KR20230050283A - Cooling module for water purifier - Google Patents

Abstract

The present invention relates to a cooling module using ice storage. The cooling module for a water purifier according to the present invention comprises: a main body for accommodating a heat transfer medium; a lid coupled to an upper end of the main body to seal the main body; and a refrigerant pipe, which discharges cold to the heat transfer medium while enabling refrigerant to flow, extending in a coil shape along the inner wall of the main body; a cold water pipe, which receives cold from the heat transfer medium while enabling water to flow, extending in a coil shape having a radius of rotation smaller than the refrigerant pipe, and arranged inside the refrigerant pipe; a rotational axis extending downward from the side of the lid through the inner side of the cold water pipe; a first propeller coupled to the lower end of the rotational axis; and a second propeller coupled to a higher side of the rotational axis than the first propeller. Therefore, provided is a cooling module for a water purifier capable of churning a heat transfer medium effectively in a limited space.

Description

Cooling module for water purifier {COOLING MODULE FOR WATER PURIFIER}

The present invention relates to a cooling module for a water purifier, and more particularly to an ice storage type cooling module.

An ice storage cooling module often includes a tank accommodating a heat transfer medium, a refrigerant pipe disposed inside the tank to discharge cold air into the heat transfer medium, and a cold water pipe disposed together inside the tank to receive cold air from the heat transfer medium. As a result, the water is cooled while flowing along the cold water pipe, and is provided to the user as cold water.

At this time, the heat transfer action may be promoted by further including an impeller to stir the heat transfer medium. In general, the larger the propeller is, the more advantageous it is to improve the agitation effect, but in reality, the inner space of the tank is limited to some extent, so the propeller cannot be made large.

Therefore, it is necessary to design an impeller to effectively agitate the heat transfer medium in a limited space.

In order to solve the above problem, an object of the present invention is to provide a cooling module for a water purifier capable of effectively stirring a heat transfer medium in a limited space.

A cooling module for a water purifier according to the present invention includes a main body accommodating a heat transfer medium, a lid coupled to an upper end of the main body to seal the main body, and discharging cool air to the heat transfer medium while a refrigerant flows. A refrigerant pipe extending in a coil shape along which water flows and receiving cold air from the heat transfer medium while extending in a coil shape having a smaller radius of rotation than the refrigerant pipe and disposed inside the refrigerant pipe, a cold water pipe, A rotation shaft extending downward from the side of the lid through the inside of the cold water pipe, a first propeller coupled to a lower end of the rotation shaft, and a second propeller coupled to an upper side of the rotation shaft than the first propeller It may include.

In addition, the first propeller may be located at a height corresponding to 1/3 to 1/2 of the water level of the heat transfer medium from the bottom of the tank.

Also, the second propeller may be located at least 30 mm below the surface of the heat transfer medium.

Also, an area of a wing of the second propeller may be smaller than an area of a wing of the first propeller.

Also, the number of wings of the second propeller may be less than the number of wings of the first propeller.

In addition, the first propeller and the second propeller may be formed to force the heat transfer medium to flow in the same direction during rotation.

In the cooling module for a water purifier according to the present invention, since the impeller is composed of dual propellers, the heat transfer medium can be more effectively stirred in a limited space.

1 is a cross-sectional view of a cooling module for a water purifier according to an embodiment of the present invention.
2 is a perspective view of an impeller of a cooling module for a water purifier according to an embodiment of the present invention.
3 is a graph showing a result of measuring noise according to a position of a second propeller in an impeller of a cooling module for a water purifier according to an embodiment of the present invention.

A cooling module 100 for a water purifier according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a cross-sectional view of a cooling module 100 for a water purifier according to an embodiment of the present invention, and FIG. 2 is a perspective view of an impeller 140 of the cooling module 100 for a water purifier according to an embodiment of the present invention.

3 is a graph showing the result of measuring noise according to the position of the second propeller 143 in the impeller 140 of the cooling module 100 for a water purifier according to an embodiment of the present invention.

First, referring to FIG. 1 , the cooling module 100 for a water purifier includes a tank 110 , a refrigerant pipe 120 , a cold water pipe 130 , an impeller 140 and a net.

The tank 110 consists of a body 111 and a lid 112.

The main body 111 is generally formed in a rectangular parallelepiped shape, a cylindrical shape, or the like, and may accommodate a heat transfer medium, for example, water.

The lid 112 is detachably coupled to the top of the body 111 to seal the body 111. The lid 112 includes a sensor (not shown) for measuring the temperature of the heat transfer medium, a motor M for driving the impeller 140 to be described later, and a Printed Circuit Board (PCB) for controlling the operation of the motor M. ) (not shown) and the like may be installed.

The refrigerant pipe 120 is a part corresponding to an evaporator in a refrigeration cycle consisting of a compressor, a condenser, a capillary tube (or a throttling valve), and an evaporator, and is installed inside the main body 111 and is immersed in a heat transfer medium. Therefore, while the refrigerant flows through the refrigerant pipe 120 , cool air may be discharged to the heat transfer medium of the main body 111 .

In addition, the refrigerant pipe 120 extends in a coil or spiral shape along the inner wall of the main body 111 to more effectively discharge cold air to the heat transfer medium by increasing the contact area with the heat transfer medium. However, since the cross-sectional area, radius of rotation, pitch, number of revolutions, etc. of the refrigerant pipe 120 may vary depending on individual design conditions of the cooling module 100 for a water purifier, they will not be specifically specified herein.

The cold water pipe 130 is also installed inside the body 111 and is immersed in the heat transfer medium. Therefore, while the water flows through the cold water pipe 130, it receives cold air from the refrigerant pipe 120 from the heat transfer medium and is cooled to become cold water, which can be supplied to the user.

The cold water pipe 130 likewise extends in a coil or spiral shape to more effectively receive cold air from the heat transfer medium by increasing the contact area with the heat transfer medium, and extends in a coil shape having a smaller radius of rotation than the refrigerant pipe 120 to receive cold air from the heat transfer medium. It can be concentrically arranged on the inside of (120). However, since the cross-sectional area, radius of rotation, pitch, and number of revolutions of the cold water pipe 130 may also vary depending on individual design conditions of the cooling module 100 for a water purifier, they will not be specifically specified herein.

Of course, the cold water pipe 130 extends in a coil shape along the inner wall of the main body 111, and the refrigerant pipe 120 extends in a coil shape having a smaller radius of rotation than that and is concentrically disposed inside the cold water pipe 130. It could be.

However, for convenience of understanding, a case in which the cold water pipe 130 is disposed inside the refrigerant pipe 120 will be described as shown in the drawing.

The impeller 140 serves to promote the heat transfer action by stirring the heat transfer medium. To this end, the impeller 140 includes a rotating shaft 141 and a propeller.

The rotating shaft 141 is coupled to the motor M and extends straight downward through the inside of the cold water pipe 130 . At this time, the rotating shaft 141 may be concentrically arranged in the cold water pipe 130 to evenly stir the heat transfer medium as a whole.

The propeller is coupled to the rotating shaft 141, and generally the larger the propeller is, the more advantageous it is to improve the stirring effect. However, since the internal space of the main body 111 is limited in reality, the propeller will not be able to be formed as large as it is. Accordingly, the impeller 140 of the cooling module 100 for a water purifier is composed of a double propeller, that is, a first propeller 142 and a second propeller 143.

More specifically, the first propeller 142 is coupled to the lower end of the rotating shaft 141 .

Also, the second propeller 143 is coupled to an upper side than the first propeller 142 of the rotating shaft 141 .

As a result, the first propeller 142 and the second propeller 143 rotate simultaneously, so that the first propeller 142 mainly stirs the lower region of the heat transfer medium and the second propeller 143 mainly stirs the upper region of the heat transfer medium. By doing so, it is possible to effectively stir the heat transfer medium as a whole.

In particular, the first propeller 142 may be located at a height (H1) corresponding to 1/3 to 1/2 of the water level (H) of the heat transfer medium from the bottom of the main body 111.

In general, it is known that the optimal agitation effect can be obtained when the propeller is positioned at a height corresponding to 1/6 to 1/3 of the water level from the theoretical bottom, and the agitation effect is reduced when the propeller is positioned higher than that.

However, since the impeller 140 of the cooling module 100 for a water purifier is composed of dual propellers, as mentioned above, the first propeller 142 is 1/1 of the water level H of the heat transfer medium from the bottom of the main body 111. Higher than 6 to 1/3, that is, even if located at a height corresponding to 1/3 to 1/2 (H ₁ ), it is possible to ensure a stirring effect of a certain level or more.

Here, the fact that the first propeller 142 is located higher from the bottom of the main body 111 means that the rotating shaft 141 can be formed as short as that. As the rotating shaft 141 is formed longer, the possibility of eccentricity from the motor M increases and the degree of vibration generated during rotation may increase. Therefore, there is a problem that noise may increase and durability of the motor M and related parts may deteriorate. However, if the rotating shaft 141 can be formed short, there is an advantage in preventing the above problem as much as possible.

Meanwhile, the second propeller 143 may be located at least about 30 mm below the surface of the heat transfer medium (H ₂ ).

If the second propeller 143 is located higher than that, for example, if it is located about 10 mm below the water surface of the heat transfer medium, as shown in FIG.

Furthermore, in order to further reduce the fluctuation of the water surface, the area of the wing of the second propeller 143 may be smaller than that of the wing of the first propeller 142 .

Also, the number of wings of the second propeller 143 may be less than that of the first propeller 142 . In the drawing, the number of wings of the first propeller 142 is four, and the number of wings of the second propeller 143 is illustrated as two.

Moreover, in the drawing, the first propeller 142 and the second propeller 143 are illustrated as being formed to force the heat transfer medium to flow downward when rotating clockwise. However, if necessary, all of the heat transfer media may be forced to flow upward.

Alternatively, it may be formed to force the heat transfer medium to flow in different directions. For example, the first propeller 142 may force the heat transfer medium to flow upward and the second propeller 143 may force the heat transfer medium to flow downward.

The net 150 is disposed between the cold water pipe 130 and the impeller 140 and surrounds the impeller 140 .

The net 150 allows the heat transfer medium to pass through, but serves to block the ice from passing to the impeller 140 when ice is generated. Therefore, it is possible to prevent noise or damage to the impeller 140 caused by ice colliding with the impeller 140 .

The embodiments of the present invention described above and shown in the drawings do not limit the technical idea of the present invention. The protection scope of the present invention is determined by the matters described in the claims. On the other hand, those skilled in the art will be able to variously improve or change the technical spirit of the present invention. Such improvement or change falls within the protection scope of the present invention as long as it is obvious to a person skilled in the art.

Claims (7)

In the water purifier including a cooling module for the water purifier,
The cooling module for the water purifier,
a body accommodating a heat transfer medium;
A lid coupled to the top of the body to seal the body;
A refrigerant pipe extending in a coil shape along an inner wall of the main body for discharging cool air to the heat transfer medium while the refrigerant flows;
A cold water pipe extending in a coil shape having a smaller radius of rotation than the refrigerant pipe and disposed inside the refrigerant pipe to receive cool air from the heat transfer medium while the water flows;
A rotation shaft extending downward from the lid side through the inside of the cold water pipe;
A first propeller coupled to the lower end of the rotating shaft and
Including a second propeller coupled to an upper side of the rotation shaft than the first propeller,
The area of the blades of the second propeller is smaller than the area of the blades of the first propeller, or the number of blades of the second propeller is smaller than the number of blades of the first propeller. a body accommodating a heat transfer medium;
A lid coupled to the top of the body to seal the body;
A refrigerant pipe installed inside the main body for discharging cool air to the heat transfer medium while the refrigerant flows;
A cold water pipe installed inside the main body for receiving cold air from the heat transfer medium while the water flows,
A rotation shaft extending downward from the lid side through the inside of the cold water pipe;
A first propeller coupled to the lower end of the rotating shaft and
Including a second propeller coupled to an upper side of the rotation shaft than the first propeller,
The second propeller is a cooling module for a water purifier positioned at least 30 mm below the surface of the heat transfer medium. According to claim 2,
The first propeller is located at a height corresponding to 1/3 to 1/2 of the water level of the heat transfer medium from the bottom of the main body. According to claim 2,
The cooling module for a water purifier, wherein the first propeller and the second propeller are configured to force the heat transfer medium to flow in the same direction when rotating. According to claim 2,
The cooling module for a water purifier wherein the cold water pipe is disposed inside the refrigerant pipe. According to claim 2,
The cooling module for a water purifier, wherein the refrigerant pipe is disposed inside the cold water pipe. A water purifier comprising the cooling module for a water purifier according to any one of claims 2 to 6.

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