KR20190096563A - Water purifying apparatus - Google Patents

Abstract

A water purifier according to an embodiment of the present invention comprises: a cooling water tank; a tank cover covering the cooling water tank; and a gasket placed at a portion where the cooling water tank and the tank cover are coupled to each other to prevent leakage of the cooling water. The gasket comprises: a head portion seated on an upper end of the cooling water tank; an outer extension end extending from an outer edge of a bottom surface of the head portion and in contact with an outer surface of the cooling water tank; and an inner extension end extending from an inner edge of the bottom surface of the head portion and in contact with an inner surface of the cooling water tank. A part of the gasket is placed inside the cooling water tank, and the other part is placed outside the cooling water tank. Insulation performance is enhanced by increasing the thickness of an insulating case portion covering the gasket.

Description

Water purifier

The present invention relates to a water purifier.

Water purifiers are devices that filter harmful substances such as foreign substances or heavy metals in water by physical and / or chemical methods.

The prior art below discloses what is called a direct water purifier. The direct water purifier means a water purifier in which a water tank is not required separately, and when a water supply button is pressed, water supplied through a faucet is cooled to a set temperature while passing through a cooling unit and is directly supplied to a consumer.

In the case of a direct type water purifier, since there is no need for a reservoir, foreign matters accumulate on the bottom of the reservoir and there is no problem that bacteria grow in the reservoir.

1 is a longitudinal sectional view showing a coupling structure of a cooling water tank and a tank cover constituting a conventional direct type water purifier.

Referring to FIG. 1, a conventional direct type water purifier includes a cooling water tank 2 in which cooling water is stored, an insulating case 1 surrounded by an outer circumferential surface of the cooling water tank, and an upper surface of the cooling water tank 2. It may include a tank cover (3) to be seated, and a gasket (4) seated at a coupling portion of the cold cover (3) and the coolant tank (2) to prevent leakage. In addition, the cooling parts disclosed in the prior art are accommodated in the cooling water tank 2, a stirring motor is seated on an upper surface of the tank cover 3, and a motor extending to the bottom surface of the cold cover 3. The stirring member is connected to the shaft.

A space in which the gasket 4 is seated is formed at an upper end of the coolant tank 2, and the outer diameter of the coolant tank 2 is increased as much as the space in which the gasket 4 is seated.

As a result, the thickness of the heat insulating case 1 at the portion where the gasket 4 is seated becomes thinner than other portions, resulting in a problem that heat loss is inevitably generated. Furthermore, there arises a problem of increased power consumption due to adiabatic loss, and a problem of condensation occurring at a portion where adiabatic loss occurs.

Korean Laid-Open Patent Publication No. 2017-0024969 (March 08, 2017)

The present invention is proposed to improve the above problems.

Purifier according to an embodiment of the present invention for achieving the above object, the tank cover covering the cooling water tank and the cooling water tank, and the gasket for preventing the leakage of the cooling water is placed on the portion where the cooling water tank and the tank cover is coupled The gasket includes: a head portion seated on an upper end of the cooling water tank, an outer extension end extending from an outer edge of the bottom surface of the head portion, and an outer extension end contacting an outer surface of the cooling water tank; And an inner extension end in contact with an inner surface of the coolant tank, wherein a part of the gasket is placed inside the coolant tank, and another part is placed outside the coolant tank.

According to the water purifier according to the embodiment of the present invention constituting the above configuration has the following effects.

First, a part of the gasket provided between the coolant tank and the tank cover is in contact with the outer surface of the coolant tank, and the remaining part is in contact with the inner surface of the coolant tank, so that the volume of the gasket accommodating portion is reduced, the insulating case portion covering the gasket Increasing the thickness of the thermal insulation performance is improved.

Second, since the size of the gasket receiving portion is reduced, there is an advantage that the size of the cooling unit can be compactly designed without reducing the cooling water storage volume.

Third, since the thickness of the heat insulation case formed on the outer side of the gasket accommodating portion is increased, heat insulation loss is reduced, thereby reducing power consumption.

Fourth, since the heat insulation case thickness increases around the gasket accommodating portion, heat insulation loss is reduced, thereby minimizing the possibility of condensation occurring around the gasket.

1 is a longitudinal sectional view showing a coupling structure of a cooling water tank and a tank cover constituting a conventional direct type water purifier.
2 is a longitudinal sectional view of a cooling unit constituting a water purifier according to an embodiment of the present invention.
Figure 3 is a partially cut perspective view showing the structure of the gasket according to the embodiment of the present invention.
Figure 4 is a view showing a comparison of the insulating case thickness of the cooling water tank is equipped with a conventional gasket and the cooling water tank is equipped with a gasket according to an embodiment of the present invention.

Hereinafter, a water purifier to which a gasket according to an embodiment of the present invention is applied will be described in detail with reference to the accompanying drawings.

2 is a longitudinal sectional view of a cooling unit constituting the water purifier according to the embodiment of the present invention.

2, since the water purifier to which the cooling unit 10 according to the embodiment of the present invention is mounted is the same as the direct type water purifier disclosed in the prior art, a description of the structure other than the cooling unit 10 will be omitted. do.

In detail, the cooling unit 10 provided with the gasket according to the embodiment of the present invention includes a cooling water tank 13 in which cooling water is stored, an insulating case 11 surrounding the outer circumferential surface of the cooling water tank 13, A drain valve 12 mounted at an inner lower end of the insulation case 11 and connected to a lower end of the coolant tank 13, a tank cover 17 covering an opened upper surface of the coolant tank 13, and It may include a gasket 20 seated on the upper end of the coolant tank 13 and pressed by the tank cover 17.

The gasket 20 is interposed between the tank cover 17 and the cooling water tank 13 and pressurized by the tank cover 17 so that the cooling water stored in the cooling water tank 13 leaks to the outside. Can be prevented.

In addition, the cooling unit 10 includes a partition member 16 placed inside the cooling water tank 13, an evaporator 15 placed above the partition member 16, and the partition member 16. Cold water pipe 14 placed on the lower side, a stirring motor 18 placed on the upper surface of the tank cover 17, and through the tank cover 17 from the stirring motor 18, inside the cooling water tank 13 It may further include a motor shaft extending to, and a stirring member 19 connected to the motor shaft.

The evaporator 15 is installed to cool the coolant stored in the coolant tank 13 to a set temperature. The cooling water stored in the cooling water tank 13 exchanges heat with the drinking water flowing along the cold water pipe 14 to cool the drinking water to a predetermined temperature.

In addition, the stirring member 19 agitates the cooling water in the cooling water tank 13 so that the cooling water on the upper side of the cold air partition member 16 and the cooling water on the lower side of the partition member 16 exchange heat with the cooling water. That is, the cooling water having a temperature lowered by heat exchange with the evaporator 15 moves to the lower space of the cooling water tank 13 so that the cooling water in the cooling water tank 13 is maintained at a uniform temperature.

Meanwhile, a gasket accommodating part 134 is formed in an outer space of the cooling water tank 13 to accommodate a part of the gasket 20, and the gasket accommodating part 134 is formed on an outer circumferential surface of the cooling water tank 13. It is formed by an extending cover support rib 131. The cover support rib 131 is encircled in the circumferential direction on the outer circumferential surface of the cooling water tank 13.

In detail, the cover support rib 131 may include a first extension part 132 extending in a radial direction of the coolant tank 13 at a point spaced a predetermined distance downward from an upper end of the coolant tank 13, and And a second extension part 132 extending from the end of the first extension part 132 in the direction intersecting with the first extension part 132 (upward direction of the coolant tank). The horizontal width of the gasket accommodating part 134 corresponds to the length of the first extension part 132, and the height of the gasket accommodating part 134 is from the first extension part 132 to the cooling water tank 13. It can be defined as corresponding to the length up to the top of).

Since the cover support rib 131 is injection molded into the body with the cooling water tank 13, it can be seen as a part of the cooling water tank 13, and in this embodiment, the upper end of the cooling water tank 13 It is defined for convenience as a part where the head part (to be described later) of the gasket 20 is seated, not the upper end of the second extension part 133. In addition, an upper end of the second extension part 133 may extend to an upper point of the upper end of the cooling water tank 13 and the upper surface of the gasket 20 to prevent the gasket 20 from being exposed to the outside. have.

In addition, the bottom surface of the outer edge of the tank cover 17 is seated on the second extension 133, the rotation axis of the stirring motor 18 passes through the center of the bottom portion 171 of the tank cover 17. .

In addition, the tank cover 17 may include a side portion 174 extending upward from an edge of the bottom portion 171, and a stepped portion extending from an upper end of the side portion 174 to an outer side (a radial direction of the tank cover) ( 172). In addition, after the side portion is further extended from the stepped portion 172 to the upper side, it may be bent and seated on the second extension portion 133. That is, the side portion 174 that extends upward from the edge of the bottom portion 171 may be defined as a first side portion, and the side portion that is extended upward from the stepped portion 172 is defined as a second side portion. In addition, a portion bent from the second side portion to the outside (radial direction of the tank cover 17) may be defined as a second stepped portion. The bottom surface of the second stepped part is seated on an upper end of the second extension part 133.

In addition, a pressure rib 173 (or a sealing rib) may be extended to the bottom surface of the stepped portion 172 to press the upper surface of the gasket 20. When the upper surface of the gasket 20 is pressed, the gas 20 may be deformed to closely contact the side surface of the tank cover 17 and the inner surface of the second extension 133 to improve the sealing function.

3 is a partial cutaway perspective view showing a structure of a gasket according to an embodiment of the present invention.

Referring to FIG. 3, the gasket 20 according to the exemplary embodiment of the present invention is seated on an upper end of the coolant tank 13, and is formed of a closed annular strip along an upper end of the coolant tank 13.

In detail, the gasket 20 includes a head portion 21, an outer extension end 23 extending downward from an outer edge of a bottom portion of the head portion, and an inner extension extending from an inner edge of the head portion 21. And stage 24. In addition, a hollow portion 22 is formed inside the head portion 21.

The bottom of the head portion 21, that is, the portion except the outer extension end 23 and the inner extension end 24 is seated on the upper end of the coolant tank 13. The width and length of the gasket accommodating part 134 correspond to the thickness and length of the outer extension end 23.

In addition, the outer circumferential surface of the inner extension end 24 contacts the inner surface of the coolant tank 13, and the inner circumferential surface contacts the side portion 174 of the tank cover 17. In addition, an end portion of the inner extension end 24 may extend slightly lower than the lower end of the side portion 174 or may extend to the same length as the lower end of the side portion 174. If the length of the inner extension end 24 is too long, a portion that is not contacted by the side portion 174 of the tank cover 17 may be rolled up phenomenon.

In addition, since the outer extension end 23 is formed longer than the inner extension end, the outer extension end 23 can be stably received in the gasket accommodating part 134. In addition, the gasket 20 may be prevented from being separated from the gasket accommodating part 134 by the friction force during the coupling process of the tank cover 17.

In addition, the thickness of the inner extension end 24 is preferably formed to be thinner than the thickness of the outer extension end (23). If the inner extension end 24 is too thick, there is a problem that the assembly is not easy because excessive force is applied to the tank cover 17.

In addition, the head portion 21 may have a rectangular cross-sectional shape by the hollow portion 22, and may be formed of an upper portion and a lower portion, and an outer portion and an inner portion, and the thickness T1 of the upper portion may be a thickness T2 of the lower portion. It may be formed thinner than).

In detail, the upper portion is pressurized by the pressurizing rib 174, so that the gap between the tank cover 17 and the cooling water tank 13 must be completely filled, so that a relatively thin thickness is formed so as to have high ductility.

On the contrary, the lower portion needs to be formed thicker than the upper portion, so that the upper end portion of the cooling water tank 13 is easily inserted between the outer extension end 23 and the inner extension end 24 in the mounting process. If the thickness of the lower part is thin and the ductility is high, it may be difficult for the inner extension end 24 and the outer extension end 23 to stick together, so that the upper end of the coolant tank 13 may be seated on the bottom of the head part 21. .

Figure 4 is a view showing a comparison of the thickness of the insulating case of the cooling water tank is equipped with a conventional gasket and the cooling water tank is equipped with a gasket according to an embodiment of the present invention.

Referring to FIG. 4, an upper cross sectional view is an enlarged view of portion A of FIG. 1, and a lower cross sectional view is an enlarged view of portion B of FIG. 2.

First, the inner diameter (D1) and the outer diameter (D2) of the cooling water tank 13 is the case of the present invention is the same as the conventional case and the case of the present invention, the outer diameter of the heat insulating case 11, the gasket accommodating part in the case of the present invention As the width of the 134 is reduced, it can be seen that the insulation thickness of the portion of the insulation case covering the gasket receiving portion 134 is reduced.

In other words, the heat insulation thickness of the part of the heat insulation case 1 which covers the gasket accommodating part of the cooling water tank 2 in which the conventional gasket 4 is mounted is W1, and the cooling water tank 13 in which the gasket 20 of the present invention is mounted. Insulation thickness of the gasket receiving portion is W2, it can be confirmed that the insulation thickness is thicker by W3 than the conventional case.

As the insulation thickness increases, the insulation loss in the vicinity of the portion where the gasket is mounted is reduced, thereby reducing the power consumption.

Claims (10)

A coolant tank in which coolant is stored;
An insulation case surrounding the cooling water tank;
An evaporator provided in the cooling water tank to cool the cooling water;
A cold water pipe provided inside the cooling water tank to exchange heat with the cooling water, and drinking water flowing therein;
A tank cover covering an opened upper surface of the cooling water tank;
A stirring motor seated on an upper surface of the tank cover;
A stirring member placed inside the cooling water tank and connected to the stirring motor to stir the cooling water;
A gasket placed at a portion at which the coolant tank and the tank cover are coupled to prevent leakage of the coolant;
The gasket,
A head part seated on an upper end of the cooling water tank;
An outer extension end extending from an outer edge of the bottom surface of the head portion and in contact with an outer surface of the cooling water tank;
And an inner extension end extending from an inner edge of a bottom surface of the head portion to be in contact with an inner surface of the cooling water tank. The method of claim 1,
The hollow portion is formed inside the head portion,
And a thickness of the head portion defining the upper surface of the hollow portion is thinner than a thickness of the head portion defining the lower surface of the hollow portion. The method according to claim 1 or 2,
And the outer extension end is formed thicker than the inner extension end. The method of claim 3, wherein
And the outer extension end is formed longer than the inner extension end. The method of claim 1,
A cover support rib extending from an outer circumferential surface of the cooling water tank to form a gasket receiving portion for receiving the outer extension end;
The cover support rib is a water purifier, characterized in that consisting of the cooling water tank and one body. The method of claim 5,
The cover support rib,
A first extension part extending in a radial direction of the cooling water tank at a point spaced apart from an upper end of the cooling water tank by a distance corresponding to the length of the outer extension end;
And a second extension portion extending from an end portion of the first extension portion to an upper side of the cooling water tank. The method of claim 6,
The first extension portion is bent upward after extending by a length corresponding to the thickness of the outer extension end,
The second extension portion further extends upwardly than an upper end of the cooling water tank,
A water purifier, characterized in that the bottom of the outer edge of the tank cover is seated on the top of the second extension. The method of claim 1,
The tank cover,
A bottom part for supporting the stirring motor,
A side portion remaining upward from the edge of the bottom portion;
A stepped portion bent in the radial direction of the tank cover at the end of the side portion, and
And a pressurizing rib extending downward from the bottom of the stepped portion to press the head portion. The method of claim 8,
An inner surface of the inner extension end is in contact with an outer surface of the side portion,
The outer surface of the inner extension end is in contact with the inner surface of the coolant tank. The method of claim 8,
The lower end of the inner extension end is formed at the same height as the lower end of the side portion, or water purifier, characterized in that it extends longer than the lower end of the lower side.

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