KR20110003731A - Ice supplier for hot and cold water supplier - Google Patents

Abstract

PURPOSE: An ice supplier for a water cooler/heater is provided to reduce noise occurred when sprayed water falls down and to make ice with a uniform-size and high-transparency. CONSTITUTION: An ice supplier for a water cooler/heater comprises an ice maker(110) and a sprayer(120). The ice maker has an ice making frame(112) and a heat exchanging pipe(114). Multiple engraving parts are formed in the ice making frame. The opened surfaces of the engraving parts are downward arranged. The heat exchanging plate is installed on the top surface of the ice making frame and cools the ice making frame. The sprayer is installed in the bottom of the ice maker and has a nozzle. The nozzle sprays water to the engraving parts of the ice making frame.

Description

Ice feeder for cold and hot water heaters {Ice supplier for hot and cold water supplier}

The present invention relates to an ice supply device for a cold / hot water machine, which is provided in a cold / hot water machine, to ice and supply ice. In particular, even when a plurality of ices are iced at the same time, the shape of each ice is uniform and the transparency is high. The present invention relates to an ice supply device for a cold / hot water machine, which reduces power consumption of an injection pump and reduces noise caused by falling of injected water.

Recently, in various living spaces such as homes and offices, the use of cold and hot water heaters to provide cold water and hot water has been increasing to solve the hassle of boiling tap water or bringing water directly. Increasingly, the use of cold and hot water machines equipped with an ice feeder to supply the water is supplied.

On the other hand, the ice supply device for cold and hot water as described above sprays the water supplied through the injection nozzle to the ice making frame for ice making a plurality of ice at the same time, and thus the water filled in the ice making frame through the heat exchange tube through which the refrigerant below the freezing point flows. It is intended to ice and supply ice by cooling.

However, in the conventional art, since water is injected into the ice tray through one spray nozzle, the distance between the spray nozzle and the ice tray has to be long, and the reaching distance between the spray nozzle and each part of the ice tray is different. There was a problem that the shape of the ice ice is not uniform, as well as the transparency of the ice is low.

In addition, since the spray angle of the water sprayed from the spray nozzle to each part of the ice making machine is large, most of the water falls to the bottom surface without freezing from the ice making machine. There was a problem that the efficiency of the injection pump is not good.

The present invention solves the problems as described above, even when the ice is iced at the same time to provide a uniform and transparent ice of each ice shape, as well as to reduce the power consumption of the water supply injection pump and An object of the present invention is to provide an ice cold water supply device for reducing noise caused by falling.

To this end, the ice supply device for cold or hot water according to the present invention is provided with a plurality of engraved portions of the ice shape to be iced and is installed in contact with the ice making frame and the upper surface of the ice making frame is arranged so that the open surface of the engraved portion toward the lower side. An ice maker having a heat exchanger tube for cooling the ice tray; And an injector disposed below the ice maker and having an injection nozzle for injecting water to be supplied to the intaglio portion of the ice making machine from a lower portion to an upper portion thereof, wherein the injection nozzles are equal to the number of the indentations. It is provided with a water, wherein each of the spray nozzles is characterized in that to spray water individually to each indentation located in the upper portion.

At this time, the injector, the nozzle block having a water flow inside; A supply nozzle installed at one side of the nozzle block to communicate with the flowing water; And an injection nozzle installed on an upper surface of the nozzle block and spraying water supplied through the supply nozzle.

In addition, it is preferable that a plurality of injection holes are formed in the injection nozzle.

In addition, a heat conduction plate of a high thermal conductivity material is installed between the heat exchange tube and the ice making frame, wherein the lower surface of the heat conductive plate is in contact with the ice making frame, the upper surface of the heat conductive plate is in contact with the heat exchange tube. desirable.

The apparatus may include a slider installed to cover the upper part of the injector and discharging the ice dropped from the ice making mold, wherein the slider has a through portion formed so that water sprayed from the injector reaches the ice making mold. .

In addition, the injector is coupled to the ice maker through the rotation coupling unit is installed to be able to rotate in the downward direction, the support portion for supporting the injector, a rotating shaft rotated by the rotating motor, and one end of the rotating shaft It is preferable to include; and the other end is connected to the support arm connected to the lower portion of the injector.

In addition, the refrigerant circuit for circulating the refrigerant in the heat exchange tube, the freezing point operation mode for circulating the refrigerant having a temperature below the freezing point to make the water injected into the ice making frame iced; Non-freezing point operation mode for circulating the refrigerant of the freezing point temperature to remove and drop the ice generated in the ice making frame; It is preferred to be configured to operate in either mode.

In addition, the rotation motor is preferably driven in the non-freezing point operation mode to rotate the injector equipped with the slider to the lower side.

According to the ice supply apparatus for cold and hot water according to the present invention as described above, even if a plurality of ice is iced at the same time, the shape of each ice is uniform and provide a high transparency, as well as reducing the power consumption of the water supply injection pump It is possible to reduce noise caused by the drop of the injected water.

Hereinafter, with reference to the accompanying drawings to be described in detail for the ice supply device for cold and hot water according to an embodiment of the present invention.

1 is a perspective view showing an ice making state of the ice cold water supply apparatus according to the present invention, Figure 2 is a perspective view showing a deicing state of the ice water supply apparatus for cold and hot water according to the present invention, Figure 3 is ice for a cold water heater according to the present invention 4 is a perspective view showing an injector of an ice supply device for a cold / hot water machine according to the present invention, and FIG. 5 is a partially enlarged view showing a rotation coupling part of the ice supply device for a cold / hot water machine according to the present invention. to be.

First, as shown in FIG. 1 showing a state in which ice is iced and FIG. 2 showing a state of defrosting and supplying iced ice, the ice supply device 100 for a cold / hot water machine according to the present invention supplies water largely. Ice maker 110 for receiving and ice-making, the injector 120 is provided below the ice maker 110, the slider 130 is installed to cover the upper portion of the injector 120, the ice maker 110 and the injector It includes a rotation coupling unit 140 for connecting the 120 to each other and a support 150 for supporting the injector 120 from the bottom.

Accordingly, when water is injected and supplied from the injector 120 supplied with water through a supply hose (not shown) to the ice maker 110 disposed above, the ice maker 110 temporarily cools the water being supplied to provide ice. De-ice.

In addition, the ice-making ice is defrosted and dropped and placed on the upper portion of the slider 130, and the injector 120 installed to be rotatable through the rotation coupling unit 140 and the support unit 150 includes a rotation motor (of the support unit 150). M is rotated downward with the slider 130 to discharge and supply the ice.

In addition, the injector 120 is restored to the horizontal direction again by the rotation motor (M) of the support unit 150 after the ice is discharged to continue to spray water and ice ice.

In more detail, as shown in FIG. 3, the ice maker 110 is provided with an ice maker housing 111 and a lower portion of the ice maker housing 111 but has an ice-shaped intaglio to be iced. And an open surface of the intaglio portion is formed with an ice tray 112 disposed so as to face the lower side on which the injector 120 is installed, a heat conducting plate 113 and the heat conduction plate installed in contact with an upper surface of the ice tray 112. And a heat exchange tube 114 for transmitting cold air to the ice making frame 112 through the 113.

In addition, the ice making frame 112 includes a plurality of negative parts (for example, 4 × 4 = 16 pieces) to make a plurality of ices at once, and the thermal conductive plate 113 made of a high thermal conductivity material such as copper may be ice making. It is provided in the upper surface (especially the position corresponding to the intaglio part) of the frame 112, and the heat exchanger tube 114 is arrange | positioned so that it may contact via all the heat conductive plates 113. FIG.

Therefore, when the refrigerant having a temperature below the freezing point circulates (hereinafter, referred to as a “freezing point operation mode”) along the inside of the heat exchange tube 114, the cold air is engraved in the ice tray 112 through the heat conduction plate 113. In this case, the water sprayed into the intaglio portion from the lower injector 120 is instantaneously defrosted to grow ice particles, thereby forming ice having the same shape as the intaglio portion.

In addition, after the ice is iced as described above, if the refrigerant of the freezing temperature exceeding the freezing temperature circulates along the inside of the heat exchange tube 114 (hereinafter, referred to as 'non-freezing point operation mode'), the surface of the ice slightly melts and the ice is engraved. De-ice and fall from the portion to be supplied to the user as described below.

However, except for the technical idea that ice is made by using the non-freezing point operation mode to facilitate the supply of ice, the other refrigerant circulation circuit (not shown) may be one of freezing point operation mode or non-freezing point operation mode. It is composed of various parts such as compressor, condenser, expansion valve and evaporator so that it can be operated in the same way, and by changing the path of refrigerant circulating along them, the technology itself operates in either freezing or non-freezing operation mode. Since already known, a detailed description thereof will be omitted.

The injector 120 is installed at the lower side of the ice maker 110 and sprays water from the lower side to the upper side, thereby supplying water to the inside of the intaglio portion of the ice making machine 112, as shown in FIGS. 1 and 2. And a nozzle block 122 seated inside the injector housing 121 and having a running water space therein.

In addition, as shown in FIG. 4A, one side of the nozzle block 122 is provided with a supply nozzle 123 which communicates with the flowing water, and an injection nozzle 124 is provided on an upper surface of the nozzle block 122. In the injection nozzle 124, preferably, two injection holes are formed to allow sufficient and rapid water supply.

Further, by spraying water onto a plurality of intaglio portions (for example, sixteen) provided in the ice making frame 112, the spray nozzles can be used to reduce the water spraying distance and to make the water spraying distance to each intaglio portion equal. 124 also has the same number of spray nozzles 124 as the intaglio. That is, one spray nozzle 124 is configured to spray water 1: 1 in one intaglio portion.

Therefore, when water is supplied to the supply nozzle 123 installed on one side of the nozzle block 122 through the injection pump (not shown) and the supply hose (not shown), the supply nozzle 123 is inside the nozzle block 122. High pressure water is injected into the flowing water, and the water sprayed in this way passes through the respective injection nozzles 124 as shown in FIG. 4B (ie, the shortest distance water injection direction). Spray water on.

Therefore, compared to spraying water on all the concave portions of the ice making frame through a single spray nozzle as in the prior art, the shape of each ice is uniform, and the transparency of the ice is improved, as well as the water falling without ice making. It is possible to reduce the noise by, and to reduce the power consumption of the injection pump (not shown).

Slider 130 (slider) is that the refrigerant circulation circuit is operated in the non-ice point operation mode as described above, when the ice iced in the ice making frame 112 is defrosted and dropped, the ice is temporarily stored and then discharged to the outside. , To cover the top of the injector 120.

2, the slider 130 includes a horizontal frame 131 and a vertical frame 132 supported by the horizontal frame 131 and spaced apart from each other by a predetermined interval.

The vertical frames 132 should be spaced apart from each other because the water sprayed from the nozzle block 122 beneath it should be able to reach the ice maker 110 located above through the slider 130.

Therefore, the space between the vertical frames 132 (hereinafter referred to as a 'penetration portion') corresponds to the position where the spray nozzles 124 of the nozzle block 122 provided below the spray nozzles 124 are installed. The water sprayed from the ()) can be sprayed upward through the through between the vertical frame (132).

On the other hand, the ice maker 110 and the injector 120 described above are coupled to each other through the rotation coupling unit 140, the injector 120 is supported by a support unit 150 installed below.

This is because the injector 120 and the slider 130 are integrally rotated downward as shown in FIG. 2, so that the ice circulating ice is dropped and dropped during the operation of the refrigerant circulation circuit in the non-freezing point operation mode (not shown). To be discharged.

To this end, as can be seen through Figure 5, the rotation coupling portion 140 is fixedly coupled to the upper side of the ice maker 110, the lower side is pivotally coupled to the injector 120 by a rotating shaft or the like. Therefore, as shown in FIG. 5A, the injector 120 is kept horizontal with respect to the ice maker 110, or as shown in FIG. 5B, the injector 120 is rotatable downward.

In addition, the support unit 150 includes a rotation motor M, a rotation shaft 151 and a support arm 152. The rotation motor M is driven according to a control signal of a controller (not shown). The rotating shaft 151 is connected to the rotating motor M and rotates according to the driving of the rotating motor M. The supporting arm 152 is connected to the rotating shaft at one end and the other end of the injector 120. It is connected to support the injector 120.

At this time, the rotation motor M is a direction in which the injector 120 and the slider 130 are integrally adjusted downward at the time when the refrigerant circulation circuit operates in the non-icing point operation mode (that is, when the iced ice is defrosted and dropped). Driven by the lower limit limit switch (not shown) installed on one side of the rotation motor M to prevent the rotation motor M from being excessively driven.

In addition, after a predetermined time, the rotation motor M is driven in a direction in which the injector 120 and the slider 130 are horizontal, and an upper limit limit switch (not shown) installed on one side of the rotation motor M is shown. This prevents the rotational motor from being excessively driven.

Therefore, while the coolant circulation circuit is operating in the freezing point operation mode, the injector 120 and the slider 130 are kept in the ice state in the ice making frame 112 while keeping the horizontal, and at this time by the support unit 150 Allow injector 120 and slider 130 to be supported.

On the other hand, when the refrigerant circulation circuit is operated in the non-icing point operation mode and the ice is defrosted and dropped from the ice making frame 112, the injector 120 and the slider 130 are rotated downward by the rotating motor M, and the ice is rotated. Is discharged to the ice reservoir (not shown) while sliding along the inclined slider (130).

Furthermore, after all of the ice placed on the slider 130 is discharged as described above, the rotation motor M rotates in the opposite direction, and the injector 120 and the slider 130 integrally coupled thereon are restored horizontally again. As such, the injector 120 can continue to defrost ice by injecting water in the horizontal state.

The specific embodiments of the present invention have been described above. However, the spirit and scope of the present invention is not limited to these specific embodiments, and various modifications and variations can be made without departing from the spirit of the present invention. Those who have it will understand.

Therefore, since the embodiments described above are provided to completely inform the scope of the invention to those skilled in the art, it should be understood that they are exemplary in all respects and not limited. The invention is only defined by the scope of the claims.

The ice supply device for the cold and hot water machine of the present invention provides ice with a uniform and transparent transparency even when a plurality of ices are iced at the same time, as well as reducing the power consumption of the water supply injection pump and reducing the drop of injected water. It is possible to reduce the noise caused by. Therefore, it is possible to accelerate the technological development of the cold and hot water heater industry, and to meet the needs of the users of the hot and cold water heater.

1 is a perspective view showing the ice making state of the ice supply device for cold and hot water according to the present invention.

Figure 2 is a perspective view showing a defrosting state of the ice supply device for cold and hot water according to the present invention.

3 is an internal configuration diagram showing an ice maker of a cold / hot water ice supply device according to the present invention.

Figure 4 is a perspective view showing the injector of the ice supply device for cold and hot water according to the present invention.

Figure 5 is a partially enlarged view showing the rotational coupling portion of the ice supply device for cold and hot water according to the present invention.

<Explanation of symbols for the main parts of the drawings>

110: ice maker 111: ice maker housing

112: ice tray 113: heat conduction plate

114: heat exchanger tube 120: injector

121: injector housing 122: nozzle block

123: supply nozzle 124: spray nozzle

130: slider 140: rotation engaging portion

150: support portion 151: rotation axis

152: support arm M: rotating motor

Claims (8)

In the ice feeder provided in the cold and hot water machine, A plurality of ice-shaped intaglio portions to be iced are formed, and an ice making frame disposed so that the open surface of the intaglio portion faces downward and a heat exchange tube installed in contact with an upper surface of the ice making frame to cool the ice making frame. Ice maker; And And an injector disposed below the ice maker and having an injection nozzle for injecting water to be supplied to the intaglio portion of the ice making machine from the lower part to the upper part. The spray nozzles are provided in the same number as the number of the intaglio portion, the ice supply apparatus for cold and hot water heater, characterized in that the respective spray nozzles separately spray water to each intaglio portion located directly above. The method of claim 1, The injector, A nozzle block having a running water portion therein; A supply nozzle installed at one side of the nozzle block to communicate with the flowing water; And And an injection nozzle installed on an upper surface of the nozzle block and spraying water supplied through the supply nozzle. The method of claim 2, Ice spraying device for cold and hot water, characterized in that the injection nozzle is formed with a plurality of injection holes. The method of claim 1, And a heat conduction plate of a high thermal conductivity material installed between the heat exchange tube and the ice making frame, wherein a lower surface of the heat conduction plate is in contact with the ice making frame, and an upper surface of the heat conduction plate is in contact with the heat exchange tube. Ice feeder for cold and hot water machine. The method of claim 1, And a slider installed to cover the upper part of the injector and discharging the ice dropped from the ice making mold, wherein the slider has a through portion formed so that the water sprayed from the injector reaches the ice making mold. Ice feeder for cold and hot water machine. The method of claim 5, The injector is coupled to the ice maker through the rotation coupling unit is installed to be able to rotate in the downward direction, The support portion for supporting the injector, And a rotating motor, a rotating shaft rotated by the rotating motor, and one end of which is connected to the rotating shaft, and the other end of which is connected to the lower part of the injector. The method of claim 6, A refrigerant circuit for circulating a refrigerant in the heat exchange tube, A freezing point operation mode for circulating a refrigerant having a temperature below a freezing point to freeze water injected into the ice making frame; Non-freezing point operation mode for circulating the refrigerant of the freezing point temperature to remove and drop the ice generated in the ice making frame; Ice supply device for cold and hot water, characterized in that configured to operate in any one of the modes. The method of claim 7, wherein The rotating motor is driven in the non-freezing point operation mode, the ice supply device for cold and hot water, characterized in that for rotating the injector equipped with the slider to the lower side.

Images