KR100376312B1 - a system for cold-purified water using heat transmission of ice frozen - Google Patents

Abstract

The present invention relates to a cold water purification system using ice-axis heat exchange, and more particularly, to arrange the purified water tank and the cold water tank from side to side to reduce the overall height of the water purifier and reduce the dead space, and to increase the pressure of cold and purified water flowing in and out The inlet and outlet pipes of the purified water tank and the inlet and outlet pipes of the cold water tank are installed at the bottom of the cold and purified water tank to extract a large amount of water, preventing the vortex of the purified water flowing from the purified water tank and mixing the purified water and cold water A baffle is installed to prevent the phenomenon, and a plurality of grooves are provided on the left and right sides of the baffle to allow cold water to flow while melting ice formed on the inner surface of the cold water tank, and the purified water is formed on the inner surface of the cold water tank. The inner diameter of the cold water tank inlet pipe is configured to be smaller than the inner diameter of the purified water tank outlet pipe so as to flow while melting ice, The inner diameter of the cold water tank outlet pipe is related to the cold / water purification system configured to be smaller than the inner diameter of the purified water tank outlet pipe so that the cold water flows while melting ice formed on the inner surface of the cold water tank.

Cold water purification system of the present invention comprises a cold water tank inlet, outlet pipe and purified water tank inlet and outlet pipes installed on the bottom of the purified water tank and cold water tank, the cold and purified water tank arranged to the left and right, the cold water Inside the tank is a cold water purification system with baffles with a plurality of grooves on the left and right.

Description

Cold water purification system using ice-axis heat exchange {a system for cold-purified water using heat transmission of ice frozen}

The present invention relates to a cold water purification system using ice-axis heat exchange, and more particularly, to arrange the purified water tank and the cold water tank from side to side to reduce the overall height of the water purifier and reduce the dead space, and to increase the pressure of cold and purified water flowing in and out The inlet and outlet pipes of the purified water tank and the inlet and outlet pipes of the cold water tank are installed at the bottom of the cold and purified water tank to extract a large amount of water, to prevent the vortex of the purified water flowing from the purified water tank, and to mix the purified water and cold water. A baffle is installed to prevent the phenomenon, and a plurality of grooves are provided on the left and right sides of the baffle to allow cold water to flow while melting ice formed on the inner surface of the cold water tank, and the purified water is formed on the inner surface of the cold water tank. The inner diameter of the cold water tank inlet pipe is configured to be smaller than the inner diameter of the purified water tank outlet pipe so as to flow while melting ice, The inner diameter of the cold water tank outlet pipe is related to the cold / water purification system configured to be smaller than the inner diameter of the purified water tank outlet pipe so that the cold water flows while melting ice formed on the inner surface of the cold water tank.

1 is a schematic diagram of a conventional cold water purification system.

In the conventional cold water purification system, the general arrangement of the purified water tank 12 and the cold water tank 14 is, as shown in the figure, the hexahedral purified water tank 12 is installed on top, the cylindrical cold water tank 14 is It has a structure installed at the bottom. This is because the relatively cold water is gathered down due to the high specific gravity, the cold water tank 14 is installed below the purified water tank 12 to extract the cold water as much as possible after the cooling is completed. Another reason for placing the cold water tank 14 in the lower portion of the purified water tank 12 is to suppress the eddy current caused by excessive water flowing into the cold water tank 14 through the purified water inlet pipe 20 during cold water extraction The purpose was to extract as much cold water as possible.

However, in the structure of the conventional cold water purification system, the cylindrical cold water tank is installed at the lower part, so that the overall height of the water purifier increases, a large amount of dead space occurs, and all the cold water in the cold water tank cannot be extracted. , The problem that the cold water extraction pipe 16 freezes and a structure in which the purified water tank and the cold water tank are arranged in the market, but the vortex of the purified water flowing from the purified water tank occurs, and the purified water and cold water mixed And, there was a problem that the cold water cannot flow while melting the ice formed on the cold water surface.

The present invention has been made to solve the above problems, the first object of the present invention is to provide a cold water purification system that can reduce the constraints of the space according to the water purifier installation by reducing the total height of the water purifier to reduce the water purifier volume. It is.

A second object of the present invention is to provide a cold water purification system which can prevent the vortex of purified water flowing from the purified water tank and prevent the mixing of purified water and cold water so that the cold water can be smoothly supplied. It is to provide a cold water purification system in which cold water can flow while melting ice formed on the surface of cold water. A fourth object of the present invention is to provide a cold water purification system capable of extracting a large amount of cold water. In order to achieve the present invention, the purified water tank and the cold water tank are arranged left and right, and the present invention provides a baffle having a plurality of grooves on the left and right inside the cold water tank to achieve the second object. In order to achieve the present invention, the inner diameter of the cold water tank inlet pipe is smaller than the inner diameter of the clean water tank outlet pipe and the inner diameter of the cold water tank outlet pipe is the clean water tank outlet pipe. It was configured to be smaller than the inner diameter of, in order to achieve the fourth object, a cold water extraction tube was installed at the bottom of the cold water tank.

1 is a schematic diagram of a conventional cold water purification system.

2 is a front view of the cold water purifying system of the present invention.

3 is a perspective view showing the structure of a baffle with grooves in the cold water tank of the present invention.

<Description of Major Reference Marks in Drawings>

12: water purification tank 14: cold water tank

16: cold water extraction pipe 18: cold water extraction coke

20: purified water inlet pipe 22: cooling coil

24: baffle 26: water purification tank inlet pipe

28: water purification tank water supply pipe 30: cold water tank water supply pipe

32: cold water tank outlet 34: connector

36: baffle hole

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a schematic view of a conventional cold water purification system, FIG. 2 is a front view of a cold water purification system of the present invention, and FIG. A perspective view showing the structure of a baffle having grooves in a cold water tank. In a cold water purification system having a cold water tank 14 and a purified water tank 12, the cold water purification system according to the present invention is a cold water tank inlet pipe. 30, a cold water tank 14 provided with a cold water tank discharge pipe 32, and a purified water tank 12 provided with a purified water tank inlet pipe 26 and a purified water tank discharge pipe 28, wherein the purified water tank 12 and the cold water tank 14 are arranged side to side to reduce the overall height of the water purifier and reduce the dead space, the cold water tank inlet pipe 30, the cold water tank outlet pipe 32 and the purified water tank inlet pipe 26 Water tank (28) is to increase the pressure of cold and purified water flowing in and out It is installed at the bottom of the cold water tank 14 and the purified water tank 12 so as to extract a large amount of water, and inside the cold water tank 14 to prevent the vortex of the purified water flowing from the purified water tank 12, A baffle 24 is installed to prevent mixing of cold water, and a plurality of grooves 36 are installed on the left and right sides of the baffle 24 so that cold water flows while melting ice formed on the inner surface of the cold water tank 14. The cold water tank inlet pipe 30 is installed at the end of the cold water tank 14 in order to lower the temperature of the purified water flowing into the cold water tank 14, and the cold water tank inlet pipe ( The inner diameter of 30 is configured to be smaller than the inner diameter of the purified water tank outlet pipe 28 so that the purified water is introduced while melting the ice formed on the inner surface of the cold water tank 14, the cold water tank outlet pipe 32 Is the temperature of the cold water extracted from the cold water tank (14) It is installed at the end of the cold water tank 14 on the opposite side of the inlet pipe to lower the, and the inner diameter of the cold water tank outlet pipe 32 is leaked while the cold water is discharged while melting the ice formed on the inner surface of the cold water tank 14 It is characterized in that it is configured to be smaller than the inner diameter of the purified water tank outlet pipe 28. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a front view of the cold water purification system of the present invention. As shown, the cold water purification system of the present invention supplies purified water to the cold water tank 14 and the cold water tank 14 wound by the cooling coil 22. The purified water tanks 12 are arranged side to side. However, if the cold water tank 14 and the purified water tank 12 are arranged only in left and right arrangements, a vortex phenomenon occurs when the purified water is introduced at a relatively high temperature during cold water extraction, resulting in mixing of cold water and purified water. Due to the rise in cold water temperature occurs a problem that can not extract the entire amount of cold water. Therefore, the baffle 24 is inserted into the cold water tank 14 to suppress the eddy current caused by the inflow of purified water during cold water extraction, and to prevent the mixing of the cold water and the purified water to prevent the temperature rise of the cold water due to the inflow of purified water. It was configured to smoothly extract the total amount of cold water. The number of the baffles 24 is determined in consideration of the number of the cold water tank 14, in the general water purifier 2 to 3 will be suitable.

The water purification tank inlet pipe 26, the water outlet pipe 28, the cold water tank inlet pipe 30, and the water outlet pipe 32 are provided at the bottom of the cold and purified water tanks 14 and 12. This is to increase the pressure of cold and purified water flowing in and out, and to extract a large amount of cold water.

On the other hand, the cold water tank inlet pipe 30 is installed at the end of the cold water tank 14 so as to lower the temperature of the purified water flowing into the cold water tank 14 and the temperature of the cold water extracted from the cold water tank 14. The cold water tank outlet pipe 32 is installed at the end of the cold water tank 14 opposite to the cold water tank inlet pipe 30. The farther the cold water tank inlet pipe 30 into which the purified water flows in and the cold water tank outlet pipe 32 through which the cold water flows out, the higher the purified water is extracted along the cold water tank outlet pipe 32. This is because the user can extract enough cold water.

In addition, the inner diameter of the cold water tank inlet pipe 30 is smaller than the inner diameter of the purified water tank outlet pipe 28. This is to reduce the temperature of the purified water by allowing the purified water flowing into the cold water tank 14 to be injected into the spray type to melt the ice formed on the inner surface of the cold water tank 14 by the ejection pressure. In addition, the inner diameter of the cold water tank outlet pipe 32 is also smaller than the inner diameter of the purified water tank outlet pipe 28, which is sprayed by the ejection pressure of cold water discharged through the cold water tank outlet pipe 32. This is to allow the ice formed on the inner surface of the cold water tank 14 to flow out while melting.

In addition, a large amount of cold water is iced on the inner surface of the tank to shorten the cold water restart time and to supply cooler cold water. When the user extracts a certain amount of cold water, purified water flows back into the cold water tank 14 from the purified water tank 12. Accordingly, when the temperature of the cold water tank 14 rises, the cooling system operates to operate the cold water tank 14. Cool. At this time, the ice-cold ice can shorten the restart time of a cooling system.

3 is a perspective view showing the structure of the baffle 24 having the groove 36 in the cold water tank 14 of the present invention.

As shown, cold water flows through the grooves 36 of the baffle 24 in the cold water tank 14. The grooves 36 of the baffle 24 are formed at the edge of the baffle 24 so as to flow while melting the ice on the inner surface of the cold water tank 14. Therefore, since cold water flows while melting ice formed on the inner surface of the cold water tank 14, it is possible to supply colder cold water. In addition, the cold water tank 14 may be configured to have an oval cross section as shown, but is not limited thereto. The configuration of the elliptical cross section is advantageous to install the baffle 24, to better prevent the vortex of the purified water flowing from the purified water tank 12, and to better prevent the mixing of purified water and cold water. To do this.

According to the cold water purifying system of the present invention, since the cold water tank and the purified water tank are arranged to the left and right, the overall height of the conventional water purifier in which the cold water tank and the purified water tank are disposed up and down is reduced, thereby reducing the constraint of space due to the installation of the water purifier. And the dead space is reduced, thereby reducing the volume of the overall water purifier.

In addition, since the baffle is provided inside the cold water tank, it is possible to prevent the vortex phenomenon caused by the introduction of a relatively high temperature of purified water, and to prevent the mixing phenomenon of the cold water and the purified water to smoothly supply cold water.

In addition, the inner diameter of the cold water tank inlet pipe is made smaller than the inner diameter of the purified water tank outlet pipe and the inner diameter of the cold water tank outlet pipe is smaller than the inner diameter of the purified water tank outlet pipe to melt the ice formed on the surface of the cold water It is to provide a cold water purification system that can flow. In addition, the cold water extraction pipe is installed on the bottom of the cold water tank also has the advantage of extracting a large amount of cold water.

Claims (4)

delete In a cold water purification system equipped with a cold water tank and a purified water tank, Cold water tank inlet (30), cold water tank outlet pipe 32, the cold water tank (14) and the purified water tank inlet pipe (26), water purification tank (28) is provided, including the purified water tank (12). The water purification tank 12 and the cold water tank 14 are arranged side to side to reduce the overall height of the water purifier and reduce dead space, and the cold water tank inlet pipe 30 and the cold water tank outlet pipe 32 and the purified water are The tank inlet pipe 26 and the purified water tank outlet pipe 28 are respectively installed at the bottom of the cold water tank 14 and the purified water tank 12 to increase the pressure of cold and purified water flowing out and extract a large amount of cold water. Baffles 24 are installed inside the tank 14 to prevent vortex of purified water flowing from the purified water tank 12 and to prevent mixing of purified water and cold water, and cold water is provided on the left and right sides of the baffle 24. A plurality of grooves for melting the ice formed on the inner surface of the tank 14 to allow cold water to flow. Cooling water purifying system, characterized in that 36) is installed. According to claim 1, wherein the cold water tank inlet pipe 30 is installed at the end of the cold water tank 14 in order to lower the temperature of the purified water flowing into the cold water tank 14, the cold water tank inlet pipe (30) The inner diameter of the) is cold water purification system, characterized in that the purified water is smaller than the inner diameter of the purified water tank outlet pipe 28 so as to flow while melting the ice formed on the inner surface of the cold water tank (14). According to claim 1, wherein the cold water tank outlet pipe 32 is installed at the end of the cold water tank 14 opposite to the inlet pipe to lower the temperature of the cold water extracted from the cold water tank 14, the cold water tank output water The inner diameter of the pipe 32 is cold water purification system, characterized in that smaller than the inner diameter of the purified water tank outflow pipe 28 so that the cold water flowing out to melt the ice formed on the inner surface of the cold water tank (14) .