KR100770072B1 - Dish washer - Google Patents

Abstract

A dish washer comprising: a washing tank, a heat pump unit, a control unit for sequentially controlling a series of steps of washing, rinsing, heating rinsing, and drying, and a first heat exchanger for exchanging heat with washing water in the washing tank constituting the heat pump unit. Contains groups. Here, the control part controls conversion so that a 1st heat exchanger may become a condenser in at least one of a washing | cleaning and a heating rinsing stroke, and an evaporator in a drying stroke. This configuration provides a dishwasher which is energy efficient and easy to use.

Description

Dish Washer {DISH WASHER}

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a side sectional view in a washing stroke of a dish washing machine according to Embodiment 1 of the present invention.

Fig. 2 is a side sectional view of the dishwasher in a drying stroke according to Embodiment 1 of the present invention.

3 is a side sectional view of the dishwasher according to Embodiment 2 of the present invention.

Figure 4 is a side cross-sectional view of a conventional dishwasher.

<Explanation of symbols for main parts of the drawings>

1: main body 13: washing tank,

14: first heat exchanger 15: second heat exchanger

16 compressor 17 expansion valve

30: heat pump unit 31: control unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dish washer for cleaning dishware by spraying washing water from the washing nozzle toward the dishware.

4 is a side cross-sectional view of a conventional dish washing machine. Conventionally, this kind of dish washer was comprised as shown in FIG. 4, for example. Hereinafter, the structure of the conventional dishwasher is demonstrated.

In FIG. 4, the washing | cleaning tank 102 is provided in the dishwasher main body 101 inside. The drain hole 103 is provided in the bottom of this washing tank 102. The washing pump 105 is disposed in the pump chamber communicating with the side portion of the drain hole 103. This washing pump 105 is driven by the motor 104. The washing water is circulated inside the washing tank 102 by the washing pump 105.

This circulation is sucked into the washing pump 105 from the drain hole 103 and supplied to the washing nozzle 106 disposed at the inner bottom of the washing tank 102 by the washing pump 105. After the nozzle 106 is sprayed toward the tableware 107 to clean the tableware 107, the process returns to the drain hole 103.

The washing water heating heater 108 is disposed between the cleaning nozzle 106 and the bottom of the cleaning tank 102. Moreover, the dish basket 109 is provided above the washing nozzle 106. By arrange | positioning the tableware 107 in this dish basket 109, it is comprised so that the washing water may be sprayed on the tableware 107 effectively and washing of the tableware 107 is performed efficiently.

Moreover, the washing tank 102 is opened forward, and the cover 110 is attached so that this opening may be covered. When the washing pump 105 reversely rotates the motor 104, the washing pump 105 sucks the washing water from the drain hole 103 and discharges the washing water out of the machine through the drain hose 111.

In addition, the heater 108 is intermittently made to pass a current, and the air entering the cleaning tank 102 from the outside of the machine is heated by the drying fan 112 and shot on the dishware 107, thereby adhering to the dishware 107. It is comprised so that evaporation of water and drying may be possible. A dishwasher of this kind is disclosed, for example, in Japanese Patent Application Laid-Open No. 9-103402.

However, in the conventional dishwasher having the above-described configuration, the heat amount for heating the washing water when washing the dishes 107 is all generated by the heat generation of the heater 108, and only the power consumption is used as the heat amount. In addition, since all the steam generated when drying the dishes 107 is discharged out of the machine, the problem that the humidity of the indoor air of the kitchen in which the dishwasher main body 101 is installed rises and superimposes the increase in the discomfort index. there was.

The dish washing machine of the present invention is configured to exchange heat with a washing tank, a heat pump unit, a control unit for sequentially controlling a series of steps of washing, rinsing, heating rinsing and drying, and washing water in the washing tank constituting the heat pump unit. A heat exchanger. The control unit controls the heat exchanger to be a condenser in at least one of the washing and heating rinsing strokes, and the evaporator in the drying stroke.

Moreover, the dishwasher of this invention controls the electric current which flows to a Peltier element while simultaneously controlling a washing tank, a Peltier element, and a series of processes of washing | cleaning, rinsing, heat rinsing, and drying in order as another structure. It includes a control unit. The Peltier element is configured to be in contact with the cleaning tank, and the control unit converts and controls the current so that the Peltier element becomes the heat generating side in at least one of the cleaning and heating rinsing strokes and the endothermic side in the drying stroke. .

According to these configurations, it is possible to transfer the surrounding heat to the washing water by the heat pump unit or the Peltier element at the time of washing and heating rinsing stroke, and the amount of power consumption required for increasing the temperature of the washing water can be reduced. In addition, since the dehumidification in the washing tank can be carried out during the drying stroke, the amount of water vapor discharged out of the machine can be reduced. Therefore, the increase in the humidity of the indoor air can be suppressed to be low, and a convenient dishwasher can be provided. .

Thus, according to the dishwasher of this invention, a more efficient use of a heat pump unit or a Peltier element can provide a dishwasher which is more energy efficient and convenient to use.

(Embodiment)

Embodiments of the present invention will be described with reference to the drawings. In addition, this invention is not limited by this embodiment.

(Embodiment 1)

1 is a side sectional view in a washing stroke of a dish washing machine according to Embodiment 1 of the present invention, and FIG. 2 is a side sectional view in a drying stroke of the dish washing machine.

First, the main structure of the dishwasher of this Embodiment 1 is demonstrated using FIG. 1 and FIG. That is, the dishwasher of this Embodiment 1 is the washing tank 13, the heat pump unit 30, the control part 31 which controls a series of steps of washing | cleaning, rinsing, heating rinsing, and drying sequentially, The heat exchanger 14 which comprises the heat pump unit 30 and heat-exchanges with the wash water in the washing tank 13 is included. The control part 31 converts and controls the heat exchanger 14 so that it may become a condenser in at least one of a washing | cleaning and a heating rinsing stroke, and an evaporator in a drying stroke.

With this configuration, the heat pump unit 30 makes it possible to transfer the surrounding heat to the washing water at the time of washing and heating rinsing stroke, and the amount of power consumption required for increasing the temperature of the washing water can be reduced. During the drying process, it is possible to perform dehumidification in the washing tank 13 and to reduce the amount of water vapor discharged out of the machine, so that the increase in humidity of the indoor air can be suppressed low, and the dishwasher which is convenient to use. Can provide.

The dishwasher which concerns on Embodiment 1 of this invention which has the above main structures is demonstrated in more detail.

1 and 2, the first heat exchanger 14, the second heat exchanger 15, the compressor 16, and the expansion valve 17 under the washing tank 13 provided in the dishwasher main body 1. ), A heat pump unit 30 including the switching valve 18 is disposed. Here, the 1st heat exchanger 14 is arrange | positioned in contact with the rear side side down of the washing tank 13. On the other hand, the second heat exchanger 15 is disposed away from the washing tank 13. The control unit 31 controls the washing pump 5, the heater 8, the drying fan 12, the heat pump unit 30, and the like, and controls the sequence of washing, rinsing, heating rinsing and drying in order. do.

The operation and action of the dish washing machine of the first embodiment configured as described above will be described. First, the user arranges the dishes 7 in the dish basket 9, and then accommodates the dish basket 9 in the cleaning tank 13. Then, when the dishwasher starts to operate, the washing pump 5 is driven, and the pressurized washing water is injected from the washing nozzle 6 toward the dishware 7. In the washing stroke and the heating rinsing stroke, a current flows in the heater 8, and the injection from the washing nozzle 6 is performed while heating the washing water to a predetermined temperature (washing stroke: 55 ° C, heating rinsing stroke: 67 ° C). Is done.

In this washing stroke and heat rinsing stroke, as shown in FIG. 1, the switching valve 18 is controlled so that the first heat exchanger 14 in contact with the washing tank 13 in the heat pump unit 30 is a condenser. . For this reason, the compressor 16 is driven and the heat contained in the surrounding air below the washing tank 13 is absorbed by the second heat exchanger 15 which is an evaporator. In this way, it is possible to heat the washing water by transferring heat from the first heat exchanger 14 to the washing water in the washing tank 13. As a result, it is possible to reduce the amount of power consumption required for increasing the temperature of the washing water.

In the drying stroke, as shown in FIG. 2, the switching valve 18 is controlled so that the first heat exchanger 14 in contact with the washing tank 13 in the heat pump unit 30 is an evaporator. For this reason, in the vicinity of the inner surface of the washing tank 13 in which the first heat exchanger 14 is in contact with the compressor 16, it is necessary to condense and dehumidify the water vapor contained in the air in the washing tank 13. It is possible.

In addition, although the location where the 1st heat exchanger 14 contacts the washing tank 13 is preferable from the point of thermal efficiency of the rear side side down of the washing tank 13 like FIG. 1 and FIG. 2, it is not limited to this. For example, the bottom may be sufficient. Regarding the thickness of the cleaning tank 13, if the portion where the first heat exchanger 14 is in contact with the thinner portion is set thinner than other portions, the heat transfer rate increases, which is more effective.

As described above, in at least one of the washing and heating rinsing strokes, the control unit 31 switches the switching valve such that the first heat exchanger 14 becomes a condenser and the second heat exchanger 15 becomes an evaporator. (18). On the other hand, in a drying stroke, the control part 31 controls the switching valve 18 so that the 1st heat exchanger 14 may become an evaporator and the 2nd heat exchanger 15 may become a condenser.

The drying fan 12 which sends drying air into the washing tank 13 is equipped with the duct 19 so that the drying air intake 40 may be in the vicinity of the heat pump unit 30. As a result, heat generated from the second heat exchanger 15 and the compressor 16 of the heat pump unit 30 during the drying stroke can be brought into the drying air. As a result, the amount of power consumption required for heating the drying air can be reduced to a low level, and a dishwasher excellent in energy efficiency can be obtained.

(Embodiment 2)

3 is a side sectional view of the dishwasher according to Embodiment 2 of the present invention. As shown in FIG. 3, in the dishwasher of 2nd Embodiment, it replaces the heat pump unit 30 of 1st Embodiment, and is in contact with the outer side of the rear back surface of the washing tank 20, and the Peltier element 21 is shown. Is placed. In addition, since the other structure as a dishwasher is the same as that of Embodiment 1, description is abbreviate | omitted.

Next, the operation | movement and action | action of the dishwasher of Embodiment 2 of the said structure are demonstrated. After the user arranges the dishes 7 in the dish basket 9, the dish basket 9 is accommodated in the washing tank 20. As shown in FIG. When the dishwasher starts to operate, the washing pump 5 is driven, and the pressurized washing water is injected from the washing nozzle 6 toward the dishware 7.

In the washing stroke and the heating rinsing stroke, a current flows through the heater 8 and the spray from the washing nozzle 6 is heated while heating the washing water to a predetermined temperature (washing stroke: 55 ° C, heating rinsing stroke: 67 ° C). Is done.

In at least one of the washing stroke and the heating rinsing stroke, the current is controlled so that the surface in contact with the washing tank 20 of the Peltier element 21 becomes the heat generating side. For this reason, the heat contained in the surrounding air of the washing tank 20 can be transferred to the washing water in the washing tank 20, and the amount of power consumption required for increasing the temperature of the washing water can be reduced.

In the drying stroke, the current is controlled so that the surface in contact with the cleaning tank 20 of the Peltier element 21 becomes the heat absorbing side. For this reason, in the vicinity of the inner surface of the washing tank 20 that the Peltier element 21 is in contact with, it is possible to condense and dehumidify the water vapor contained in the air in the washing tank 20.

The place where the Peltier element 21 contacts is not limited to the side surface of the washing tank 20 like FIG. 3, and may be a bottom face. With respect to the thickness of the cleaning tank 20, when the portion where the Peltier element 21 is in contact with the thinner portion is set thinner than other portions, the heat transfer rate increases, which is more effective.

The drying fan 12 which sends drying air into the washing tank 20 is equipped with the duct 22 so that the drying air intake 41 may be in the vicinity of the Peltier element 21. For this reason, since heat generated from the surface on the opposite side to the cleaning tank 20 of the Peltier element 21 can enter the drying air during the drying stroke, the amount of power consumption required to heat the drying air is kept low. It becomes possible, and it can be set as the dishwasher excellent in energy efficiency.

As is apparent from the above, the dish washing machine of the present invention includes a washing tank, a heat pump unit, a control unit for sequentially controlling a series of steps of washing, rinsing, heating rinsing and drying, and a washing tank constituting the heat pump unit. It includes a first heat exchanger for heat exchange with the washing water in. Here, the control unit controls the conversion so that the first heat exchanger becomes a condenser in at least one of the washing and heating rinsing strokes and the evaporator in the drying stroke. This configuration provides a dishwasher which is energy efficient and easy to use.

When the heat exchanger which exchanges heat with the washing water in the washing tank is in contact with the washing tank, there is no need to drill a hole in the washing tank, so there is no fear of water leakage. In addition, since the heat pump unit can be assembled as one part in the dishwasher, a dishwasher having high manufacturing workability and service maintenance workability can be realized.

In the case where the drying air inlet is arranged near the heat pump unit, the heat generated from the condenser and the compressor of the heat pump unit can be introduced into the washing tank by the drying fan in the drying stroke, and thus the drying air is heated. It is possible to reduce the amount of power required to do so and to provide a more energy-efficient dishwasher.

In the dishwasher main body, a washing tank, a Peltier element, and a control unit for controlling a current flowing through the Peltier element while controlling a series of steps of washing, rinsing, heating rinsing and drying in sequence, are provided. The control unit controls the current so that the Peltier element in contact with the cleaning tank becomes the heat generating side in at least one of the cleaning and heating rinsing strokes, and the endothermic side in the drying stroke. At the time of washing and heating rinsing stroke, the surrounding heat can be transferred to the washing water by the Peltier element, and the amount of power consumption required to increase the temperature of the washing water can be reduced. In addition, it is possible to perform dehumidification in the washing tank during the drying stroke, and the amount of underwater air discharged out of the machine can be reduced. Therefore, the increase in humidity of the indoor air can be suppressed to be low, and a convenient dishwasher can be provided. .

In the case where the drying air inlet is disposed in the vicinity of the Peltier element, it is possible to introduce heat generated from the heat-generating side of the Peltier element into the washing tank by the drying fan in the drying stroke, so that the drying air is heated. The amount of power consumption required can be kept low and a more energy efficient dishwasher can be provided.

As mentioned above, the dishwasher which concerns on this invention uses a heat pump unit or a Peltier element more effectively, and can use it for a dishwasher which is more energy efficient than the conventional technique, and is convenient to use.

Claims (7)

Washing tank, With heat pump unit, A control unit which controls a series of steps of washing, rinsing, heating rinsing and drying in order; A first heat exchanger configured to exchange heat with the washing water in the washing tank, which constitutes the heat pump unit, And the control unit controls the first heat exchanger to convert the first heat exchanger into a condenser in at least one of the washing and the heating rinsing stroke, and the evaporator in the drying stroke. The dish washing machine according to claim 1, wherein the first heat exchanger is in contact with the washing tank. The dish washing machine according to claim 1, further comprising a second heat exchanger disposed away from the washing tank. 4. The method of claim 3, wherein when the first heat exchanger is the condenser, the second heat exchanger is an evaporator, and when the first heat exchanger is the evaporator, the second heat exchanger is configured to be a condenser. dish washer. The dishwasher according to claim 1 or 2, further comprising a drying air inlet in the vicinity of the heat pump unit. Washing tank, Peltier Soja, A control unit for controlling a current flowing in the Peltier element while simultaneously controlling a series of steps of washing, rinsing, heating rinsing and drying, The Peltier element is in contact with the cleaning tank, The controller controls the Peltier element to convert the current so as to be a heat generating side in at least one of the cleaning and heating rinse strokes, and an endothermic side in the drying stroke. dish washer. 7. The dishwasher of claim 6, further comprising a drying air inlet in the vicinity of the Peltier element.

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