JP2019051094A - washing machine - Google Patents

Abstract

To provide a washing machine capable of efficiently washing a heat exchanger.SOLUTION: A washing machine 1 includes: a washing water tank 15 storing washing water to be used for washing a material to be washed; a detection part 40 detecting dirt of the washing water stored in the washing water tank 15; a heat exchanger 64 which condenses steam in the washing chamber 3 and exhausts air whose steam content has decreased; a washing part 66 jetting water to the heat exchanger 64; and a control part 50 controlling water supply for the washing part 66. The control part 50 controls water supply for the washing part 66 on the basis of dirt of the washing water detected by the detection part 40.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a washing machine.

  As a conventional washing machine, for example, one described in Patent Document 1 is known. A cleaning machine described in Patent Document 1 includes a main body having a cleaning chamber, a heat exchanger that discharges air in which the amount of water vapor contained is reduced by condensing water vapor in the cleaning chamber, and a cleaner device that cleans the heat exchanger And.

German Patent Application Publication No. 102007006787

  In a conventional washer, the heat exchanger is cleaned by operating a cleaner device every predetermined time. Therefore, in the conventional cleaning machine, even when the heat exchanger is not dirty, the heat exchanger is cleaned by the cleaner device. For this reason, in the conventional cleaning machine, the heat exchanger is not efficiently cleaned.

  An object of one aspect of the present invention is to provide a washing machine capable of efficiently washing a heat exchanger.

  A washing machine according to one aspect of the present invention is a washing machine for washing an object to be washed contained in a washing chamber, and a washing water tank for storing washing water used for washing the article to be washed, and a washing water tank A detection unit that detects dirt in the cleaning water stored in the heat exchanger, a heat exchanger that condenses water vapor in the cleaning chamber and discharges air with a reduced amount of water vapor, and a cleaning unit that injects water into the heat exchanger, A control unit that controls the supply of water to the cleaning unit, and the control unit controls the supply of water to the cleaning unit based on the contamination of the cleaning water detected by the detection unit.

  In the cleaning machine according to one aspect of the present invention, the control unit controls the supply of water to the cleaning unit based on the contamination of the cleaning water detected by the detection unit. Water vapor generated in the cleaning chamber adheres to the heat exchanger. For example, when oil adheres to an object to be cleaned, oil can be contained in water vapor generated from the cleaning water sprayed on the object to be cleaned. Therefore, when the washing water is dirty, it is highly possible that the heat exchanger is also dirty. Therefore, the washing machine controls the supply of water to the washing unit based on the dirt of the washing water. Thereby, in a washing machine, when a heat exchanger is dirty, water can be supplied from a washing part and a heat exchanger can be washed. Therefore, the washing machine does not wastefully wash the heat exchanger. Therefore, in the washing machine, the heat exchanger can be efficiently washed.

  In one embodiment, the control unit may supply water to the cleaning unit when the value indicating the contamination of the cleaning water detected by the detection unit is equal to or greater than a specified value. In this configuration, when the cleaning water in the cleaning water tank is dirty, the heat exchanger is cleaned. Therefore, the heat exchanger can be cleaned at an appropriate timing when the heat exchanger is contaminated.

  In one embodiment, a supply valve that supplies water to the cleaning unit may be provided, and the control unit may control opening and closing of the supply valve. In this configuration, the supply of water to the cleaning unit can be accurately controlled.

  In one aspect of the present invention, the heat exchanger can be efficiently cleaned.

FIG. 1 is a perspective view of a dishwasher according to an embodiment. Drawing 2 is a sectional view showing a schematic structure of a dishwasher concerning one embodiment. FIG. 3 is a side view showing the internal configuration of the dishwasher. FIG. 4 is a diagram showing a cross-sectional configuration of the dishwasher. FIG. 5 is a perspective view showing the heat exchange unit. FIG. 6 is a rear view showing the internal configuration of the heat exchange unit. FIG. 7 is a side view showing the internal configuration of the dishwasher with the door open. FIG. 8 is a diagram showing a cross-sectional configuration of the dishwasher. FIG. 9 is a flowchart showing the operation of the dishwasher.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same or equivalent elements will be denoted by the same reference numerals, and redundant description will be omitted. The dimensional ratios in the drawings do not necessarily match those described. In the following description, directions defined in FIG. 1 (vertical direction, front-rear direction, left-right direction (width direction)) are used for the description.

  As shown in FIGS. 1 and 2, the dishwasher 1 has a washing machine body (main body part) 2 covered with a stainless steel panel. The cleaning machine main body 2 is partitioned into an upper portion 2A in which the cleaning chamber 3 is formed and a lower portion 2B in which the machine chamber 4 is formed. A column 6 extending in the vertical direction across the upper portion 2A and the lower portion 2B is disposed in the corner portion on the back side of the cleaning machine body 2, and a back panel (one side portion) 5 is disposed between the columns 6 and 6. Is arranged.

  A box-shaped door 7 for opening and closing the cleaning chamber 3 is provided on the upper portion 2 </ b> A of the cleaning machine body 2. The door 7 is guided by a pair of stainless steel columns 6 and 6 so as to be movable up and down, and is moved up and down by a handle 8A extending horizontally in front. The ends of a pair of left and right rotating arms 8B, 8B are fixed to both ends of the handle 8A, and the rotating arms 8B, 8B are disposed obliquely along the side surface 7A of the door 7. One end of a link portion 8C disposed along the side surface 7A of the door 7 is rotatably connected to the rotation arms 8B and 8B, and the other end of the link portion 8C is connected to the door 7 via a shaft pin 8D. The door 7 is vertically movable with respect to the rotational movement of the handle 8A. Legs 9 are attached to the four corners of the bottom surface of the cleaning machine main body 2.

  As shown in FIG. 4, a seal portion 42 is provided on the ceiling surface 7 s of the door 7. The seal part 42 is arranged at the rear part on the ceiling surface 7 s of the door 7. The seal part 42 protrudes downward from the ceiling surface 7s. The seal portion 42 extends along the width direction of the cleaning machine main body 2. The back panel 5 is provided with a seal portion 44. The seal portion 44 is disposed on the upper portion of the back panel 5. The seal portion 44 projects forward from the back panel 5. The front end portion of the seal portion 44 is located close to the lower end portion of the seal portion 42. The seal portion 44 extends along the width direction of the cleaning machine main body 2. In the cleaning machine main body 2, when the door 7 is in a closed state, the water vapor in the cleaning chamber 3 is prevented from leaking from between the door 7 and the back panel 5 to the outside by the seal portion 42 and the seal portion 44.

  As shown in FIG. 2, a rack rail 11 is detachably arranged in the cleaning chamber 3, and dishes (washing objects) such as dishes and teacups after eating and drinking are arranged on the rack rail 11. A grid-like tableware rack is placed. In the upper part of the cleaning chamber 3, an upper cleaning nozzle 12A composed of three arms extending radially and an upper rinse nozzle 13A composed of two arms are rotatably arranged. Similarly, a lower cleaning nozzle 12B composed of three arms extending radially and a lower rinse nozzle 13B composed of two arms are rotatably disposed in the lower part of the cleaning chamber 3. Washing water is sprayed from above and below by the upper cleaning nozzle 12A and the lower cleaning nozzle 12B, and the rinsing water is sprayed from above and below by the rinsing nozzles 13A and 13B.

  A cleaning water tank 15 is provided at the bottom of the cleaning chamber 3 so as to protrude into the machine chamber 4. A filter 18 is detachably disposed between the cleaning chamber 3 and the cleaning water tank 15. The cleaning water tank 15 is provided with a dirt sensor (detection unit) 40. The dirt sensor 40 detects the dirt of the cleaning water in the cleaning water tank 15. The dirt sensor 40 includes, for example, a light projecting unit and a light receiving unit. In this configuration, the dirt sensor 40 detects the transmittance of the cleaning water. In the dirt sensor 40, the light projecting unit irradiates the cleaning water with light, and the light receiving unit receives the light transmitted through the cleaning water. When the cleaning water is dirty, the light receiving intensity of the light receiving unit is lowered. The dirt sensor 40 outputs a detection signal indicating the received light intensity of the light receiving unit to the controller 50 described later. In addition, the dirt sensor 40 may be a sensor that detects the ease of passing cleaning water through electricity. The dirt sensor 40 may be a turbidimeter.

  A cleaning pump 23 is connected to the front wall of the cleaning water tank 15 via a cleaning water suction port. A cleaning water discharge pipe 21 is connected to the discharge port of the cleaning pump 23. The cleaning water discharge pipe 21 branches into a first cleaning water discharge pipe 21A and a second cleaning water discharge pipe 21B, and the first cleaning water discharge pipe 21A is connected to the upper cleaning nozzle 12A, and the second cleaning water discharge pipe 21B is connected to the lower cleaning nozzle 12B.

  A rinsing water tank 25 to which rinsing water is supplied from the outside via a water supply pipe (not shown) is disposed in the machine room 4. A rinse pump 27 is connected to the rinse water tank 25 via a rinse water suction pipe 29. A rinse water discharge pipe 31 is connected to the discharge port of the rinse pump 27. The rinse water discharge pipe 31 branches into a first rinse water discharge pipe 31A and a second rinse water discharge pipe 31B, and the first rinse water discharge pipe 31A is connected to the upper rinse nozzle 13A, and the second rinse water discharge pipe 31B is connected to the lower rinse nozzle 13B. The first rinse water discharge pipe 31A is disposed in the first cleaning water discharge pipe 21A. That is, the first cleaning water discharge pipe 21A and the first rinse water discharge pipe 31A have a double pipe structure.

  Housed in the machine room 4 is an electrical box (not shown) in which a controller (control unit) 50 for controlling the overall operation of the dishwasher 1 is incorporated. The controller 50 controls the supply of water to the cleaning nozzle 66 of the heat exchange unit 60 described later. Specifically, the controller 50 controls opening and closing of a supply valve 66b provided in a water supply pipe 66a that supplies water to the cleaning nozzle 66 based on a detection signal output from the dirt sensor 40.

  The controller 50 supplies water to the cleaning nozzle 66 when the value indicating the contamination of the cleaning water detected by the contamination sensor 40 is equal to or greater than a specified value. In this embodiment, when the value of the received light intensity indicated by the detection signal of the dirt sensor 40 is equal to or less than the threshold value, it is determined that the value indicating the dirt of the cleaning water is equal to or greater than the specified value. The controller 50 opens the supply valve 66b when the value of the received light intensity indicated by the detection signal of the dirt sensor 40 is not more than the threshold value. That is, the controller 50 opens the supply valve 66b when the cleaning water becomes dirty and the cleaning water permeability decreases. The specified value and threshold value are appropriately set based on tests and experiments. When the controller 50 opens the supply valve 66b, water is supplied to the cleaning nozzle 66 through the water supply pipe 66a, and water is jetted from the cleaning nozzle 66 to the heat exchanger 64.

  As shown in FIG. 3, the cleaning machine main body 2 has an exhaust port 2 </ b> H that exhausts water vapor in the cleaning chamber 3. The exhaust port 2H is formed through the back panel 5 in the thickness direction (front-rear direction). The exhaust port 2 </ b> H is disposed at the upper end of the back panel 5 of the cleaning machine body 2. Specifically, the exhaust port 2 </ b> H is disposed below the seal portion 44. The exhaust port 2 </ b> H extends along the width direction of the cleaning machine body 2.

  As shown in FIG. 4, the cleaning machine body 2 has a cover 70. The cover 70 is disposed at a position overlapping with at least a part of the exhaust port 2H when viewed from the front of the exhaust port 2H. In the present embodiment, viewing from the front means viewing from the front of the washing machine body 2 (viewing along the front-rear direction). The cover 70 has a first inclined portion 72 and a second inclined portion 74. The cover 70 has a substantially V-shaped cross section. The first inclined portion 72 and the second inclined portion 74 are plate members. The first inclined portion 72 and the second inclined portion 74 are integrally formed.

  The first inclined portion 72 is attached to the back panel 5. Specifically, the base end portion of the first inclined portion 72 is attached to the lower portion of the exhaust port 2H in the back panel 5 provided with the exhaust port 2H. The 1st inclination part 72 inclines so that the front-end | tip part (other end part) connected with the 2nd inclination part 74 may become downward rather than a base end part. The second inclined portion 74 is connected to the distal end portion of the first inclined portion 72. The second inclined portion 74 is inclined with respect to the exhaust port 2H. Specifically, the second inclined portion 74 is inclined such that the upper end portion is separated from the exhaust port 2H than the lower end portion (so that the interval with the exhaust port 2H is increased). The second inclined portion 74 overlaps at least a part of the exhaust port 2H when viewed from the front side of the exhaust port 2H.

  The cover 70 is provided with a through hole 78 in a connecting portion 76 between the first inclined portion 72 and the second inclined portion 74. That is, the through hole 78 is provided at the lowest position of the cover 70. The through hole 78 is formed through the connecting portion 76 in the thickness direction. A plurality of through holes 78 are provided at predetermined intervals in the longitudinal direction of the cover 70. The through hole 78 may be a long hole extending along the longitudinal direction of the cover 70.

  As shown in FIGS. 1 and 3, the dishwasher 1 includes a heat exchange unit 60. The heat exchange unit 60 includes a housing 62, a heat exchanger 64, a cleaning nozzle (cleaning unit) 66, and an exhaust fan 68. The heat exchange unit 60 condenses the water vapor discharged from the cleaning chamber 3 of the main body 2 of the cleaning machine, and discharges the air with the reduced amount of water vapor to the outside. In the heat exchange unit 60, the heat exchanger 64, the cleaning nozzle 66, and the exhaust fan 68 are arranged in this order from the upstream side in the path through which water vapor (air) flows.

  The housing 62 accommodates the heat exchanger 64, the cleaning nozzle 66 and the exhaust fan 68. The housing 62 is a box-shaped member. The casing 62 constitutes a flow path (duct) through which the water vapor exhausted from the cleaning chamber 3 is circulated and air in which the amount of the water vapor heat-exchanged by the heat exchanger 64 is reduced is circulated. The casing 62 is fixed to the back panel 5 of the cleaning machine body 2. Specifically, brackets 62 a and 62 b (see FIG. 5) provided at the lower end portion of the housing 62 are fixed to the upper end portion of the back panel 5 of the cleaning machine body 2. The housing 62 extends in the vertical direction on the back side of the cleaning machine body 2.

  As shown in FIG. 5, the housing 62 has an intake port 63 a and an exhaust port 63 b (see FIG. 3). The intake port 63 a takes in water vapor into the housing 62. The intake port 63 a is provided in the lower part of the housing 62. It is connected to an exhaust port 2H provided in the back panel 5 of the cleaning machine body 2. Thereby, the cleaning chamber 3 and the housing 62 of the cleaning machine main body 2 communicate with each other.

  The discharge port 63b discharges air having a reduced water vapor content to the outside. The discharge port 63 b is provided in the upper part of the housing 62. The discharge port 63b communicates with the intake port 63a. A grill 61 (see FIGS. 1 and 3) is disposed in the discharge port 63b. Since the exhaust fan 68 is covered by the grill 61, it is possible to prevent an operator or the like from coming into contact with the exhaust fan 68.

  The housing 62 has a front wall (cooling surface) 62s. The front wall 62 s is one side surface constituting the housing 62 and is located in front of the housing 62. As shown in FIG. 7, the front wall 62 s is a surface on which the opening of the rear portion of the door 7 faces when the door 7 is opened. The front wall 62s has thermal conductivity. In the present embodiment, the front wall 62s is close to or in contact with the heat exchanger 64. Thereby, when water is supplied to the heat exchanger 64 and the heat exchanger 64 is cooled, the front wall 62s is also cooled. The front wall 62s is at a temperature lower than that of water vapor when the door 7 is opened. Therefore, in this embodiment, water is supplied to the heat exchanger 64 when the door 7 is opened. The front wall 62s comes into contact with the water vapor discharged from the opening of the door 7 and condenses the water vapor. Thereby, the water vapor condenses into water (water droplets).

  As shown in FIG. 8, the lower end portion of the front wall 62 s is located above the seal portion 44. Thereby, the water generated in the front wall 62s flows downward along the front wall 62s, and falls from the front wall 62s to the seal portion 44. The water dropped on the seal portion 44 flows along the inclination of the seal portion 44 and is discharged to the cleaning chamber 3. That is, the front wall 62 s and the seal portion 44 constitute a discharge path for discharging water generated on the front wall 62 s to the cleaning chamber 3.

  The heat exchanger 64 has fins and flow path pipes (both not shown). As shown in FIG. 6, a water supply pipe 64a is connected to one end of the flow path pipe. The water supply pipe 64a supplies water to the flow path pipe. Water is supplied to the water supply pipe 64a from a water source such as a water supply (not shown). A drain pipe 64b is connected to the other end of the flow path pipe. The drain pipe 64b discharges the water that has passed through the flow path pipe. The drain pipe 64 b is connected to the rinse water tank 25. That is, the water flowing through the flow path pipe of the heat exchanger 64 is discharged to the rinse water tank 25. The heat exchanger 64 is in contact with water vapor flowing through the housing 62. The heat exchanger 64 performs heat exchange between water flowing through the flow path pipe and water vapor.

  The cleaning nozzle 66 is disposed in the casing 62 on the downstream side of the water vapor (air) from the heat exchanger 64 (upper part of the heat exchanger 64). A water supply pipe 66 a is connected to the cleaning nozzle 66. The water supply pipe 66a is connected to the same water source as the water supply pipe 64a. Alternatively, water is supplied from the rinse water tank 25 to the water supply pipe 66a. The water supply pipe 66 a is provided with a supply valve 66 b that supplies water to the cleaning nozzle 66. The supply valve 66b is controlled to be opened and closed by the controller 50. By opening the supply valve 66b, water is supplied to the cleaning nozzle 66 through the water supply pipe 66a. Thereby, the washing nozzle 66 injects water to the heat exchanger 64. Therefore, the heat exchanger 64 and the water vapor flow path leading to the heat exchanger 64 can be washed. The water sprayed from the cleaning nozzle 66 is discharged into the cleaning chamber 3 of the cleaning machine body 2 through the intake port 63a of the housing 62 and the exhaust port 2H of the cleaning machine body 2.

  The exhaust fan 68 is disposed in the casing 62 at the downstream portion of the water vapor (air) flow path. The exhaust fan 68 is disposed in the vicinity of the discharge port 63 b of the housing 62. Specifically, the exhaust fan 68 is disposed at the upper end portion of the housing 62 and is disposed in the duct portion 62c protruding forward. In the present embodiment, four exhaust fans 68 are provided. The exhaust fans 68 are arranged side by side along the width direction. The exhaust fan 68 is attached to the bracket 69. The number of exhaust fans 68 is set as appropriate.

  Next, the operation of the dishwasher 1 will be described with reference to FIG. First, when the power switch is turned on, the dishwasher 1 injects hot water in the hot water storage tank 28 into the washing chamber 3 by the rinse pump 34, thereby supplying hot water into the washing water tank 15. The temperature of the hot water in the hot water storage tank 28 is set to about 80 ° C., for example. Thereby, initial hot water supply is performed. Then, an amount of detergent corresponding to the initial hot water supply amount is supplied into the washing water tank 15, and the detergent concentration of the washing water in the washing water tank 15 becomes a predetermined concentration.

  After the initial hot water supply, when the user racks the tableware and closes the door 7, it is detected by a door switch (not shown) that the door is closed, and an operation start signal is input to the controller 50. When the operation start signal is input to the controller 50, the cleaning of the dishes is started (step S01). The cleaning of the dishes is performed by spraying the cleaning water in the cleaning water tank 15 toward the tableware in the cleaning chamber 3. The temperature of the cleaning water in the cleaning water tank 15 is set to be 60 ° C. to 70 ° C., for example.

  When the cleaning pump 23 is started, the cleaning water stored in the cleaning water tank 15 is pumped to the upper cleaning nozzle 12A and the lower cleaning nozzle 12B via the cleaning water discharge pipe 24 and the like, and the upper cleaning nozzle 12A. And it sprays toward the tableware in the washing room 3 from the lower side washing nozzle 12B. At this time, since the upper cleaning nozzle 12A and the lower cleaning nozzle 12B continue to rotate due to the reaction force of the jet force, the cleaning water is uniformly applied to the dishes, and the dishes are efficiently washed away.

  The washing water sprayed into the washing chamber 3 is collected in the washing water tank 15 while the remaining vegetables washed away from the dishes are removed by the filter 18. The cleaning water collected in the cleaning water tank 15 is circulated and supplied again into the cleaning chamber 3 by the cleaning pump 23. When the cleaning of the dishes with the cleaning water is performed for a predetermined time, the operation of the cleaning pump 23 is stopped. Thereby, the operation of the dishwasher 1 is temporarily stopped (step S02).

  Next, when the rinsing pump 34 is started, the rinsing water stored in the hot water storage tank 28 is pumped to the upper and lower rinsing nozzles 13A and 13B via the rinsing water discharge pipe 36, etc. It sprays toward tableware from 13A, 13B (step S03). The temperature of the rinsing water pumped from the hot water storage tank 28 is set to about 80 ° C., for example. At this time, since each of the rinsing nozzles 13A and 13B also continues to rotate due to the reaction force of the injection force, the rinsing water is uniformly applied to the tableware, and the tableware is efficiently rinsed.

  The rinsing water sprayed on the tableware is collected in the washing water tank 15 through the filter 18 and mixed with the washing water, and used as washing water in the next washing step. When rinsing water is sprayed into the cleaning chamber 3 and collected in the cleaning water tank 15, excess cleaning water exceeding a certain water level is discharged to the outside from an overflow pipe (not shown).

  When rinsing water is jetted from the upper rinsing nozzle 13 </ b> A and the lower rinsing nozzle 13 </ b> B to the tableware, water vapor is generated in the cleaning chamber 3. In the dishwasher 1 of the present embodiment, when the rinsing process is started, the exhaust fan 68 starts operating, and the water vapor generated in the cleaning chamber 3 is discharged by the exhaust fan 68 (step S04). The operation start timing of the exhaust fan 68 is not limited to this timing, and may be started from a cleaning step S01 in which water is jetted from the upper cleaning nozzle 12A and the lower cleaning nozzle 12B.

  When the water vapor is discharged from the cleaning chamber 3 by the exhaust fan 68, the water vapor is sent out to the heat exchanger 64 of the heat exchange unit 60 through the exhaust port 2H. The water vapor flows through the flow path in which the heat exchanger 64 is disposed. In the heat exchanger 64, heat exchange is performed between “water vapor” flowing through the flow path and “water” flowing through the heat exchanger 64.

  When the exhaust fan 68 is operated to collect the water vapor in the cleaning chamber 3 for a predetermined time, the operation of the exhaust fan 68 is stopped. When the operation of the exhaust fan 68 is stopped, the flow of water vapor to the heat exchanger 64 is stopped. At this time, there is almost no water vapor (steam) in the cleaning chamber 3.

  Subsequently, it is determined whether or not the cleaning water is dirty (step S05). The controller 50 determines whether or not the value indicating the contamination of the cleaning water detected by the contamination sensor 40 is equal to or greater than a specified value. In the present embodiment, the controller 50 determines whether or not the value indicating the received light intensity output from the dirt sensor 40 is equal to or less than a threshold value. If the value indicating the received light intensity is greater than the threshold value, the process ends. When the value indicating the received light intensity is equal to or less than the threshold value, the supply valve 66b of the water supply pipe 66a is opened. Thereby, water is jetted from the cleaning nozzle 66 to the heat exchanger 64 (step S06), and when the heat exchanger 64 is cleaned for a predetermined time, the supply valve 66b is closed. The water that has cleaned the heat exchanger 64 is discharged to the cleaning chamber 3 through the exhaust port 2H. The water discharged into the cleaning chamber 3 is stored in the cleaning water tank 15.

  When the cleaning of the heat exchanger 64 is completed, all the cleaning water stored in the cleaning water tank 15 is discharged (total drainage) (step S07). The total drainage is carried out for the purpose of replacing the cleaning water in the cleaning water tank 15 that becomes gradually soiled by repeated operation with clean cleaning water. When all drainage is completed, initial hot water supply is performed as described above (step S08). That is, the hot water in the hot water storage tank 28 is injected into the cleaning chamber 3 by the rinse pump 34 to supply the hot water into the cleaning water tank 15. Thus, the operation of the dishwasher 1 is completed. The tableware washing machine 1 will be in a washing reception standby state when the above operation is completed.

  Then, the effect of the dishwasher 1 of this embodiment is demonstrated. In the dishwasher 1, the controller 50 controls the supply of water to the cleaning nozzle 66 based on the contamination of the cleaning water detected by the contamination sensor 40. Water vapor generated in the cleaning chamber 3 adheres to the heat exchanger 64. For example, when oil adheres to the tableware, the oil may be contained in water vapor generated from the washing water sprayed on the tableware. Therefore, when the washing water is dirty, the heat exchanger 64 is likely to be dirty. Therefore, the dishwasher 1 controls the supply of water to the cleaning nozzle based on the contamination of the cleaning water. Thereby, in the dishwasher 1, when the heat exchanger 64 is dirty, water can be supplied from the washing nozzle 66 and the heat exchanger 64 can be washed. Therefore, the dishwasher 1 does not wastefully clean the heat exchanger 64. Therefore, in the dishwasher 1, the heat exchanger 64 can be cleaned efficiently.

  In the present embodiment, water is sprayed from the cleaning nozzle 66 to clean the heat exchanger 64, and then the cleaning water tank 15 is entirely drained. Thereby, in the dishwasher 1, tableware is not washed with the washing water containing the water which washed the heat exchanger 64. Therefore, it is possible to avoid washing the dishes with dirty washing water.

  In the present embodiment, the controller 50 supplies water to the cleaning nozzle 66 when the value indicating the contamination of the cleaning water detected by the contamination sensor 40 is equal to or greater than a specified value. In the present embodiment, when the value indicating the received light intensity output from the dirt sensor 40 is equal to or less than the threshold value, it is determined that the value indicating the cleaning water dirt detected by the dirt sensor 40 is equal to or greater than a specified value. In this configuration, the heat exchanger 64 is cleaned when the cleaning water in the cleaning water tank 15 is dirty. Therefore, the heat exchanger 64 can be cleaned at an appropriate timing when the heat exchanger 64 is contaminated.

  The dishwasher 1 according to this embodiment includes a supply valve 66 b that supplies water to the cleaning nozzle 66. The controller 50 controls opening and closing of the supply valve 66b. In this configuration, the supply of water to the scrub 66 can be controlled with high accuracy.

  In the dishwasher 1 according to the present embodiment, the water sprayed from the cleaning nozzle 66 and cleaning the heat exchanger 64 is discharged into the cleaning chamber 3 and stored in the cleaning water tank 15. In this configuration, there is no need to provide a drainage path only for discharging water sprayed from the cleaning nozzle 66. Therefore, the cost does not increase.

  The dishwasher 1 according to the present embodiment is provided so as to be movable up and down, and includes a door 7 that opens and closes the cleaning chamber 3 by moving up and down, and a housing 62 that houses a heat exchanger 64. Yes. The door 7 has an opening that faces the housing 62 when positioned above the opening of the cleaning chamber 3. The housing 62 is disposed at a position where the opening of the door 7 faces, and has a front wall 62s having a temperature lower than that of water vapor at least when the door 7 is opened. In this configuration, when the water vapor remaining in the cleaning chamber 3 is discharged from the opening of the door 7 when the door 7 is opened, the water vapor contacts the front wall 62s. The front wall 62s is lower than the temperature of the water vapor. Therefore, when the water vapor contacts the front wall 62s, the water vapor is condensed. Therefore, it can suppress that water vapor | steam is discharged | emitted outside the dishwasher 1. FIG.

  The dishwasher 1 according to the present embodiment has a discharge path for discharging water generated in the front wall 62s to the cleaning chamber 3. In the present embodiment, the discharge path is configured by the front wall 62 s and the seal portion 44. In this configuration, water (water droplets) generated by condensation on the front wall 62 s can be discharged into the cleaning chamber 3. Therefore, it is possible to prevent water from being discharged outside the dishwasher 1.

  In the dishwasher 1 according to the present embodiment, the front wall 62 s is cooled by the heat exchanger 64. The heat exchanger 64 circulates water and exchanges heat between water and water vapor. Therefore, the temperature of the heat exchanger 64 is lower than that of water vapor. Therefore, the front wall 62 s can be cooled by bringing the front wall 62 s and the heat exchanger 64 into contact or close to each other. Therefore, since it is not necessary to provide another device for cooling the front wall 62s, the configuration can be simplified.

  In the dishwasher 1 according to this embodiment, the washing machine body 2 has a cover 70. The cover 70 is provided with a through hole 78 at the lowest position. Thereby, when the water sprayed from the cleaning nozzle 66 is discharged from the exhaust port 2 </ b> H, it is discharged to the cleaning chamber 3 through the through hole 78. Therefore, when the water is discharged into the cleaning chamber 3 from the exhaust port 2H, the cover 70 can suppress the water from adhering to the tableware.

  As mentioned above, although embodiment of this invention has been described, this invention is not necessarily limited to embodiment mentioned above, A various change is possible in the range which does not deviate from the summary.

  In the embodiment described above, an example in which the initial hot water supply (step S08) is performed after the total drainage (step S07) has been described as an example. However, rinsing may be performed after all drainage. That is, after the total drainage, the rinse pump 34 may be started and the rinse water may be jetted from the upper and lower rinse nozzles 13A and 13B. At this time, the water is discharged from the washing water tank 15. Thereby, the washing water tank 15 after all drainage can be washed.

  In the said embodiment, after wash | cleaning the heat exchanger 64, the form which drains all the washing water tanks 15 was demonstrated to an example. However, the timing for cleaning the heat exchanger 64 is not limited to this. For example, when all the drainage of the washing water tank 15 is performed by opening / closing the drain valve or using a drain pump, the heat exchanger 64 is washed when the drain valve opens or when the drain pump starts operating. May start. For example, when all the drainage of the washing water tank 15 is performed by pulling out the overflow pipe, the heat exchanger 64 has a timing when a water level sensor (not shown) detects a drop in the washing water level in the washing water tank 15. Washing may begin.

  In the embodiment described above, an example in which the front wall 62 s constituting one side surface of the housing 62 is a cooling surface has been described. However, the cooling surface may be a surface constituted by another member disposed on the front surface of the housing 62.

  In the above-described embodiment, the mode in which the front wall 62s of the housing 62 is cooled by the heat exchanger 64 has been described as an example. However, the front wall 62s may be cooled by another device (for example, a Peltier module or the like).

  In the above embodiment, as shown in FIG. 9, when the value indicating the light receiving intensity of the dirt sensor 40 is equal to or greater than a specified value, the heat exchanger 64 is cleaned, and then all the waste water in the cleaning water tank 15 is discharged. The form to perform was demonstrated to an example. However, the heat exchanger 64 may be cleaned when the entire drainage of the cleaning water tank 15 has been performed a predetermined number of times (for example, two or three times). In this case, in the flowchart of FIG. 7, it may be determined whether or not the total drainage of the washing water tank 15 has been performed more than the specified number of times before the step S05. The heat exchanger 64 progresses dirt more slowly than the washing water stored in the washing water tank 15. Therefore, even when the heat exchanger 64 is cleaned when the drainage of the cleaning water tank 15 has been performed a predetermined number of times, it can be cleaned at an appropriate timing according to the degree of contamination of the heat exchanger 64.

  In the above-described embodiment, an example in which the supply of water to the cleaning nozzle 66 is controlled based on the detection result of the dirt sensor 40 has been described. However, when the cumulative number of operations (the number of operations refers to the number of cycles when the washing process and the rinsing process of the tableware are one cycle) reaches a specified number, water is supplied to the cleaning nozzle 66. The heat exchanger 64 may be cleaned. As the number of operations increases, the cleaning water in the cleaning water tank 15 becomes dirty. That is, the number of operations and the degree of contamination of the cleaning water are proportional. Therefore, by supplying water to the cleaning nozzle 66 when the cumulative number of operations reaches the specified number, cleaning can be performed at an appropriate timing according to the degree of contamination of the heat exchanger 64.

  In the above-described embodiment and the above-described modification, the dishwasher of the type in which the door 7 opens and closes is described as an example. However, the present invention is an undercounter tableware in which a door is provided on the front wall of the cleaning room. The present invention can also be applied to a washing machine or a conveyor-type dish washing machine that performs washing while conveying a rack for storing dishes.

  In the above embodiment, the exhaust fan 68 is taken as an example of means for discharging water vapor from the cleaning chamber 3, but is not limited to this as long as water vapor can be sent from the cleaning chamber 3 to the heat exchange unit 60.

  In the said embodiment, in the heat exchange unit 60, it demonstrated to an example in the form which condensed the water vapor | steam discharged | emitted from the washing | cleaning chamber 3 of the washing machine main body 2, and discharged | emitted the air in which the inclusion amount of water vapor | steam decreased outside. However, the air whose water vapor content is reduced may be returned to the cleaning chamber 3. That is, a circulation type heat exchange unit may be used.

  The present invention may appropriately combine the contents described in the above embodiment, the above modified examples, and other modified examples without departing from the spirit of the invention.

  DESCRIPTION OF SYMBOLS 1 ... Tableware washing machine, 3 ... Cleaning room, 7 ... Door, 15 ... Washing water tank, 40 ... Dirt sensor (detection part), 50 ... Controller (control part), 62 ... Case, 62s ... Front wall (cooling surface) ), 64... Heat exchanger, 66... Cleaning nozzle (cleaning section), 66 b.

Claims (3)

A washing machine for washing an object to be washed contained in a washing room,
A cleaning water tank for storing cleaning water used for cleaning the object to be cleaned;
A detection unit for detecting dirt of the cleaning water stored in the cleaning water tank;
A heat exchanger that condenses water vapor in the cleaning chamber and discharges air with a reduced amount of water vapor contained therein;
A cleaning unit for injecting water into the heat exchanger;
A control unit for controlling the supply of the water to the cleaning unit,
The said control part is a washing machine which controls supply of the said water to the said washing | cleaning part based on the stain | pollution | contamination of the said washing water detected by the said detection part.   The cleaning device according to claim 1, wherein the control unit supplies the water to the cleaning unit when a value indicating the contamination of the cleaning water detected by the detection unit is a specified value or more. A supply valve for supplying the water to the cleaning unit;
The washing machine according to claim 1 or 2, wherein the control unit controls opening and closing of the supply valve.

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