JP6712464B2 - washing machine - Google Patents

Description

The present invention relates to a washing machine for washing items to be washed such as dishes.

2. Description of the Related Art A washing machine for washing an object to be washed such as tableware stored in a washing room of a main body is known. In such a washing machine, water vapor is generated at the time of washing the article to be washed and rinsing the article to be washed. The washing machine disclosed in Patent Document 1 includes a suction unit that sucks water vapor generated in the washing chamber, and a heat exchanger that dehumidifies and cools the sucked water vapor.

JP-A 1-222732

In the heat exchanger, it is necessary to circulate the steam a plurality of times in the heat exchanger in order to recover the heat of the steam. Therefore, in the conventional heat exchanger, it takes time to recover the heat of steam.

Therefore, an object of the present invention is to provide a washing machine capable of improving the heat recovery rate of water vapor.

A cleaning machine according to the present invention is a cleaning machine for cleaning an object to be cleaned housed in a cleaning chamber, and an exhaust unit for exhausting steam in the cleaning chamber, and a condensing unit for condensing steam discharged from the exhaust unit. And a heat exchanger having a housing in which the condenser is housed, and the flow path of the water vapor in which the condenser contacts the water vapor has a meandering shape.

In the washer having this configuration, since the water vapor passage has a meandering shape, the length of the passage can be secured without enlarging the heat exchanger. Thereby, the water vapor and the condenser can be effectively brought into contact with each other. Therefore, the condenser can efficiently recover the heat of the steam. Therefore, the washing machine can improve the heat recovery rate of water vapor. As a result, in the washing machine, the time for recovering the heat of steam can be shortened.

In the washing machine according to the present invention, a washing water storage unit for storing rinsing water used for rinsing the object to be washed is provided, and the condensing unit is provided in the feeding unit for circulating the feeding water supplied to the feeding water storage unit and the feeding unit. The housing may have a plurality of partition portions that form a meandering flow path together with the fins. In the washer having such a structure, the meandering flow path can be formed with a simple structure.

The cleaning machine according to the present invention may include an exhaust fan that exhausts water vapor from the cleaning chamber. In the washing machine having such a configuration, the water vapor can be more reliably exhausted from the washing chamber. Further, in the washing machine, even when the exhaust fan having a narrow air flow width is used and the flow path width is adapted to the air flow width of the exhaust fan, the meandering flow path can ensure the heat exchange amount. Therefore, in the washing machine, the exhaust fan can be downsized while ensuring the heat recovery rate of water vapor.

According to the present invention, the heat recovery efficiency of water vapor can be improved.

It is a perspective view of the dishwasher which concerns on one Embodiment. It is a figure which shows schematic structure of the dishwasher of FIG. It is a perspective view which shows the state which the top plate of the dishwasher of FIG. 1 removed. It is an exploded perspective view of a heat exchanger. (A) is a top view of the main body of the housing of a heat exchanger, (b) is a side view of the main body of the housing of a heat exchanger. (A) is a plan view of the lid of the heat exchanger housing, (b) is a side view of the lid of the heat exchanger housing, and (c) is a front view of the lid of the heat exchanger housing. It is a figure. It is a figure which shows the exhaust flow path of a heat exchanger.

Hereinafter, a dishwasher (washer) according to an embodiment will be described with reference to the drawings. In the description of the drawings, the same or corresponding elements will be denoted by the same reference symbols, without redundant description. The dimensional ratios in the drawings do not necessarily match. For convenience of explanation, the front-rear direction, the left-right direction, and the up-down direction are set in FIG.

As shown in FIG. 1, the dishwasher 1 according to the embodiment is an undercounter type washer having a door 4 provided in front of a washing chamber 2A. As shown in FIGS. 1 and 2, the dishwasher 1 includes a main body 2, an upper cleaning nozzle 5, an upper rinsing nozzle 6, a lower cleaning nozzle 7, a lower rinsing nozzle 8, and a cleaning tank. 9, a hot water storage tank (water supply storage section) 18, a detergent supply pump 32, a rinse agent supply pump 37, and a heat exchanger 80.

The main body 2 is formed of a stainless steel panel. The main body 2 includes a cleaning chamber 2A having an opening toward the front for taking in and out a rack in which dishes (objects to be cleaned) D are set, a drainage pump 52, a hot water storage tank 18, and a microcomputer (hereinafter referred to as "microcomputer"). )) 55 etc. are provided in the machine room 2B. Legs 3 are attached to the four corners of the bottom surface of the main body 2.

A door 4 for loading and unloading the tableware D into and from the cleaning chamber 2A is attached to the main body 2. A rack rail 2C is provided in the cleaning chamber 2A, and a tableware rack (not shown) in which the tableware D is arranged is placed on the rack rail 2C. An operation panel 2D for a user to input a driving mode and various settings is provided above the door 4 on the front surface of the main body 2.

A top plate 2E is provided on the top of the main body 2. The top plate 2E constitutes the upper part of the dishwasher 1. As shown in FIG. 3, the top plate 2E is detachably provided on the main body 2. The top plate 2E has locking holes (not shown) that are locked to the locking portions 2F and 2G arranged in a pair on the left and right on the upper surface of the main body 2. The top plate 2E is locked to the locking portions 2F and 2G, and is fixed to the main body 2 with a screw (not shown). With this configuration, the top plate 2E is attachable to and detachable from the main body 2 by attaching or removing screws.

The upper cleaning nozzle 5 and the upper rinsing nozzle 6 are provided above the cleaning chamber 2A. The upper cleaning nozzle 5 includes three radially extending arms and is rotatably arranged. The upper rinse nozzle 6 includes two arms and is rotatably arranged. The lower cleaning nozzle 7 and the lower rinsing nozzle 8 are provided below the cleaning chamber 2A. The lower cleaning nozzle 7 includes three radially extending arms and is rotatably arranged. The lower rinsing nozzle 8 includes two arms and is rotatably arranged.

On the tableware D arranged in the tableware rack, cleaning water is sprayed from above and below by the upper cleaning nozzle 5 and the lower cleaning nozzle 7 in the cleaning step, and rinsed from above and below by the upper rinsing nozzle 6 and the lower rinsing nozzle 8 in the rinsing step. Water is sprayed.

An exhaust port (exhaust part) 63 is provided in the cleaning chamber 2A. The exhaust port 63 is provided on the upper surface of the cleaning chamber 2A, for example. In the cleaning chamber 2A, water vapor (including steam) is generated in the rinsing step and the like described later. The exhaust port 63 communicates with an exhaust hole 92 of the heat exchanger 80 described later. The water vapor in the cleaning chamber 2A is sent to the heat exchanger 80 via the exhaust port 63 provided in the upper part of the cleaning chamber 2A.

The cleaning tank 9 is arranged below the cleaning chamber 2A and stores cleaning water. The cleaning tank 9 is provided with a water level detection switch 10 for detecting the water level of the cleaning water. The water level detection switch 10 is a switch that is turned on when the water level in the cleaning tank 9 exceeds a predetermined water level H and turned off when the water level is below the predetermined water level H.

A cleaning pump 14 is connected to a side surface of the cleaning tank 9 via a cleaning water suction pipe 13. A pump filter 12 is provided at a portion of the cleaning tank 9 to which the cleaning water suction pipe 13 is attached. A cleaning water discharge pipe 15 is connected to the discharge port of the cleaning pump 14. The cleaning water discharge pipe 15 is branched into a first cleaning water discharge pipe 16 and a second cleaning water discharge pipe 17. The first cleaning water discharge pipe 16 is connected to the upper cleaning nozzle 5. The second cleaning water discharge pipe 17 is connected to the lower cleaning nozzle 7.

A drain pipe 50 is connected to the bottom portion 9A of the cleaning tank 9 via a drain suction pipe 9B. The drain pipe 50 is provided with a drain pump 52 that drains the drain from the cleaning tank 9. The operation of the drainage pump 52 is controlled by the microcomputer 55. The water stored in the cleaning tank 9 is discharged to the outside through the drain pipe 50 by the drain pump 52. When the drainage pipe 50 discharges the drainage below the drainage suction pipe 9B, the drainage pump 52 may not be provided.

As shown in FIG. 1, the heat exchanger 80 is arranged above the cleaning chamber 2A. The heat exchanger 80 is housed in the top plate 2E. As shown in FIG. 3, the heat exchanger 80 is exposed by removing the top plate 2E. As shown in FIG. 4, the heat exchanger 80 has a condensing part 81 and a housing 82 that houses the condensing part 81. The heat exchanger 80 is a device that exchanges heat between the water vapor flowing through the exhaust passage F and the water flowing through the water supply passage pipe 84, which will be described later.

As shown in FIG. 7, the condensing part 81 has a water supply flow path pipe (supply part) 84, fins 85, and support parts 86 and 87.

The water supply flow passage pipe 84 is a pipe passage member having a circular cross-sectional shape orthogonal to the flow passage direction. Rinsing water to be supplied to the hot water storage tank 18 flows through the hollow portion of the water supply passage pipe 84. The water supply flow path pipe 84 constitutes a part of a supply unit that circulates the water supplied to the hot water storage tank 18. The water supply flow path pipe 84 condenses water vapor flowing through the exhaust flow path F. In the present embodiment, the water supply flow path pipe 84 is formed in a meandering shape in a plan view. Specifically, the water supply flow path pipe 84 has a linear portion that extends linearly and a folded portion that connects the linear portions to each other. As shown in FIG. 7, the water supply flow path pipes 84 are arranged at a predetermined interval in a direction orthogonal to the flow path direction of the straight line portion of the water supply flow path pipe 84.

Examples of the water supply flow path pipe 84 are a flexible pipe made of copper and coated with corrosion resistance, a flexible pipe made of stainless steel, a fin tube having fins provided on the outer circumference of the pipe, and a spiral shape on the outer circumference of the pipe. Included are fin tubes with wound fins, and the like. One end 84A of the water supply passage pipe 84 is connected to a water supply pipe 21C described later, and the other end 84B of the water supply passage pipe 84 is connected to a water supply pipe 21D described later.

The fins 85 are, for example, aluminum plate materials. The fins 85 are provided so that their surfaces are orthogonal to the flow path direction of the straight line portion of the water supply flow path pipe 84. The fins 85 are arranged at a predetermined interval in the extending direction of the straight portion of the water supply flow path pipe 84. The fins 85 are provided integrally with the water supply flow path pipe 84. The number of fins 85 may be set appropriately according to the design. The fins 85 are preferably formed of a material having high thermal conductivity.

Each of the support portion 86 and the support portion 87 is arranged at the end of the straight portion of the water supply flow path pipe 84 in the extending direction. Each of the support portion 86 and the support portion 87 has a substantially U-shaped cross section, and is formed by bending a plate member. The support part 86 and the support part 87 are arranged such that the extending direction thereof is orthogonal to the flow path direction of the straight line portion of the water supply flow path pipe 84. The support portion 86 and the support portion 87 are provided integrally with the water supply flow path pipe 84. That is, in the condensing part 81, the water supply flow path pipe 84, the fins 85, and the supporting parts 86, 87 are unitized.

The housing 82 has a main body 90 and a lid 91. The main body 90 is a box-shaped member having an open top. The main body 90 has a bottom portion 90a and four side portions 90b, 90c, 90d, 90e. The side portion 90b and the side portion 90c are arranged to face each other. The side portion 90d and the side portion 90e are arranged to face each other. The bottom portion 90a and the side portions 90b to 90e form a rectangular accommodation space that accommodates the condenser portion 81.

As shown in FIG. 7, an exhaust hole 92 is provided in the bottom 90a. The exhaust hole 92 is arranged at one corner of the bottom 90a. The exhaust hole 92 has a circular shape and is formed to penetrate the bottom portion 90a. The exhaust hole 92 communicates with the exhaust port 63 in a state where the heat exchanger 80 is arranged above the cleaning chamber 2A.

A partition portion 93 is provided on the side portion 90b. The partition part 93 is a plate member and is integrally formed with the side part 90b. The partition part 93 is arranged on the side part 90d side so that the exhaust hole 92 is located between the partition part 93 and the side part 90b. The partition portion 93 extends inward from the inner surface of the side portion 90b in the direction in which the side portions 90b and 90c face each other (hereinafter referred to as the "first direction"). The upper end of the partition part 93 is at the same height position as the upper end of the side part 90b.

A partition portion 94 is provided on the side portion 90c. The partition portion 94 is a plate member and is integrally formed with the side portion 90c. The partition portion 94 is arranged on the side portion 90e side so that the discharge portion 101 described later is located between the partition portion 94 and the side portion 90e. The partition portion 94 extends inward from the inner surface of the side portion 90c in the first direction. The upper end of the partition portion 94 is at the same height position as the upper end of the side portion 90c.

The side portion 90d is provided with a positioning portion 95 and a positioning portion 96. The positioning portion 95 and the positioning portion 96 are plate members and are integrally formed with the side portion 90d. The positioning portion 95 is arranged on the side portion 90c side. The positioning portion 96 is arranged on the side portion 90b side. The positioning part 95 and the positioning part 96 are arranged at a predetermined interval in the first direction. Specifically, the distance between the positioning portion 95 and the positioning portion 96 is equal to the length of the support portion 86 of the condensing portion 81. The positioning portion 95 and the positioning portion 96 extend inward from the inner surface of the side portion 90d along the facing direction of the side portion 90d and the side portion 90e (hereinafter, referred to as "second direction"). The upper ends of the positioning portion 95 and the positioning portion 96 are at the same height position as the upper ends of the side portions 90d.

A positioning part 97 and a positioning part 98 are provided on the side part 90e. The positioning part 97 and the positioning part 98 are plate members and are integrally formed with the side part 90e. The positioning portion 97 is arranged on the side portion 90c side. The positioning portion 98 is arranged on the side 90b side. The positioning part 97 and the positioning part 98 are arranged at a predetermined interval in the first direction. Specifically, the distance between the positioning part 97 and the positioning part 98 is equal to the length of the support part 87 of the condensing part 81. The positioning part 97 and the positioning part 98 are arranged at the same positions as the positioning part 95 and the positioning part 96 in the second direction. The positioning part 97 and the positioning part 98 extend inward from the inner surface of the side part 90e along the second direction. The upper ends of the positioning portion 97 and the positioning portion 98 are at the same height as the upper ends of the side portions 90e.

A first groove 99 and a second groove 100 are provided on the side portion 90e. The first groove 99 and the second groove 100 are arranged between the positioning portion 97 and the positioning portion 98 with a predetermined gap in the first direction. The first groove 99 and the second groove 100 are formed to penetrate the side portion 90e in the thickness direction. The first groove 99 and the second groove 100 extend downward from the upper ends of the side portions 90e. In the present embodiment, the bottom portion of the second groove 100 is located below the bottom portion of the first groove 99. The other end 84B of the water supply flow path pipe 84 is located in the first groove 99. One end 84A of the water supply flow path pipe 84 is located in the second groove 100.

As shown in FIGS. 4 and 7, the main body 90 is provided with a discharge portion 101. The discharge part 101 is arranged at a position diagonal to the exhaust hole 92 of the bottom part 90a. The discharge part 101 is connected to the exhaust path 65 and is provided integrally with the exhaust path 65. The discharge part 101 is provided so as to project outward from the side part 90c.

An exhaust fan 60 is arranged in the discharge section 101. Specifically, the exhaust fan 60 is housed in the housing section 102 of the discharge section 101. The exhaust fan 60 sucks the air in the housing 82 and discharges it to the exhaust passage 65. The housing portion 102 is provided with a positioning portion 103a and a positioning portion 103b. The positioning portions 103a and 103b define the position of the exhaust fan 60 in the housing portion 102. The exhaust fan 60 is positioned and housed in the housing part 102 by the positioning parts 103a and 103b. The exhaust fan 60 is not fixed (joined) in the housing portion 102. Therefore, the exhaust fan 60 is detachable in the housing section 102. Specifically, the exhaust fan 60 can be attached and detached by sliding it vertically in the housing portion 102.

The discharge part 101 is provided with a bottom part 104 formed over a part of the bottom part 90a. The surface of the bottom portion 104 is provided at a position lower than the surface of the bottom portion 90a. As shown in FIG. 5B, the bottom portion 104 is inclined downward from the main body 90 of the housing 82 toward the exhaust passage 65. The bottom 104 is provided with a groove 104A. The groove 104A is formed from the end of the bottom portion 104 on the main body 90 side to the end on the exhaust passage 65 side. That is, the groove 104A is also formed in the lower portion of the housing portion 102.

The condenser 81 is housed in the main body 90. Specifically, the support part 86 of the condensing part 81 is arranged between the positioning part 95 and the positioning part 96. The support portion 87 of the condenser portion 81 is arranged between the positioning portion 97 and the positioning portion 98. One end 84A of the water supply passage pipe 84 is arranged in the second groove 100, and the other end 84B of the water supply passage pipe 84 is arranged in the first groove 99. With this configuration, the condenser 81 is positioned and arranged in the main body 90. The condenser 81 is not fixed (joined) to the main body 90. Therefore, the condensing part 81 is detachable in the main body 90. Specifically, the condensing part 81 can be attached and detached by sliding the support parts 86 and 87 in the vertical direction along the positioning parts 95 to 98 in the main body 90. At this time, one end 84A and the other end 84B of the water supply flow path pipe 84 slide vertically along the first groove 99 and the second groove 100.

As shown in FIG. 6, the lid 91 has a first portion 105 that closes the accommodation space of the condensation portion 81 in the main body 90, and a second portion 106 that closes the discharge portion 101. The first portion 105 and the second portion 106 are integrally formed. The lid 91 is fixed to the main body 90 with screws, for example. In the case 82, by removing the lid 91, the condenser 81 and the exhaust fan 60 can be attached and detached.

The first portion 105 is provided with a first cover portion 107 and a second cover portion 108. The first cover portion 107 and the second cover portion 108 extend downward from the first portion 105. The first cover portion 107 is arranged at a position corresponding to the first groove 99 provided on the side portion 90e of the main body 90. When the lid 91 is attached to the main body 90, the first cover portion 107 is located on the other end 84B of the water supply flow path pipe 84 arranged in the first groove 99 and closes the first groove 99. The tip of the first cover portion 107 is curved according to the shape of the other end 84B of the water supply flow path pipe 84.

The second cover portion 108 is arranged at a position corresponding to the second groove 100 provided on the side portion 90e of the main body 90. When the lid 91 is attached to the main body 90, the second cover portion 108 is located on the one end 84A of the water supply flow path pipe 84 arranged in the first groove 99 and closes the second groove 100. The tip of the second cover portion 108 is curved according to the shape of the one end 84A of the water supply flow path pipe 84. In the present embodiment, the length of the second cover portion 108 is longer than that of the first cover portion 107.

As shown in FIG. 7, an exhaust passage F is provided in the housing 82. The exhaust passage F is a passage through which water vapor exhausted from the cleaning chamber 2A flows. The exhaust passage F is connected to the exhaust port (exhaust part) 63 and the exhaust passage 65. The exhaust passage F is formed in a meandering shape in a state where the condensing portion 81 is housed in the main body 90 of the housing 82. The exhaust passage F is composed of a partition part 93, a partition part 94, and fins 85 of the condensing part 81. Specifically, the exhaust passage F is formed by the fins 85, the partition portions 93, and the partition portions 94 shown by solid lines in FIG. 7. As a result, the water vapor meanders from the exhaust port 63 toward the exhaust passage 65, as indicated by the arrow in FIG. 7. The space surrounded by the positioning part 95, the positioning part 96, and the support part 86, and the space surrounded by the positioning part 97, the positioning part 98, and the support part 87 have a low heat exchange rate. Therefore, the heat exchanger 80 is designed so that steam does not flow in these spaces. In the air containing water vapor flowing through the exhaust flow path F, a part of the water vapor is condensed to become water, and the air has a reduced water vapor inclusion amount.

The exhaust passage 65 is a pipe member, and air having a reduced water vapor content flows through the hollow portion thereof. The exhaust passage 65 allows the air exhausted from the exhaust passage F of the heat exchanger 80 by the exhaust fan 60 to flow. One end of the exhaust path 65 is connected to the housing 82. In the present embodiment, a part of the exhaust passage 65 and the main body 90 of the housing 82 are integrally formed. The other end of the exhaust passage 65 is connected to, for example, the side portion of the cleaning chamber 2A. As a result, the exhaust passage 65 discharges the air having a reduced amount of water vapor into the cleaning chamber 2A.

As shown in FIG. 2, the hot water storage tank 18 is a tank in which water for rinsing the dishes D is stored. Water is supplied to the hot water storage tank 18 from an external water heater (not shown) via the water supply pipe 21A. The strainer 19 is provided in the water supply pipe 21A. A branch portion 21B is provided downstream of the strainer 19 in the water supply pipe 21A. One of the branch portions 21B is connected to the hot water storage tank 18 via the water valve 20A. The water valve 20A is controlled by the microcomputer 55. The other end of the branch portion 21B is connected to one end 85A (see FIG. 3) of the water supply passage pipe 84 in the heat exchanger 80 described above via the water supply pipe 21C. The water flowing from the water supply pipe 21C passes through the water supply passage pipe 84 of the heat exchanger 80 and is supplied to the hot water storage tank 18 via the water supply pipe 21D.

In the hot water storage tank 18, a rinsing water heater 22 for maintaining the water for rinsing the dishes D at a predetermined temperature and a water temperature sensor 23 for detecting the temperature of the rinsing water are installed. A rinsing pump 25 is connected to the hot water storage tank 18 via a rinsing water suction pipe 24. A rinse water discharge pipe 26 is connected to the discharge port of the rinse pump 25. The rinse water discharge pipe 26 is branched into a first rinse water discharge pipe 27 and a second rinse water discharge pipe 28. The first rinse water discharge pipe 27 is connected to the upper rinse nozzle 6. The second rinse water discharge pipe 28 is connected to the lower rinse nozzle 8.

The detergent supply pump 32 is arranged outside the dishwasher 1, that is, outside the main body 2. The detergent supply pump 32 is a bellows pump for supplying the detergent stored in the detergent tank 33 to the cleaning chamber 2A. The detergent supply pump 32 is connected to a detergent discharge pipe 34 connected to the side wall of the cleaning chamber 2A, and is connected to the microcomputer 55 by a signal line. The detergent supply pump 32 operates in response to a signal output from the microcomputer 55, sucks the detergent in the detergent tank 33 from the connected detergent suction pipe 35, and discharges a predetermined amount of detergent to the detergent discharge pipe 34. This detergent is provided at the tip of the detergent discharge pipe 34 and is discharged into the cleaning chamber 2A from a detergent discharge port 36 that connects the cleaning chamber 2A and the detergent discharge pipe 34. The detergent discharged into the cleaning chamber 2A flows into the cleaning tank 9 below the cleaning chamber 2A and is mixed with the cleaning water.

The rinse agent supply pump 37 is arranged outside the dishwasher 1, that is, outside the main body 2. The rinse agent supply pump 37 is for supplying the rinse agent stored in the rinse agent tank 38 to the rinse channel. The rinse agent supply pump 37 is connected to the rinse agent discharge pipe 39 that communicates with the first rinse water discharge pipe 27, and is connected to the microcomputer 55 by a signal line. The rinse agent supply pump 37 operates in response to a signal output from the microcomputer 55, sucks the detergent in the rinse agent tank 38 from the connected rinse agent suction pipe 40, and discharges the rinse agent to the rinse agent discharge pipe 39. .. The rinse agent is discharged from the rinse agent discharge pipe 39 to the rinse water channel in the rinse water discharge pipe 26 by the rinse agent supply pump 37, and is mixed into the rinse water.

The microcomputer 55 is arranged in the machine room 2B. The microcomputer 55 controls the overall operation of the dishwasher 1. The microcomputer 55 is built in the electrical equipment box 55A. The microcomputer 55 is a computer system or a processor mounted on an integrated circuit. The microcomputer 55 is a part that controls various operations in the dishwasher 1, and is mutually connected with a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like.

Next, the operation of the above dishwasher 1 will be described. When the power switch is turned on, the dishwasher 1 supplies water into the washing tank 9 by injecting the water in the hot water storage tank 18 into the washing chamber 2A by the rinsing pump 25. Thereby, the initial hot water supply is performed. Then, an amount of detergent matching the initial amount of hot water supplied is supplied into the washing tank 9, and the detergent concentration of the washing water in the washing tank 9 becomes a predetermined concentration.

When the user racks the tableware D and closes the door 4 after the initial hot water supply, it is detected that the door 4 is closed by a door switch (not shown), and an operation start signal is input to the microcomputer 55. When the operation start signal is input to the microcomputer 55, the microcomputer 55 operates the washing pump to start washing the dishes D (washing process). Cleaning of the tableware D is performed by spraying the cleaning water in the cleaning tank 9 toward the tableware D in the cleaning chamber 2A.

When the cleaning pump 14 is started, the cleaning water stored in the cleaning tank 9 is pressure-fed to the upper and lower cleaning nozzles 5 and 7 via the cleaning water discharge pipe 15 and the like, and the upper and lower cleaning nozzles are discharged. It is sprayed from 5, 7 toward the tableware D in the cleaning room 2A. The cleaning water sprayed into the cleaning chamber 2A is collected in the cleaning tank 9 while the leftover dishes and the like washed off the dishes D are removed by a filter (not shown). Further, the water in the cleaning tank 9 is taken in by the cleaning pump 14 via the pump filter 12 and the like, and is again supplied into the cleaning chamber 2A.

When the cleaning process ends, the microcomputer 55 operates the drainage pump 52 to start discharging the cleaning water stored in the cleaning tank 9 (drainage process). In the dishwasher 1 of the present embodiment, the washing pump 14 operates to discharge from the washing tank 9 the same amount of washing water as the rinsing water supplied to the washing chamber 2A in the rinsing step described later.

When the drainage process ends, the microcomputer 55 operates the rinsing pump 25 to start rinsing the dishes D (rinsing process). The dishes D are rinsed by spraying the rinsing water in the hot water storage tank 18 toward the dishes D in the cleaning chamber 2A.

By activating the rinsing pump 25, the rinsing water stored in the hot water storage tank 18 is pressure-fed to the upper and lower rinsing nozzles 6 and 8 via the rinsing water discharge pipe 26, etc. Is sprayed toward the tableware D. The rinsing water sprayed on the tableware D is collected in the cleaning tank 9 through a filter (not shown), mixed with the cleaning water, and used as cleaning water in the next cleaning process.

When rinsing water is sprayed from the upper and lower rinsing nozzles 6 and 8 to the tableware D, steam is generated in the cleaning chamber 2A. In the dishwasher 1 of the present embodiment, when the rinsing process is started, the exhaust fan 60 starts operating, and the steam generated in the cleaning chamber 2A is exhausted by the exhaust fan 60 (exhaust process). The operation start timing of the exhaust fan 60 is not limited to this timing, and may be started from a cleaning process in which water is jetted from the upper and lower cleaning nozzles 5, 7.

When the steam is discharged from the cleaning chamber 2A by the exhaust fan 60, the steam is sent to the heat exchanger 80 via the exhaust port 63. The water vapor flows through the exhaust passage F of the heat exchanger 80. When water that is colder than the water vapor flows through the water supply flow passage pipe 84 in the exhaust water flow passage F through which the water vapor flows, "water vapor" that flows through the exhaust water flow passage F and "water that flows through the water supply flow passage pipe 84" A heat exchange is performed between

As a result, the water that has flowed in from one end 84A of the water supply flow path pipe 84 flows out from the other end 84B of the water supply flow path tube 84 in a state in which the temperature is higher than that at the time of inflow. Further, the air containing water vapor flowing through the exhaust passage F becomes air having a reduced inclusion amount of water vapor and is discharged to the cleaning chamber 2A via the exhaust passage 65. The air having the reduced amount of water vapor discharged into the cleaning chamber 2A is discharged from the cleaning chamber 2A by the exhaust fan 60 together with the water vapor contained in the air and the air containing the steam in the cleaning chamber 2A. And in the heat exchanger 80.

Since the water valve 20B is provided on the water supply pipe 21D connected to the other end 85B of the water supply flow path pipe 84, water may stay in the water supply flow path pipe 84 depending on the open/close state of the water valve 20B. There is a case. In this case, heat exchange is performed between “water vapor” flowing through the exhaust passage F and “water” staying in the water supply passage pipe 84.

When the steam in the cleaning chamber 2A is collected for a predetermined time by the operation of the exhaust fan 60, the operation of the exhaust fan 60 is stopped. When the operation of the exhaust fan 60 is stopped, the flow of water vapor in the exhaust passage F of the heat exchanger 80 is stopped. As a result, the discharge of the air from the exhaust passage 65 into the cleaning chamber 2A with the reduced amount of water vapor is stopped. At this time, almost no steam (steam) exists in the cleaning chamber 2A.

Further, in the dishwasher 1 of the present embodiment, the cumulative number of operations (the number of operations in the present embodiment means the number of cycles when the washing process and the rinsing process of the dish D are defined as one cycle). When it reaches, it has a function of discharging all the drainage stored in the cleaning tank 9 (total drainage function). The total drainage function is installed for the purpose of replacing the cleaning water in the cleaning tank 9 which becomes gradually dirty due to repeated operations with clean cleaning water.

Next, operation effects of the dishwasher 1 of the above embodiment will be described. In the dishwasher 1 of the above-described embodiment, since the steam exhaust passage F in the heat exchanger 80 has a meandering shape, the length of the exhaust passage F can be secured without enlarging the heat exchanger 80. Thereby, in the heat exchanger 80, the steam and the condenser 81 can be effectively brought into contact with each other. Therefore, the condenser 81 can efficiently recover the heat of the steam. Therefore, the dishwasher 1 can improve the heat recovery rate of water vapor. As a result, the dishwasher 1 can reduce the time required to recover the heat of steam.

Further, in the dishwasher 1 of the above-described embodiment, the condensing unit 81 has the water supply flow path pipe 84 for circulating the water supply supplied to the hot water storage tank 18, and the fins 85 provided on the water supply flow path pipe 84. doing. The housing 82 has a plurality of partition portions 93 and 94 that form a meandering exhaust passage F together with the fins 85. In the dishwasher 1 with such a configuration, the meandering exhaust passage F can be formed with a simple configuration.

Further, the dishwasher 1 of the above embodiment is provided with the exhaust fan 60 that exhausts the water vapor from the washing chamber 2A. In the dishwasher 1 having such a configuration, the steam can be more reliably exhausted from the washing chamber 2A.

Here, in the conventional heat exchanger, in order to effectively bring the condenser and the steam into contact with each other, the steam can be uniformly blown into the entire heat exchanger so that the steam uniformly flows in the housing. It was necessary to install an exhaust fan with a wide blast width. Further, in the conventional heat exchanger, when the air blowing width of the exhaust fan is narrow, it is necessary to set the width of the exhaust passage in accordance with the air blowing width in order to uniformly blow the air in the heat exchanger. In this case, it is necessary to secure a long exhaust flow path, which increases the size of the heat exchanger. On the other hand, in the dishwasher 1 of the above-described embodiment, even when the exhaust fan 60 having a narrow airflow width is used and the width of the exhaust flow passage F is set to match the airflow width of the exhaust fan 60, the meandering The heat exchange amount can be secured by the exhaust passage F in the shape of a circle. Therefore, in the dishwasher 1, the exhaust fan 60 can be downsized while ensuring the heat recovery rate of water vapor.

Moreover, in the dishwasher 1 of the above-described embodiment, the housing 82 of the heat exchanger 80 has a main body 90 and a lid 91. Condensation occurs in the heat exchanger 80 due to the condensation of water vapor. The water generated by the dew condensation is returned to the cleaning chamber 2A. However, it is difficult to completely discharge the water in the heat exchanger 80, and water may remain in the heat exchanger 80. The water remaining in the heat exchanger 80 may cause molds and bacteria to propagate, which may deteriorate hygiene. Therefore, in the dishwasher 1 of the above-described embodiment, the lid 91 is detachably attached to the main body 90. Thereby, the heat exchanger 80 can be easily maintained (cleaned). Therefore, in the dishwasher 1, the heat exchanger 80 can be made hygienic.

Further, in the dishwasher 1 of the above-described embodiment, the condenser 81 of the heat exchanger 80 is detachably provided in the housing 82. Accordingly, maintenance of the condenser 81 and the housing 82 can be easily performed. Therefore, in the dishwasher 1, the heat exchanger 80 can be made hygienic. When the condenser 81 is attached to the housing 82, the positions of the condenser 81 with respect to the housing 82 are defined by the positioning portions 95 to 98 provided on the housing 82. Therefore, in the heat exchanger 80, the condensing part 81 can be easily attached to the housing 82.

Further, in the dishwasher 1 of the above-described embodiment, the discharge part 101 provided in the main body 90 of the housing 82 of the heat exchanger 80 has the bottom part 104. The surface of the bottom portion 104 is provided at a position lower than the surface of the bottom portion 90a of the main body 90. Further, the bottom 104 is provided with a groove 104A. The groove 104A is also formed in the lower portion of the housing portion 102 of the exhaust fan 60 provided in the discharge portion 101. Thereby, in the dishwasher 1, water generated by dew condensation in the housing 82 can be guided to the exhaust passage 65 via the bottom portion 104 and the groove 104A. The water guided to the exhaust passage 65 is discharged to the cleaning chamber 2A.

Although one embodiment has been described above, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the invention.

<Modification 1>
In the dishwasher 1 of the above-described embodiment, in the heat exchanger 80, the form in which the exhaust passage F is formed by the fins 85 of the condenser 81 and the two partition portions 93 and 94 has been described as an example. However, the present invention is not limited to this. For example, the number of partition parts may be three or more.

<Modification 2>
In the dishwasher 1 of the above-described embodiment, water vapor is caused to flow into the heat exchanger 80 from the exhaust port 63 provided in the upper portion of the cleaning chamber 2A, and the air that has passed through the exhaust passage F is exhausted through the exhaust passage 65 to the cleaning chamber. Although the form in which the side portion of 2A is discharged into the cleaning chamber 2A has been described as an example, the present invention is not limited to this. For example, in the dishwasher 1, steam may be caused to flow into the heat exchanger 80 from the side portion of the washing chamber 2A and air may be discharged from the upper portion of the washing chamber 2A.

<Modification 3>
In addition to the dishwasher 1 of the above embodiment, the bottom portion 90a of the main body 90 in the housing 82 may be inclined. Specifically, the bottom portion 90a may be inclined so as to have a downward slope from the exhaust hole 92 toward the discharge portion 101. As a result, water generated by dew condensation in the housing 82 can be guided to the exhaust passage 65 via the bottom portion 104 and the groove 104A.

<Modification 4>
In the dishwasher 1 of the above-described embodiment, the top plate 2E is locked to the locking portions 2F and 2G and fixed to the main body portion 2 with a screw, but the present invention is not limited to this. Not limited. The top plate 2E may be fixed to the main body 2 by another fixing method.

<Modification 5>
In the dishwasher 1 of the above embodiment, the case where the lid 91 of the housing 82 is fixed to the main body 90 with screws has been described as an example, but the present invention is not limited to this. The lid 91 may be fixed to the main body 90 by another fixing method.

<Modification 6>
In the dishwasher 1 of the above-described embodiment, of the water supply pipe 21C, the water supply pipe 21D, and the water supply flow passage pipe 84 that circulate the water supplied to the hot water storage tank 18, the water supply passage pipe 84 is connected to the condensing part of the heat exchanger 80. However, the present invention is not limited to this. For example, the condensing unit may be a channel through which other water flows, or may be an electrically cooled device.

<Modification 7>
In the dishwasher 1 of the above-described embodiment, the form in which the exhaust unit 60 is provided with the exhaust fan 60 has been described as an example, but the present invention is not limited to this. The exhaust fan 60 may be arranged at another position of the main body 90 of the housing 82, or may be provided in the exhaust passage 65.

<Other modifications>
In the above-mentioned embodiment and the above-mentioned modification, although an undercounter type dishwasher in which the door 4 was provided in the front of the washing room 2A was described as an example, the present invention is a type of dish whose door is opened and closed vertically. It is also possible to apply the present invention to a washing machine or a conveyor type dishwashing machine that carries out washing while transporting a rack for accommodating the dishes D.

In the above-mentioned embodiment and the above-mentioned modification, although heat exchanger 80 was explained as an example arranged above body part 2, it may be arranged at the side of body part 2, for example, It may be arranged in the machine room 2B in the main body 2. In this configuration, the heat exchanger 80 is arranged inside the side panel or inside the panel (front panel) that covers the machine room 2B. When exposing the heat exchanger 80 having this structure, the side panel or the front panel may be removed. Further, the heat exchanger 80 may be arranged outside the dishwasher 1. Further, although the hot water storage tank 18 has been described by taking the example of being arranged in the machine room 2B of the main body 2, it may be arranged outside the main body 2. That is, it may be a dishwasher in which the hot water storage tank 18 for external attachment is provided.

When a heat exchanger is provided in the above-described embodiment and the above-described modified example, a route for supplying water from an external water heater to the hot water storage tank 18 via the heat exchanger 80 and water from an external water heater are provided. The configuration in which the path for directly supplying to the hot water storage tank 18 is formed has been described as an example, but only the path for supplying to the hot water storage tank 18 via the heat exchanger 80 may be formed.

In the above-described embodiment, the exhaust fan 60 is taken as an example of the means for discharging the steam from the cleaning chamber 2A, but the means is not limited to this as long as the steam can be sent from the cleaning chamber 2A to the exhaust passage 65.

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

DESCRIPTION OF SYMBOLS 1... Dishwasher (washer), 2A... Washing room, 18... Hot water storage tank (water supply storage part), 60... Exhaust fan, 63... Exhaust port (exhaust part), 80... Heat exchanger, 81... Condensing part, Reference numeral 82... Casing, 84... Water supply flow path pipe (supply section), 85... Fins, 93, 94... Partition section, F... Exhaust flow path.

Claims (2)

A cleaning machine for cleaning an object to be cleaned housed in a cleaning chamber,
An exhaust unit for exhausting water vapor in the cleaning chamber,
A heat exchanger having a condensing part for condensing the water vapor discharged from the exhaust part, and a housing accommodating the condensing part;
A water supply reservoir for storing rinsing water used for rinsing the object to be cleaned,
In the housing, the flow path of the water vapor in which the condensing part and the water vapor come into contact is meandering,
The condensing unit is
A supply unit that circulates the water supply supplied to the water supply storage unit, and has a linear portion that extends linearly and a folded portion that connects the linear portions to each other, and the supply is formed in a meandering shape. Department ,
A plurality of fins provided in the supply unit,
A pair of support portions arranged at each of the ends in the extending direction of the linear portion of the supply portion ,
The housing is
A plurality of partition portions that form the meandering flow path together with the fins ,
A main body having a bottom portion and four side portions and containing the condensing portion ,
Each of the plurality of fins is arranged at the linear portion of the supply unit with a predetermined interval in the extending direction of the linear portion ,
Of the four side portions, a pair of positioning portions is provided on each of the two side portions that are arranged to face each other,
Each of the pair of support portions is arranged between each of the pair of positioning portions,
A washing machine in which a space surrounded by a pair of the positioning portion and the support portion is not included in the flow path of the water vapor . The cleaning machine according to claim 1, further comprising an exhaust fan that exhausts the water vapor from the cleaning chamber.

Images