KR100487815B1 - Device for hot water dispensing for refrigerator - Google Patents

Abstract

The present invention relates to a hot water supply device for a refrigerator capable of supplying hot water through a dispenser.

The hot water supply apparatus of the present invention includes a filter composed of an ion exchange resin or polyphosphate to remove scale-generating components contained in water supplied from a water supply source; A dispenser for supplying water supplied through the filter to the outside of the refrigerator; And it is installed at the end of the pipe from which the water comes out of the dispenser, and comprises a heater for heating the water.

Description

Device for hot water dispensing for refrigerator

The present invention relates to a refrigerator, and more particularly, to a water supply apparatus for a refrigerator configured to be able to drink drinking water and to supply hot water from a dispenser.

First, a water supply structure of a conventional general refrigerator will be described with reference to FIG. 1. As shown, the water supplied from the water supply source Ws such as the faucet is purified while passing through the water purification device 12 through the pipe Pa, and then supplied to the valve 14 through the pipe Pb. The valve 14 is usually installed in a machine room provided at the lower end of the rear side of the refrigerator, and installed to supply water supplied through the pipe Pb to both sides of the ice maker 22 and the dispenser 20 as described below. will be. In addition, the water purifier 12 installed between the pipes Pa and Pb is substantially installed at the rear of the refrigerator main body.

One side of the valve 14 supplies water to the ice maker 22 through the pipe Pc, and the other side supplies water to the water tank 16 through the pipe Pd. In the water tank 16, water at a constant level is always standing, and such water can be supplied to the dispenser 20 through a pipe Pe.

The dispenser 20 is provided on the front of the door 18 (for example, a freezer compartment door), and is configured to draw water from the water tank 16 to the outside of the refrigerator without opening the door 18. Device. General conventional dispensers have been generally configured to supply only cold water.

In addition, in order to supply hot water from the dispenser, water must be heated by using a heater before water comes out of the dispenser. However, in general tap water, components such as calcium ions and magnesium ions, which generate scale on the inner surface of the flow path inside the refrigerator, are included. When such a component is heated using a heater as compared with the case where cold water flows, generation of scale becomes more remarkable. That is, scale generation is more remarkable in heated water than in general cold water. Therefore, when the water drained through the dispenser is heated using a heater, the scale is generated in the portion heated in the flow path inside the dispenser. This is remarkable.

According to the conventional structure as described above, the following problems are pointed out.

Conventional filter devices have difficulty in purifying the whole water as a whole, for example, it is difficult to filter the calcareous components dissolved in the water provided through the water pipes, and thus it is difficult to provide substantially drinkable water. It is becoming.

And according to the calcining component inherent in tap water, the following disadvantage is pointed out. Water supplied through the water pipes, although regional differences, it is apparent that there is a calcite component that generates a scale on the inner surface of the pipe, it is difficult to drink if the calcite component is not completely filtered. In addition, the water provided through the dispenser of the refrigerator to which the conventional water purifier described above is applied does not substantially filter the calcareous components, which may be a problem in drinking.

In the conventional water purifier, as described above, since the calcareous components that generate the scale are not removed from the inner surface of the pipe, the scale may substantially grow on the inner surface of the pipe inside the refrigerator, thereby causing various problems. There is a concern. For example, when scale is generated and grows inside a pipe, which is a passage for supplying water from inside the refrigerator, the A / S of such a portion becomes difficult, as well as the possibility of corrosion of components inside the refrigerator. . When the scale grows and falls, there is a fear that a mass of foreign matter is present in the water or ice supplied from the inside of the refrigerator, thereby lowering the reliability of the product to the consumer. It is also pointed out that the scale generated inside the pipe lowers the thermal conductivity of the equipment, thereby increasing the amount of power used.

In addition, when the heater is provided in the dispenser, since the generation and growth of the scale as described above are significantly promoted, the above-described problems caused by the generation of the scale are more concerned.

The present invention is to solve the above-mentioned problems, and to provide a hot water supply device configured to provide a hot water dispenser at the same time to prevent the generation of scale in the flow path inside the refrigerator. It is done.

The hot water supply apparatus of the refrigerator according to the present invention for achieving the above object, and a filter capable of removing the scale generation component contained in the water supplied from the water supply source; A dispenser for supplying water supplied through the filter to the outside of the refrigerator; And it is installed at the end of the pipe out of the dispenser, characterized in that it comprises a heater for heating the water.

In addition, the filter has shown an embodiment including a casing having an inlet through which water from a water supply is introduced, an outlet through which filtered water comes out, and a filter unit embedded in the casing.

The filter unit may be made of polyphosphate or ion exchange resin.

According to another embodiment, the filter portion comprises a first filter portion made of polyphosphate and a second filter portion made of activated carbon.

According to a further embodiment, the filter portion comprises a first filter portion composed of ion exchange resins and a second filter portion composed of activated carbon.

And it is preferable that the filter of this invention is detachably installed in the inside of a refrigerator.

Next, the present invention will be described in more detail with reference to the embodiments shown in the drawings.

First, the basic concept of the present invention will be described with reference to FIG. 2. The refrigerator according to the present invention includes a filter (100) capable of filtering water supplied from a water supply source (Ws), an ice maker (I) generating ice using water purified from the filter, and a purified water from the filter. It is configured to include a dispenser (D) for supplying the water to the user.

The water supply source Ws means a portion for supplying water, such as a faucet. Water from the water supply source Ws is provided to the filter 100 through the pipe P1. The filter 100 is a filter for removing scale generation components in tap water. Detailed description of the filter 100 will be described later.

The water purified by the filter 100 may be supplied to the ice maker I and the dispenser H through the pipe P2. According to this invention, the heater H is attached to the edge part of the pipe which supplies water to the said dispenser D here. The heater (H) is a portion provided to heat the water supplied to the dispenser (D) to provide hot water.

As described above, according to the present invention, the scale generation component included in the water supplied from the water supply source, that is, the magnesium ions and calcium ions are typically removed by the filter 100, and the generation of scale is essentially blocked, It can be seen that hot water heated by the heater H is provided to the user through the dispenser D. FIG. At this time, as described above, the water heated by the heater H completely removes the component causing the scale through the filter 100 because the generation of the scale proceeds remarkably fast. Therefore, by applying the present invention, even if the water is heated by the heater H, it is possible to substantially prevent the scale is generated and grow.

In general, a valve for controlling the discharge of water is installed at an end of the pipe that is installed in the dispenser D to supply water. Such a valve and other components inside the dispenser are substantially the same as the conventional ones. Detailed description thereof will be omitted.

Next, the filter 100 will be described in detail with reference to FIG. 3, and the heater H will be described in more detail with reference to FIG. 4.

3, an embodiment of a filter 100 according to the present invention is shown. As illustrated, the filter 100 according to the present invention includes a casing 110 having an inlet 112 and an outlet 114, and a first filter unit 120 embedded in the casing 110. It includes. In some embodiments, the second filter unit 140 may be embedded.

The casing 110 of the filter 100 is detachably installed on one side surface of the refrigerating chamber. As described above, in order to be detachably configured in the refrigerator, as illustrated, the inlet 112 through which water enters and the outlet 114 through which purified water flows out through the inside are preferably formed in the same direction. Therefore, in the illustrated embodiment, the outlet 114 is formed in the central portion of one end of the filter casing 110, and the inlet 112 is formed around the outlet 114. By forming the inlet 112 and the outlet 114 to be concentrated on one side in this way, when the portion is coupled to one side of the inner side of the refrigerating compartment, the formation of the supply passage may be more simple. Therefore, water introduced into the refrigerator through the pipe P1 (see FIG. 2) is introduced into the filter 100 through the inlet 112 and filtered while passing through the first filter unit 120 therein. After that, it exits to the exit 114. In the case of installing the second filter unit 140, as shown in the illustrated embodiment, after passing through the second filter unit 140, it will come out to the outlet 114. And the water exiting the outlet 114 will be supplied to the ice maker I and the dispenser D, respectively, guided by the pipe P2.

Here, the first filter unit 120 is a filter that can remove the cause of the scale that may occur on the passage of water in the refrigerator. According to one embodiment, the first filter unit 120 is composed of an ion exchange resin. Ion-exchange resins are resins that can trap calcium ions and magnesium ions that cause scale generation inside, and can be said to be filters that are partially used in water softeners and the like. Therefore, when the supplied water passes through the first filter part 120 formed of an ion exchange resin, calcium and magnesium ions dissolved in water may be removed.

When the second filter unit 140 is selectively installed, the second filter unit 140 may be configured as a filter that performs other functions, that is, may collect other foreign matter. For example, the second filter part may be configured to be able to basically filter foreign matter contained in water by configuring activated carbon widely used as a water purification filter. Currently, activated carbon filters have been developed and applied in various forms. For example, various kinds of substances that can filter certain foreign matter components contained in water at the same time have been developed by using the activated carbon as a basic composition and impregnating a component having a specific effect on the foreign matter filtration of water. In the present specification, the second filter unit 140 composed of activated carbon is defined as a concept including substantially all activated carbon as the main raw material as described above, and impregnating other components capable of removing certain foreign substances.

In the illustrated embodiment, the first filter part 120 is a portion communicating with the inlet 112, and it can be seen that the first filter part 120 is provided on the outer side surface of the central passage 115. The water passing through the first filter unit 120 passes through the second filter unit 140 again inside the casing 110. Alternatively, when the configuration of the second filter part 140 is omitted, the discharge part is discharged to the outlet 114 through the center passage 115 from the rear side (rear with respect to the inlet) end of the first filter part 120. Could be.

In the illustrated embodiment in which the second filter unit 140 is provided together, the second filter unit 140 is installed in the inner portion of the first filter unit 120. The second filter part 140 is arranged in an annular shape, and is configured to allow water to pass from the outside to the inside (center side). The second filter portion 140 is supported between the flange portion 117 formed on the innermost side of the central passage 115 and the innermost support portion 119 of the casing 110. The inside of the second filter part 140 communicates with the central passage 115 formed along the longitudinal direction at the inner center of the casing 110. Therefore, the water purified while passing through the second filter unit 140 will be discharged to the outlet 114 along the central passage 115.

Next, another embodiment of the first filter unit 120 will be described.

According to another embodiment of the present invention, the first filter unit 120 may be made of polyphosphate. The polyphosphate, which may constitute the first filter part 120, coats the inner surface of the pipe and the surroundings of calcium ions and magnesium ions contained in the water (by reacting the polyphosphate with calcium and magnesium cations). As it flows inside, it does not clump as lime. Therefore, when the first filter unit 120 is formed by using a polyphosphate having a particle size or a shape in which water can flow, water flows through a gap between particles. The calcium and magnesium cations contained in the flowing water will react with the polyphosphate, resulting in a state that cannot be substantially aggregated to calcite.

According to the first embodiment of the present invention as described above, it can be seen that the filter 100 for a refrigerator uses a filter composed of an ion exchange resin or polyphosphate capable of removing a substance that generates calcite. It is also possible to optionally install a separate filter based on activated carbon in the casing (110). In this way, when water is heated by the heater H installed in the dispenser, it is possible to prevent the generation of scale by using the first filter 120 capable of removing the component that generates the scale.

Water through which the foreign matter in the water is filtered while passing through the filter 100 as described above is supplied to the dispenser D and the ice maker I through the pipe P2. And according to this invention, the heater H is provided in the edge part of the pipe P which supplies water to the dispenser D, and it becomes possible to heat so that the water discharged from the dispenser D may become hot water.

As shown in FIG. 4, the heater H is composed of a metallic pipe having high thermal conductivity and a hot wire wound around the outer surface of the pipe and generating heat by application of electricity. It is a matter of course that many modifications can be made in the configuration of such a heater H, and various types of heaters can be used within the range in which water flowing in the pipe can be heated. For example, it is also possible to use an instantaneous heater having a high instantaneous heat generation capability, and FIG. 4 shows an embodiment using such an instantaneous heater.

In FIG. 4, for convenience of illustration, configurations such as a valve provided at the end of the pipe P of the dispenser D, a switch for driving the valve, and the like are omitted, and these configurations are substantially the same as those of the conventional art.

Many other modifications are possible with respect to the configuration example of the heater H. For example, as shown in FIG. 5, at the end of the pipe P which discharges water from the end of a dispenser, the heat storage tube Hc in which the heat storage material Ha was built is installed, and the said heat storage tube ( It is also possible to comprise by winding the heating wire Hb in Hc).

Here, the heat storage material (Ha) can maintain a predetermined high temperature state by heating the heating wire (Hb), and any type of material can be used as long as it is made of a material capable of transferring the heat of the high temperature state to the water flowing inside the pipe (P). It is also possible.

For example, the heat storage material Ha becomes a high temperature state (it may be a liquid state or a gaseous state in a high temperature state) by the heating wire Hb, and heat of this state is inside the pipe P. It is sufficient to be able to conduct water to flowing water. And when heat is conducted to the water inside the pipe (P), the heat storage material (Ha) may be used to cause a phase change.

Such heat storage material (Ha) will be able to use a material having a high specific heat, it is also possible to use water in the simplest configuration example. When water is used as the heat storage material (Ha), the water of the heat storage material (Ha) is heated to maintain a high temperature state by the heating wire (Hb) that generates heat by the application of electricity. And in this state, when water is supplied through the dispenser (D), the heat of the heat storage material (Ha) is conducted to the water flowing inside the pipe (P), substantially hot water is supplied through the dispenser (D) It will be possible.

As described above, the heater H according to the present invention may use an instantaneous heater, or may be configured using a heater and a heat storage material. And of course, it is also possible to configure by using the instantaneous heater and the heat storage material at the same time.

As described above, according to the present invention, in order to receive hot water through the dispenser, it can be seen that it is a basic technical idea to employ a heater to prevent generation of scale due to heat. .

Within the scope of the basic technical spirit of the present invention, many modifications are possible to those skilled in the art, and the present invention should be interpreted based on the appended claims. Self-explanatory

According to the present invention as described above, when water from a water supply source such as tap water is supplied through the dispenser of the refrigerator, it is possible to supply in a hot water state. Furthermore, in order to prevent scale that may occur due to the heating of water, by using a separate filter 100, it is possible to prevent any damage to the flow path inside the refrigerator. Therefore, by applying the present invention, it is possible to supply hot water and to prevent the generation of scale in the internal flow path of the refrigerator, so that the effect of substantially increasing the reliability of the product may be expected.

1 is a schematic view of a typical refrigerator.

Figure 2 is a block diagram showing an outline of the water supply apparatus of the present invention.

3 is an exemplary cross-sectional view of a filter according to the present invention.

Figure 4 is a schematic illustration of the dispenser according to the present invention.

Figure 5 is a schematic illustration showing a heater of another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100 ..... Filter 110 ..... Casing

112 ..... Entrance 114 ..... Exit

120 ..... 1st filter part 140 ..... 2nd filter part

D ..... dispenser I ..... ice maker

H ..... Heater Ha ..... Heat Storage

Hc ..... heating wire Hc ..... heat storage tube

Claims (10)

A filter capable of removing scale-generating components contained in water supplied from a water supply source; A dispenser for supplying water supplied through the filter to the outside of the refrigerator; And The hot water supply apparatus of the refrigerator, which is installed at the end of the pipe out of the dispenser, comprising a heater for heating the water. The refrigerator according to claim 1, wherein the filter comprises a casing having an inlet through which water from a water supply is introduced, an outlet through which filtered water comes out, and a filter unit embedded in the casing. Hot water supply. The hot water supply device of a refrigerator according to claim 2, wherein the filter unit is made of polyphosphate. The hot water supply apparatus of the refrigerator of claim 2, wherein the filter unit is made of an ion exchange resin. The hot water supply apparatus of claim 2, wherein the filter unit comprises a first filter unit composed of polyphosphate and a second filter unit composed of activated carbon. The hot water supply device of a refrigerator according to claim 2, wherein the filter part comprises a first filter part made of ion exchange resin and a second filter part made of activated carbon. The hot water supply device of a refrigerator according to any one of claims 2 to 6, wherein the filter is detachably installed inside the refrigerator. The hot water supply device for a refrigerator according to any one of claims 2 to 6, wherein the inlet and the outlet are formed on the same side of the casing. The hot water of the refrigerator according to any one of claims 2 to 6, wherein the casing is formed in a cylindrical shape, the outlet is formed in the center of one side of the cylindrical casing, and the inlet is formed along the outer circumferential surface of the outlet. Feeder. 7. The casing according to claim 5 or 6, wherein the casing is formed in a cylindrical shape, the outlet is formed in the center of one side of the cylindrical casing, the inlet is formed along the outer circumferential surface of the outlet, and the first filter part is cylindrical in the casing. A second filter portion is cylindrically disposed at a rear end of the first filter portion, the outlet communicates with a central passage formed in the longitudinal direction of the central portion of the casing, and an end portion of the central passage is located inside the second filter portion; The water introduced through the inlet is passed through the first filter portion, after passing from the outside of the second filter portion to the inside, and is discharged to the outlet through the central passage.