cooling plates 30 are located is relatively. Since the degree of heat exchange with the cold refrigerant is inevitably lowered, there is a structural limitation that the cooling efficiency of the cold water tank 10 is lowered. As a result, when the cold cold water is discharged in a large amount within a short time, the water in the upper space of the cold water tank 10 has to be mixed with the water in the lower space before being coldly cooled, which is inevitably spilled in a lukewarm state.

The present invention was developed in order to uniformly and rapidly cool the water in the cold water tank which has not been solved in the cold / hot water purifier in the short time in a short time in consideration of such circumstances. It is an object of the present invention to provide a cold and hot water purifier having a multi-faceted uniform rapid cooling function so that the purified water in the cold water tank can be directly contacted with the refrigerant in the refrigerant pipe by being able to be evenly placed in the surface.

Furthermore, even though the water from the direct water line is not directly stored in a separate reservoir, it is purified immediately and flows into the cold water tank, but it is rapidly changed to a certain temperature within a short time continuously by the refrigerant in the refrigerant pipe having an extended contact area with water. Since the cooling is possible, the unnecessary space of the water tank can be utilized as the cold water tank space, and the ultimate purpose is to provide a cold multi-stage water purifier with a new multi-faceted uniform rapid cooling function that can dramatically increase the power saving efficiency.

In order to achieve the above object, a cold / hot water purifier having a multi-uniform uniform rapid cooling function is a coolant water purifier in which purified water inside a cold water tank is cooled through heat exchange with a coolant in a coolant tube. Is continuously disposed along the upper side or the lower side of the cooling plate integrally formed in multiple layers centering on the cooling body in the center of the cold water tank, and is a refrigerant-free pipe structure, the upper side of the cooling body through which the refrigerant can pass through the refrigerant flow passage therein. It is connected to, the lower side of the cooling body is connected to the refrigerant pipe circulating the refrigerant again is configured to be in direct contact with the water of the cold water tank while the refrigerant is circulated through the refrigerant pipe extending along the cooling body and the cooling plate. .

In addition, the coolant pipe is extended to the upper or lower side of the cooling plate and the space of the cold water tank between these cooling plates with different layers, and in particular, the cooling body circulates the refrigerant flowing through one refrigerant pipe to the other refrigerant pipe. Refrigerant flow path through which the refrigerant is passed is formed on the outside of the cooling rod coupled to the inside to be formed.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment for a cold and hot water purifier having a multi-layer uniform quick cooling function of the present invention will be described in detail.

The cold / hot water purifier according to the present invention has a new cooling structure in which the refrigerant is circulated through the entire cooling plate in the horizontal direction and the cooling rod in the vertical direction in the form of a refrigerant-free tube in the vertical direction, and uniformly rapidly cools the purified water in the cold water tank. As shown in 1a and 1b, the upper or lower side of the cooling plate 30 formed integrally with the coolant tube 20a through which the coolant is circulated, in a multi-layer structure around the cooling body 32 in the center of the cold water tank 10. It is continuously disposed along and connected to an upper side of the cooling body 32 through which the refrigerant can pass through the refrigerant passage 36 therein as a refrigerant-free pipe structure, and the refrigerant below the cooling body 32 again. The refrigerant pipe 20b through which the refrigerant is circulated is connected to the refrigerant through the refrigerant pipes 20a and 20b extended along the cooling body 32 and the cooling plate 34, and the water of the cold water tank 10 It is configured to be in direct multiple contact.

In addition, one coolant pipe 20b connected to the bottom of the cooling rod 34 in the cooling body 32 has a cooling plate 30 that protrudes continuously in an integral structure with different layers on the outside of the cooling body 32. With respect to the upper side or the lower side, as well as the space of the cold water tank 10 between these cooling plate 30 may be extended and disposed by different layers. This is to structurally increase the direct contact area of the refrigerant with the purified water. Of course, even if the refrigerant pipe (20a, 20b) is in direct contact with the water of the cold water tank 10, it is obvious that there is no problem in the safety of the water.

As shown in the figure, the refrigerant pipes 20a and 20b are disposed in different layers than those repeatedly repeatedly in the same layer with respect to the cooling plate 30, so that the efficiency of heat exchange with the refrigerant is much higher in operation. Since it is high, it is preferable to arrange | position appropriately with respect to the said refrigerant pipe 20a, 20b on the space between the upper side or the lower side, and both refrigerant pipes. In addition, when one refrigerant pipe 20a disposed in the cold water tank 10 space passing through the bottom of the cold water tank 10 is connected to a compressor (not shown), the other side of the cooling rod 34 may be connected. The refrigerant pipe 20b may naturally be connected to an evaporator (not shown) to circulate the refrigerant by a conventional refrigeration cycle.

In addition, the cooling rod 34 used in the cold / hot water purifier of the present invention has a coolant flow path 36 having a predetermined depth in a spiral shape, such as a cooling plate 30 having a spiral outside thereof, or the coolant flow path 36 in a longitudinal direction. Is formed in the groove, the coolant flowing through one of the refrigerant pipe (20a) along the refrigerant passage (36) of the cooling rod (34) can be passed to the other refrigerant pipe (20b) 32) It is inserted inside to be integrally structured. Of course, one refrigerant pipe 20a is connected to the beginning of the refrigerant passage 36 above the cooling rod 34 and the other refrigerant tube 20b is the end of the cold internal passage 36 below the cooling rod 34. It is of course connected to the part.

On the other hand, the cold / hot water purifier of the present invention, in which the coolant pipes 20a and 20b are evenly disposed on the space of the cold water tank 10 via the cooling plate 34, removes purified water from the direct line. Even if it is directly introduced into the cold water tank 10 without temporarily storing it in a separate water tank, within a short time by the refrigerant circulating through the refrigerant pipes 20a and 20b evenly distributed throughout the space of the cold water tank 10. Not only can be rapidly cooled, the overall level of cooling can be achieved without discriminating the vertical space of the cold water tank (10).

As described above, the cold / hot water purifier having the multi-uniform rapid cooling function according to the present invention has a coolant tube through which cool refrigerant is circulated evenly in the entire space inside the cold water tank, so that the purified water of the cold water tank is vertically in the center of the cold water tank. Cooling rods, of course, can be structurally multi-faceted by the horizontal cooling plates of the entire cold water tank and rapidly cooled within a short time.

As a result, even though the water from the direct water line is purified and flowed into the cold water tank without having to be stored in a separate water tank, it is possible to maintain a constant temperature within a short time continuously by a refrigerant that circulates in a refrigerant pipe that is extended in length and extends as a whole. Rapid cooling is possible. This can not only utilize the unnecessary space of the reservoir as a cold water tank space, but also has the effect of dramatically increasing the power saving efficiency.

1A and 1B are schematic diagrams of uniformly rapid cooling of purified water in a cold water tank while the refrigerant is circulated through the entire cooling plate in the horizontal direction and the vertical cooling rod in the form of a refrigerant-free tube in the vertical direction. Cold and hot water purifier structure diagram.

2A and 2B are schematic schematic diagrams of cold water purifiers in which a conventional refrigerant pipe through which a refrigerant is circulated is wound on an outer side of a cold water tank and configured inside an endothermic cylinder of the cold water tank;

※ Explanation of code about main part of drawing ※

10: cold water tank 20a, 20b: refrigerant pipe

30: cooling plate 32: cooling body

34: cooling rod 36: refrigerant flow path

Claims (3)

In the cold / hot water purifier, in which the purified water in the cold water tank 10 is cooled through heat exchange with the refrigerant in the refrigerant pipes 20a and 20b, The refrigerant pipe 20a through which the refrigerant is circulated is continuously disposed along the upper side or the lower side of the cooling plate 30 integrally formed in a multi-layer with respect to the cooling body 32 in the center of the cold water tank 10 to form a refrigerant-free pipe structure. It is connected to the upper side of the cooling body 32 through which the refrigerant can pass through the refrigerant passage 36 therein, the lower side of the cooling body 32 is connected to the refrigerant pipe 20b through which the refrigerant is circulated again. And the refrigerant is circulated through the refrigerant pipes 20a and 20b extended along the cooling body 32 and the cooling plate 34 to be in direct contact with water in the cold water tank 10. Cold and hot water purifier with multi-faceted uniform rapid cooling function. The method of claim 1, The refrigerant pipe 20a, 20b is a multi-sided uniform, characterized in that extended to different spaces in the upper or lower side of the cooling plate 30 and the space of the cold water tank 10 between the cooling plate 30, respectively. Cold and hot water purifier with rapid cooling function. The method of claim 1, The coolant 32 is a refrigerant through which a coolant passes through an outer side of a cooling rod 34 coupled therein such that a coolant flowing through one coolant pipe 20a can be circulated to the other coolant pipe 20b. Cold and hot water purifier having a multi-uniform uniform rapid cooling function, characterized in that the flow path 36 is formed.