KR20110131920A - Dish washer - Google Patents

Abstract

PURPOSE: A dish washer is provided to improve the efficiency of next stroke by heat-exchanging the water which is used in a next stroke with the high temperature cleaning water. CONSTITUTION: A dish washer comprises a water supplying unit(60), a sump(10). The water supplying unit collects the water for using in the washing. The sump is provided with the water of the water chamber and supplies the cleaning water to the washing tub. The water supplying unit comprises a water supply portion, a heat exchanger, a body and a separating unit. The water supplying portion has a water chamber(62) in which the water is saved. The heat exchanger is divided with the water chamber. The heat exchanger is provided with the cleaning water of the sump and has a heat exchanging passage for heat-exchanging the water collected in the water chamber and the cleaning water.

Description

Dishwasher {Dish washer}

The present invention relates to a dishwasher.

In general, the dishwasher is a device for washing dishes by high-pressure washing water sprayed from the washing nozzle.

The dishwasher includes a washing tank in which a washing space is formed, a sump provided below the washing tank to store the washing water, and a plurality of washing nozzles provided in the washing tank.

The washing water supplied to the sump is sprayed into the washing tank after being moved to the washing nozzle, and is moved to the sump again after being sprayed into the washing tank.

The dishwasher performs a plurality of strokes until the washing of the dish is completed, and in at least one of the plurality of strokes, washing water is supplied from the outside through the water supply pipe.

It is an object of the present invention to provide a dishwasher in which the wash water used or used in a particular stroke is exchanged with water to be used in the next stroke, so that the efficiency of the next stroke is increased.

Dishwasher according to one aspect, the water supply unit for collecting water for use in the wash; And a sump for receiving the water from the water supply device and supplying the washing water to the washing tank, wherein the water supply device includes a water supply unit having a water chamber in which water is stored, and the water chamber, which is divided into the water chamber and wash water of the sump. It includes a heat exchanger having a heat exchange passage for supplying the heat and the washing water collected in the water chamber.

A dishwasher according to another aspect includes: a water supply mechanism having a water chamber for collecting water for use in washing; A sump that receives water from the water supply device and supplies washing water to a washing tank; And a heat exchanger in contact with the water supply mechanism and having a heat exchange flow path for receiving the wash water from the sump to exchange heat with the water collected in the water chamber.

According to the proposed invention, since the water to be used for the next stroke is heat-exchanged with the washing water having a temperature higher than the water temperature, and the heat-exchanged water is supplied to the sump, the administrative efficiency of the next stroke, for example, the washing or rinsing efficiency is increased. have.

1 is a schematic cross-sectional view of the dishwasher according to the first embodiment.
2 is a perspective view of a water supply mechanism according to the first embodiment.
3 is a front view of the water supply mechanism showing the heat exchange passage structure.
4 is a bottom view of a sump according to the first embodiment.
5 is a cross-sectional view of the sump for showing the structure of the washing pump.
Figure 6 is a cross-sectional view of the sump for showing the structure of the flow path adjusting device.
7 is a flowchart illustrating a control method of the dish washing machine of the first embodiment.
8 is a view illustrating a control method of the dish washing machine according to the second embodiment.
9 is a bottom view of a sump according to the third embodiment;
10 is a flowchart illustrating a control method of the dish washing machine according to the third embodiment.
11 is a bottom view of a sump according to the fourth embodiment.
12 is a flowchart illustrating a control method of the dish washing machine according to the fourth embodiment.
13 is a perspective view of a water supply mechanism according to a fifth embodiment.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.

In this specification, for the sake of clarity, "water" means water that is not used in a specific stroke, and "wash water" means water supplied to a sump for use in the stroke, water used in the stroke, and stroke In water means complete use.

1 is a schematic cross-sectional view of a dish washing machine according to a first embodiment, FIG. 2 is a perspective view of a water supply mechanism according to a first embodiment, FIG. 3 is a front view of a water supply mechanism showing a heat exchange path structure, and FIG. 4 Is a bottom view of a sump according to the first embodiment.

Some configuration of the water supply mechanism is shown in FIG. 1, and a structure not shown in FIG. 1 is clearly described in FIG. 2.

1 to 4, the dishwasher 1 according to the present embodiment includes a case 2 forming an exterior and a washing space provided inside the case 2, and for washing dishes. It includes a washing tank 4 to be formed, a sump 10 provided at the lower side of the washing tank 4 to collect washing water for washing dishes, and a door 3 for opening and closing the washing tank 4.

The control panel 3a for controlling the operation of the dish washing machine is provided on the upper side of the door 3.

Inside the washing tank 4, a plurality of racks on which tableware is placed are provided. The plurality of racks includes an upper rack 5 and a lower rack 6 located below the upper rack 5. In the present embodiment, for example, the two racks (5, 6) are provided in the washing tank 4, for example, but the number of the rack in the present embodiment is not limited.

In addition, the washing tank 4 is provided with a plurality of washing nozzles for receiving the washing water from the sump 10 and spraying the washing water to the dishes placed on the racks 5 and 6.

The plurality of washing nozzles may include a lower nozzle 7 connected to an upper side of the sump 10, and an intermediate nozzle 8 positioned above the lower nozzle 7 to receive washing water from the sump 10. And a top nozzle 9 positioned above the intermediate nozzle 8 and receiving the washing water from the sump 10.

The sump 10 is connected to a wash water guide 9a for delivering wash water to the intermediate nozzle 8 and the top nozzle 9. A single wash water flow path may be formed in the wash water guide 9a, or two wash water flow paths may be partitioned. Alternatively, each of the plurality of wash water guides may deliver wash water to each of the intermediate nozzle 8 and the top nozzle 9.

The sump 10 includes a washing pump 70 for pumping the washing water in the sump 10, and a passage adjusting device 80 for adjusting a flow path of the pumped washing water. In addition, a drain pump 50 is connected to the sump 10. A drain flow path 51 is connected to the drain pump 50. Therefore, the washing water drained by the drain pump 50 flows through the drain flow passage 51 and is drained to the outside of the dish washing machine 1.

The sump 10 includes a first guide tube 12 for guiding the washing water to the washing pump 70, and a second guide tube 13 for guiding the washing water to the drain pump 50. The sump 12 is provided with an accommodating portion 11 in which a filter unit (to be described later) is accommodated. The first guide tube 12 and the second guide tube 13 extend from the receiving portion 11 at positions spaced apart from each other.

In addition, the sump 10 further includes a third guide tube 18 for guiding the washing water pumped from the washing pump 70 to the flow path adjusting device 80.

An upper portion of the sump 10 may be formed with an inlet 17 for introducing the washing water. The washing water sprayed from one or more of the washing nozzles 7, 8, and 9 is collected into the sump 10 through the inlet 17, and again by the washing pump 70, the plurality of washing nozzles 7. , 8, 9) is supplied to the nozzle.

A water supply mechanism 60 is provided between the washing tank 4 and the case 2 to guide the flow of the washing water and to allow the outside air of the washing tank to communicate with the air inside the washing tank 4.

The water supply mechanism 60 includes a body 60a having a space formed therein and a partition 66 partitioning the internal space of the body 60a into at least two spaces. The water supply mechanism 60 is divided into a water supply unit 60b and a heat exchanger 60c by the partition 66.

The water supply unit 60b includes a first flow passage 61 in communication with a water supply pipe 30 connected to an external water supply source (not shown), and a water chamber in which water supplied through the first flow passage 61 is collected ( 62, and a second flow path 63 through which water in the water chamber 62 is discharged. The second flow path 63 is connected to the water softener 40. The softening device 40 serves to remove the hardness component contained in the water. The softening device 40 is connected to the sump 10. In the present embodiment, the water supply pipe 30, the first and second flow paths (61, 63) and the softening device 40 flows water to be supplied to the sump (10) from the outside, collectively these It can be called a water supply channel.

In addition, the water supply unit 60b includes a communication passage 64 communicating with the outside of the washing tank 4 or the outside of the dish washing machine 1, and a communication hole 64a communicating with the washing tank 4. The communication flow path 64 is partitioned from the first and second flow paths 61 and 63 and the water chamber 62.

Therefore, the inside of the washing tank 4 can be maintained at atmospheric pressure by the water supply mechanism 60, and the inside of the washing tank 4 can be prevented from increasing in pressure by hot air.

On the other hand, the heat exchanger (60c), the washing water supplied from the sump (10) and the water collected in the water chamber 62 of the water supply (60b) heat exchange.

The heat exchange part 60c is connected to a supply flow path 91 for receiving the wash water from the sump 10 and a discharge flow path 93 for discharging the wash water heat-exchanged with the water chamber to the sump.

Inside the heat exchanger 60c, a heat exchange flow path 92 is defined to exchange heat between the water in the water chamber and the wash water supplied from the sump. That is, in the present embodiment, the heat exchange passage 92 and the water chamber 62 are formed in the water supply mechanism 60, and the heat exchange passage 92 is the body 60a of the water supply mechanism 60. Defines.

The washing water of the supply passage 91 is a state before heat exchange, the washing water of the heat exchange passage 92 is in a state of being heat-exchanged with water of the water chamber 62, and the washing water of the discharge passage 93 has completed heat exchange. to be.

The heat exchange part 60c may flow the washing water during a specific stroke or after a specific stroke is completed and before draining. The water chamber 62 is supplied with water from an external water supply source. In this embodiment, the washing water temperature of the sump 10 flowing to the heat exchanger 60c is higher than the temperature of the water stored in the water chamber 62. Therefore, when the wash water flows to the heat exchanger 60c, the water of the water chamber 62 is heat-exchanged with the wash water of the heat exchanger 60c to increase the temperature.

The water in the water chamber 62 is used in the next stroke after the particular stroke is completed. When the temperature of the water in the water chamber 62 is raised in this way, the stroke efficiency (washing efficiency or rinsing efficiency) in the next stroke can be increased.

In this embodiment, in order to increase the heat exchange efficiency of the water in the water chamber 62 and the washing water flowing through the heat exchange passage 92, the heat exchange passage 92 may be bent one or more times. In detail, the heat exchange part 60c includes a plurality of guide parts 94 and 95 for increasing the flow distance of the washing water supplied from the sump. The plurality of guide parts 94 and 95 may form a zigzag heat exchange path inside the heat exchange part 60c. That is, one end of the first guide portion 94 is in contact with one surface of the heat exchange part 60c, and the other end is spaced apart from the other surface (face facing one surface) of the heat exchange part 60c. On the other hand, one end of the second guide portion 95 is spaced apart from one surface of the heat exchanger 60c, and the other end contacts the other surface of the heat exchanger 60c.

In the present exemplary embodiment, one or more first and second guide parts 94 and 95 may be provided, but a plurality of first and second guide parts 94 and 95 may be provided to increase the length of the heat exchange path 92. In FIG. 3, the first and second guide parts 94 and 95 extend in the vertical direction. However, the first and second guide parts 94 and 95 extend in the left and right directions or inclinedly. May be

Therefore, the heat of the washing water is transferred to the water of the water chamber 62 through the partition 66 while the washing water supplied from the sump 10 flows through the heat exchange passage 92. Therefore, in the present embodiment, since the partition 66 transfers heat, it may be referred to as a heat transfer unit.

In this case, the partition 66 is integrally formed with the body 60a, but may be configured as a separate article. In this case, the partition 66 may be formed of a copper material having a high thermal conductivity.

In addition, a heat insulating material may be provided on an inner surface or an outer surface of the heat exchanger 60c except for the partition 66.

Figure 5 is a cross-sectional view of the sump for showing the structure of the washing pump, Figure 6 is a cross-sectional view of the sump for showing the structure of the flow control device.

1 to 6, filter units 14 and 15 are accommodated in the accommodating part 11 of the sump 10. The filter units 14 and 15 include a first filter 14 for filtering relatively large foreign matter and a second filter 15 for filtering relatively small foreign matter. In the present embodiment, the filter unit is described as including two filters, but the number of filters is not limited, and may include one or more filters.

When the washing pump 70 is operated, the washing water flows sequentially through the first filter 14 and the second filter 15 and then passes through the first guide tube 12 toward the washing pump 70. do.

The washing pump 70 includes a washing motor 71 and an impeller 72 connected to the washing motor 71. In addition, a heater 19 for heating the washing water is disposed below the impeller 72 in the sump 10. Therefore, the washing water heated by the heater 19 may flow to the flow path adjusting device 80 by the rotation of the impeller 72.

The flow path control device 80 includes a flow path control valve 82 and a valve motor 81 for rotating the flow path control valve 82. The sump 10 is formed with a case 83 in which the flow path control valve 82 is accommodated, and the valve motor 81 is disposed outside the sump, that is, outside the case 83. 82).

The flow control valve 82 includes a body 82a in which a chamber through which the washing water flows is formed. The body 82a may include at least one inlet hole 82b through which the washing water delivered from the third guide tube 18 is introduced, and at least one nozzle hole for supplying the washing water to at least one of the plurality of washing nozzles. 82c) and one or more heat exchange holes 82d for supplying washing water to the heat exchanger 60c. The supply flow path 91 of the heat exchange part 60c is connected to the case 83. In addition, the discharge passage 93 of the heat exchange part 60c is connected to the receiving part 11 of the sump 10. In this embodiment, since the washing water is supplied to at least one of the plurality of washing nozzles by the flow control valve 82, the same as in the known concept, a detailed description thereof will be omitted.

However, in the present embodiment, there is a technical significance that the heat exchange hole 82d is formed in the flow path control valve 82 so that the washing water flows to the heat exchange part 60c. That is, when the flow path control valve 82 is rotated to a specific position, the heat exchange hole (82d) is in communication with the supply flow path 91, the washing water flows to the heat exchange unit (60c).

When the supply passage 91 and the heat exchange hole 82d communicate with each other, the nozzle hole 82c may or may not communicate with any one of the plurality of cleaning nozzles.

On the upper side of the sump 10, a first connection part 16 for connecting the lower nozzle 6 and a second connection part 16a to which the washing water guide 9a is connected are formed.

On the other hand, the dishwasher performs a plurality of strokes until the washing of the dishes is completed. In general, the plurality of strokes may include at least a washing stroke for washing the dishes and a rinsing stroke for rinsing the dishes. Depending on the type of dishwasher, a drying stroke may be added after the completion of the rinsing stroke.

The washing stroke may be a single stroke or may be divided into a preliminary washing stroke and a main washing stroke. The heater 19 does not operate in the preliminary washing stroke, and the heater 19 may operate in the main washing stroke. If the cleaning stroke is a single stroke, the heater 19 can be operated in at least some sections of the stroke.

The rinse stroke may be a single stroke or may be divided into a normal rinse stroke and a heated rinse stroke. The heater 19 may not operate in a normal rinse stroke, and the heater 19 may operate in a heated rinse stroke. If the rinsing stroke is a single stroke, the heater 19 may operate in at least some sections of the stroke.

Meanwhile, water is supplied to the dish washer from the outside before starting at least one of the entire strokes for washing the dishes. At this time, the water chamber 62 stores water to be used for the next stroke.

Since the heater 19 is operated when the main cleaning is performed, the temperature of the washing water is higher than the water temperature stored in the water chamber 62. Therefore, in order to increase the stroke efficiency in the normal rinse stroke, it is necessary to exchange heat with the water in the water chamber 62 and the hot wash water before the normal rinse stroke starts. Even when the washing stroke is a single stroke, it is necessary to exchange heat with the water in the water chamber 62 and the hot washing water before the rinsing stroke so that the stroke efficiency in the next rinsing stroke is increased.

In addition, in the normal rinse stroke, the heater 19 is not operated, but the temperature of the washing water is higher than the temperature of the water of the water chamber 62 due to the latent heat inside the washing tank. Thus, in order to increase the stroke efficiency in the heating rinse stroke, it is necessary to exchange heat with the water in the water chamber and the hot washing water before the heat rinse stroke is started.

"Specific stroke" referred to below means a stroke in which the temperature of the washing water at the time of performing the current stroke is higher than the temperature of the water to be supplied to the next stroke, and the specific stroke may be plural until the washing of the dishes is completed.

Hereinafter, a control method of the dish washing machine according to the present embodiment will be described.

7 is a flowchart illustrating a control method of the dish washing machine according to the first embodiment.

In this embodiment, the washing water flows to the heat exchange passage during a specific stroke.

Referring to FIG. 7, the heat exchange path 92 is opened by the operation of the flow path adjusting device 80 during a specific stroke (S1). In the present embodiment, the opening of the heat exchange passage 92 means that the washing water flows into the heat exchange passage.

When the water to be used for the next stroke is supplied to the water chamber 62 at the beginning of the specific stroke, the heat exchange passage 92 may be opened at the beginning of the specific stroke. When the water to be used for the next stroke is supplied to the water chamber 62 in the middle of the specific stroke, the heat exchange passage 92 may be opened at the time when the water is supplied to the water chamber 62.

In this embodiment, since the heat exchange passage 92 is opened during a specific stroke, the washing water must be supplied to at least one of the plurality of washing nozzles.

Since the washing pump 70 is operated during the specific stroke, when the heat exchange passage 92 is opened, the washing water is supplied to the heat exchange passage 92, and the washing water is supplied to the washing tank 4 by at least one washing nozzle. It is supplied (S2). The washing water supplied to the heat exchange passage 92 is recovered to the sump 10 after being exchanged with water in the water chamber 62.

It is determined whether or not the stroke is completed during the specific stroke (S3), and if it is determined that the specific stroke is completed, the heat exchange passage 92 is closed by the operation of the flow path adjusting device 80 (S4). Then, the washing pump 70 is stopped. The closing of the heat exchange passage 92 in this embodiment means that the washing water does not flow into the heat exchange passage.

When the heat exchange passage 92 is closed, the drain pump 50 is operated to drain water (S5). After the drainage is completed, the heat-exchanged water in the water chamber 62 is supplied to the sump 10.

According to the present embodiment as described above, since the water to be used for the next stroke is heat-exchanged with the washing water having a temperature higher than the temperature of the water, and the heat-exchanged water is supplied to the sump 10, the stroke efficiency of the next stroke, for example, the washing or rinsing efficiency There is an increasing advantage.

In addition, as the heat exchange passage 92 located in the water chamber 62 is bent one or more times, the heat exchange efficiency between the water in the water chamber 62 and the washing water of the heat exchange passage 92 is increased.

8 is a view illustrating a control method of the dish washing machine according to the second embodiment.

This embodiment is the same as that of the first embodiment in other parts, except that there is a difference in the opening timing of the heat exchange passage.

Referring to FIG. 8, when a specific stroke is started, the washing pump 70 is operated and washing of dishes is performed (S11). Then, during the specific stroke, it is determined whether the stroke is completed (S12). If it is determined that the specific stroke is completed, the washing pump 70 is stopped (S13). Then, the heat exchange passage 92 is opened by the operation of the passage adjusting device (S14). Then, the washing pump 70 is operated (S15). On the contrary, while the washing pump 70 is continuously operated after the specific stroke is completed, the heat exchange passage 92 may be opened by the operation of the passage adjusting apparatus 80. Of course, the washing water is not supplied to the plurality of washing nozzles after the specific stroke is completed.

When the heat exchange passage 92 is opened, the washing water exchanges heat with the water stored in the water chamber 62 in the course of flowing the heat exchange passage 92. It is determined whether heat exchange is completed during this process (S16). The determination of whether the heat exchange is completed may be determined based on, for example, the operating time of the washing pump 70 operated after the specific stroke is completed or the temperature of the water detected by the temperature sensor installed in the water chamber 62. In the present embodiment, it is apparent that the method for determining whether the heat exchange is completed is not limited.

When it is determined that the heat exchange is completed, the operation of the washing pump 70 is stopped, and the heat exchange passage 92 is closed (S17). Then, the drain pump 50 is operated to drain the water (S18).

9 is a bottom view of a sump according to a third embodiment, and FIG. 10 is a flowchart illustrating a control method of the dish washing machine according to the third embodiment.

First, referring to FIG. 9, the supply passage 91 of the present embodiment is connected to a drain passage 51 connected to the discharge side of the drain pump 50, and the discharge passage 93 is connected to the sump 10. It is connected to the receiving portion (11).

The drain passage 51 is provided with a first valve 53 to open and close the flow path, and the supply flow path 91 is provided with a second valve 94 to open and close the flow path.

Hereinafter, a control method of the dish washing machine according to the present embodiment will be described.

Referring to FIG. 10, when a specific stroke is started, the washing pump 70 is operated and washing of dishes is performed (S21). Then, during the specific stroke, it is determined whether the stroke is completed (S22). When it is determined that the specific stroke has been completed, the washing pump 70 is stopped. The drain passage 51 is closed and the heat exchange passage is opened (S23). Since the drain pump 50 does not operate until drainage is performed, the heat exchange flow path and the drain flow path 51 may be open. However, the drain passage 51 must be closed and the heat exchange passage must be open before the specific stroke is completed and drainage is performed.

Of course, since the washing pump 70 is operated during the specific stroke, the washing water does not flow into the heat exchange passage even if the heat exchange passage is open.

After the drain passage is closed and the heat exchange passage is opened, the drain pump 50 operates (S24). Then, the washing water of the sump 10 is moved to the heat exchange passage after passing the drain pump 50. Then, the washing water exchanges heat with the water stored in the water chamber 62 in the course of flowing the heat exchange passage. Washing water exchanged with water is introduced into the sump (10).

It is determined whether heat exchange is completed during this process (S25). When it is determined that the heat exchange is completed, the heat exchange passage is closed, and the drain passage 51 is opened (S26). At this time, the drain pump 50 is continuously operated. When the drain flow path 51 is opened, drainage is performed (S27).

11 is a bottom view of a sump according to a fourth embodiment, and FIG. 12 is a flowchart illustrating a control method of the dish washing machine according to the fourth embodiment.

First, referring to FIG. 11, the supply passage 91 of the present embodiment is connected to a first guide tube 12 for guiding the washing water to the washing pump 70, and the discharge passage 93 is the sump 10. Is connected to the receiving portion (11).

The heat exchange passage is provided with a heat exchange pump 100 to allow the washing water to flow into the heat exchange passage.

Hereinafter, a control method of the dish washing machine according to the present embodiment will be described.

Referring to FIG. 12, when a specific stroke is started, the washing pump 70 is operated and washing of dishes is performed (S31). Then, during the specific stroke, it is determined whether the stroke is completed (S32). When it is determined that the specific stroke has been completed, the washing pump 70 is stopped. Then, the heat exchange pump 100 is operated (S33). Then, the wash water of the sump (10) is moved to the heat exchange passage by the operation of the heat exchange pump (100). Then, the washing water exchanges heat with the water stored in the water chamber 62 in the course of flowing the heat exchange passage. Washing water exchanged with water is introduced into the sump (10).

It is determined whether heat exchange is completed during this process (S34). When it is determined that the heat exchange is completed, the heat exchange pump 100 stops (S35). Then, the drain pump 50 is operated to drain water (S36).

In the above embodiments, it has been described that the washing water that has undergone heat exchange is directly recovered to the sump. Alternatively, the washing water that has undergone the heat exchange may be recovered to the sump (indirectly with the sump) after being introduced into the washing tank. It is possible.

13 is a perspective view of a water supply mechanism according to a fifth embodiment.

This embodiment is the same as that of the first embodiment in other parts, but differs in the structure of the water supply mechanism. Therefore, hereinafter, only characteristic parts of the embodiment will be described.

Referring to FIG. 13, the heat exchange part 120 is in contact with one surface of the water supply mechanism 110 of the present embodiment. That is, the water supply mechanism 110 and the heat exchanger 120 are separately formed and contacted to allow mutual heat exchange.

The structure of the water supply mechanism 110 is the same as the structure of the water supply unit 60b of the first embodiment, and the structure of the heat exchange unit 120 is the same as that of the heat exchange unit 60c of the first embodiment. Will be omitted.

The heat exchanger 120 may be formed of, for example, a copper material having high thermal conductivity. Alternatively, a surface of the heat exchange part 120 that contacts the water supply mechanism 110 may be formed of a copper material. In this embodiment, it is noted that the material of the heat exchanger 120 is not limited.

10: sump 50: drain pump
60: water supply mechanism 62: water chamber
70: washing pump 90: heat exchanger tube

Claims (11)

A water supply unit for collecting water for use in cleaning; And
It includes a sump for supplying the washing water to the washing tank receiving the water of the water supply mechanism,
The water supply mechanism includes a water supply unit having a water chamber in which water is stored;
And a heat exchanger that is partitioned from the water chamber and has a heat exchange flow path for receiving the wash water of the sump to exchange heat with the water collected in the water chamber. The method of claim 1,
The water supply mechanism and the body,
And a partition for partitioning the inner space of the body into the water chamber and the heat exchange passage. The method of claim 2,
The heat exchange passage is bent at least once. The method of claim 2,
The heat exchanger dishwasher is formed with one or more guides for defining the heat exchange passage. The method of claim 1,
And a supply flow path for supplying the wash water from the sump to the heat exchange part, and a discharge flow path through which the wash water heat-exchanged with the water chamber is discharged from the heat exchange part. The method of claim 5, wherein
The dishwasher of the discharge flow path is recovered directly or indirectly to the sump. The method of claim 1,
And the wash water of the sump flows through the heat exchange passage during a specific stroke or before the specific stroke is completed and drained. The method of claim 7, wherein
Wherein said particular stroke is a washing stroke or a rinsing stroke. A water supply mechanism having a water chamber for collecting water for use in cleaning;
A sump that receives water from the water supply device and supplies washing water to a washing tank; And
And a heat exchanger in contact with the water supply mechanism and having a heat exchange flow path for receiving the wash water from the sump to exchange heat with the water collected in the water chamber. The method of claim 9,
The heat exchange part is connected to a supply flow path for supplying the wash water of the sump to the heat exchange part, and a discharge flow path for discharging the wash water heat exchanged with the water chamber in the heat exchange part,
The washing water of the discharge flow path is returned to the sump directly or indirectly into the sump. The method of claim 9,
The heat exchanger dishwasher comprises one or more guides for forming the heat exchange passage.

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