JP2019063492A - dishwasher - Google Patents

Abstract

To provide a dishwasher reliably depositing charged fine particle water or ions to the inner surfaces of all objects to be washed and a washing tank, and reliably performing mitigation of odor, suppressing propagation of various germs and sterilization.SOLUTION: A dishwasher includes: a blowing device (blowing fan 13) for sending air for dry to the inside of a washing tank 2 where objects 8 to be washed are stored; an air channel 20 communicating the washing tank 2 with the blowing device; an electrostatic atomization device 18 provided in the air channel 20 to generate charged fine particle water; and an ion introduction device (blowing fan 13) supplying the charged fine particle water into the inside of the washing tank 2. The air channel 20 is composed of a main air channel 20a and a sub air channel 20b blanched from the main air channel 20a. The electrostatic atomization device 18 is disposed in the sub air channel 20b, so as to make a flow rate of air flowing through the sub air channel 20b smaller than a flow rate of air flowing through the main air channel 20a.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a dishwasher. In particular, the present invention relates to a dishwasher equipped with a device for disinfecting the inner surface of a to-be-cleaned material and a washing tank.

  A dishwasher having a drying function, which includes an ion generating unit that disinfects and deodorizes an object to be cleaned and the inner surface of a cleaning tank, has been conventionally proposed.

  The configuration and operation of a conventional dishwasher will be described using FIGS. 5 and 6 (see, for example, Patent Document 1). FIG. 5 is a side cross-sectional view of a conventional dishwasher equipped with an ion generation unit. FIG. 6 is a detailed view of a conventional electrostatic atomizer (ion generating unit) of a dishwasher provided with an ion generating unit.

  As shown in FIG. 5, the washing tank 102 is provided inside the dishwasher body 101. An object to be cleaned 108 such as a dish is stored inside the cleaning tank 102 and is cleaned by the cleaning water jetted from the cleaning nozzle 107. Water or hot water is supplied as wash water into the wash tank 102 by a water supply valve (not shown). A drain hole 104 is provided at the bottom of the cleaning tank 102. A cleaning pump 105 is attached in communication with the drain hole 104. The cleaning pump 105 is configured to circulate cleaning water inside the cleaning tank 102. The drainage hole 104 is provided with a residue filter 106 for collecting residues contained in the washing water.

  In the above configuration, when the cleaning pump 105 is driven, the cleaning water supplied into the cleaning tank 102 passes through the residual filter 106 and is sucked into the cleaning pump 105, and the inner bottom of the cleaning tank 102 is cleaned by the cleaning pump 105. Is supplied to the cleaning nozzle 107 provided in The washing water jetted from the washing nozzle 107 circulates along a route of returning to the drainage hole 104 again after washing the object to be washed 108. Under the present circumstances, the residue etc. which fell off from the to-be-cleaned object 108 flow in into the residue filter 106 with washing water. The residue having a size that can not pass through the residue filter 106 is collected by the residue filter 106.

  Between the cleaning nozzle 107 and the bottom of the cleaning tank 102, a heater 109 for heating the cleaning water is provided. Above the cleaning nozzle 107, a tableware cage 110 configured to arrange the objects to be cleaned 108 in order is provided. Further, the drainage pump 111 drains the cleaning water in the cleaning tank 102 to the outside through the drainage hose 112.

  A drying unit is provided inside the dishwasher body 101. The drying unit sends warm air to the cleaning tank 102 to dry the object to be cleaned 108. The drying unit is configured by providing a blower fan 113 and a heater 116 in the air passage 115. When the blower fan 113 is driven, the air in the cleaning tank 102 is heated by the heater 116 for drying, and then fed into the cleaning tank 102 again to accelerate the drying of the object to be cleaned 108.

  A control unit 117 is provided inside the dishwasher main body 101. The control unit 117 controls the electric components such as the water supply valve, the washing pump 105, the drainage pump 111, the heater 109, the blower fan 113, and the heater 116 to execute the washing process, the rinsing process, and the drying process. In addition, an operation unit (not shown) is provided on the front of the dishwasher body 101. A user selects a driving course and the like by the operation unit.

  Furthermore, an ion generating unit 118 is provided on the inner top surface of the cleaning tank 102. The ion generation unit 118 generates ion particles to perform sterilization and deodorization of the object to be cleaned 108 and the inner surface of the cleaning tank 102.

  The tableware washing machine described in patent document 1 is equipped with the electrostatic atomizer as an ion generation part 118. As shown in FIG. Dishwasher starts operation of electrostatic atomizer before washing process, releases charged fine particle water generated by electrostatic atomizer and makes it adhere to to-be-washed thing 108 before washing Routine cleaning to improve the cleaning performance.

  The configuration and operation of the electrostatic atomizer (ion generator 118) in Patent Document 1 will be described with reference to FIG. The electrostatic atomizer (ion generating unit 118) cools the moisture in the air by the cooling unit 118a, which is a Peltier unit or the like, and generates condensed water. Then, the generated condensed water is supplied to the discharge electrode 118 b. When high voltage is applied between the discharge electrode 118b and the counter electrode 118c in a state where condensed water is supplied to the discharge electrode 118b, the condensed water at the tip portion of the discharge electrode 118b has a large energy (high density A large amount of negatively charged nanometer-sized charged fine particle water is generated under the repulsive force of the electric charge, and is released to the outside of the electrostatic atomizer (ion generating portion 118), that is, to the inside of the cleaning tank 102.

  Moreover, the structure provided with the ion generator as the ion generation part 118 like other conventional dishwashers is proposed (for example, refer patent document 2). The ion generator supplies the generated ions to the washing tank 102, and disinfects and deodorizes the object to be washed 108 and the inner surface of the washing tank 102.

JP, 2008-237439, A Unexamined-Japanese-Patent No. 2004-351012

  However, the dishwasher of the configuration as described in Patent Document 1 has a simple configuration in which the electrostatic atomizer (ion generator 118) is provided on the inner top surface of the cleaning tank 102, There is no provision for the charged fine particle water generated by the atomization device (ion generating unit 118) to be spread throughout the cleaning tank 2. Therefore, there is a problem that the charged fine particle water does not sufficiently spread over all the objects to be cleaned 108 stored in the cleaning tank 102 and all the inner surfaces of the cleaning tank 102, and cases of insufficient sterilization and deodorization occur. Have. In addition, in the generation of charged fine particle water and supply to washing tank 102, it is easily affected by the environment in washing tank 102, the amount of charged fine particle water generation is not stable, and it is difficult to control the concentration of the generated charged fine particle water Have the problem of being

  In order to solve the above-mentioned conventional problems, a dishwasher according to the present invention comprises: a cleaning tank for storing an object to be cleaned; a cleaning unit for cleaning the object to be cleaned; and an ion generating unit for generating charged particulate water or ions. And an introduction air passage and an ion introduction device for supplying charged fine particle water or ions generated by the ion generation unit into the cleaning tank, the introduction air passage being branched from a main air passage and the main air passage. The ion generating unit is provided in the sub air path, and the introduction air path has a flow velocity of air flowing through the sub air flow path according to a flow velocity of air flowing through the main air path It is configured to be small.

  The dishwasher of the present invention can generate charged particulate water or ions in a stable state, and can be reliably supplied to all positions in the washing tank. In this way, by ensuring that the charged fine particle water or the ions adhere to all the objects to be cleaned set in the cleaning tank and all the inner surfaces of the cleaning tank, it is possible to reliably reduce odor and prevent various bacteria from growing and disinfecting. It can be done. Moreover, the influence of the inside of a washing tank and the external environment of a dishwasher can be suppressed, and control of the density | concentration of charged fine particle water or ion is attained.

Side cross-sectional view of the dishwasher in accordance with the first embodiment of the present invention Principal part sectional view of the introduction air path of the dishwasher in the present embodiment The figure which shows the sequence at the time of the lump washing course driving | operation of the dishwasher in this Embodiment. Timing chart showing operation of ion introduction operation of the dishwasher in the present embodiment Side cross-sectional view of a conventional dishwasher equipped with an ion generation unit Detailed view of the electrostatic atomizer (ion generation unit) of the dishwasher equipped with the conventional ion generation unit

  A dishwasher according to a first aspect of the present invention is generated by a cleaning tank for storing an object to be cleaned, a cleaning unit for cleaning the object to be cleaned, an ion generating unit for generating charged particulate water or ions, and the ion generating unit. An introduction air passage for supplying charged fine particle water or ions into the cleaning tank and an ion introducing device, the introduction air passage being constituted by a main air passage and a sub air passage branched from the main air passage, The ion generating unit is provided in the sub air passage, and the introduction air passage is configured such that the flow velocity of air flowing through the sub air passage is smaller than the flow velocity of air flowing through the main air passage. is there.

  With this configuration, it is possible to stably generate charged fine particle water or ions by reducing the flow velocity of the sub air passage provided with the ion generation unit. As a result, the influence of the environment inside the washing tank and the outside of the dishwasher can be suppressed, and control of the concentration of the charged fine particle water or ion becomes possible. Further, the generated charged fine particle water or ions can be carried on the flow of air having a high flow velocity flowing through the main air passage and supplied into the cleaning tank. As a result, the charged fine particle water or ions are reliably attached to all the objects to be washed set in the washing tank and all the inner surfaces of the washing tank, thereby alleviating odor and reliably suppressing reproduction and elimination of various bacteria. be able to.

  According to a second invention, in particular, in the first invention, a wall surface is provided at a junction where the sub air passage joins the main air passage so as to protrude into the main air passage, and the wall surface is the junction It is formed to be inclined to the downstream side on the upstream side of the part. With this configuration, the air in the sub air passage is sucked by the venturi effect generated in the flow of the main air passage due to the presence of the wall surface. As a result, it is possible to prevent the air in the sub air passage from flowing backward in the direction of the ion generation part, and it is possible to stably supply charged particulate water or ions into the cleaning tank.

  According to a third invention, in particular, in the first or second invention, a blower for blowing external air to the inside of the cleaning tank, and an air passage for communicating the blower with the cleaning tank are provided. The air passage is configured to double as the introduction air passage, and the blower is configured to double as the iontophoresis device. This configuration makes it possible to realize the configuration and control unit related to the generation and supply of charged particulate water or ions with a simple configuration. Thereby, the internal volume of a washing tank can be large and can provide a cheap dishwasher.

  According to a fourth invention, in particular, in the third invention, a filter for collecting dust and the like contained in air is provided in the air passage, and the filter is disposed upstream of the ion generation unit. It is a thing. With this configuration, dust and the like can be prevented from adhering to an internal device (such as a discharge electrode of an electrostatic atomization device) of the ion generation unit, and generation of charged fine particle water or ions can be stabilized.

  According to a fifth invention, in particular, in the first or second invention, an outlet air passage through which the air flows out from the washing tank is provided, and the outlet air passage is connected to the inlet air passage to form a circulating air passage. The ion generating unit and the ion introducing device are provided in the circulation air passage. With this configuration, the charged particulate water or ions supplied into the cleaning tank circulate and are not released to the outside, so that more charged particulate water or ions can be supplied into the cleaning tank.

  Hereinafter, one embodiment of a dishwasher according to the present invention will be described with reference to the drawings. The present invention is not limited by the embodiment.

Embodiment 1
Hereinafter, the dishwasher of Embodiment 1 of the present invention will be described with reference to the drawings. FIG. 1 is a side cross-sectional view of the dishwasher in accordance with the first exemplary embodiment of the present invention. FIG. 2: is principal part sectional drawing of the introductory air path of the dishwasher in this Embodiment.

  As shown in FIG. 1, a washing tank 2 is provided inside the main body 1 of the dishwasher. A to-be-cleaned object 8 such as a dish is accommodated in the inside of the cleaning tank 2 and is cleaned by the cleaning water jetted from the cleaning nozzle 7 which is a cleaning unit. Water or hot water is supplied from the water supply unit 3 into the cleaning tank 2 as cleaning water. A drainage hole 4 is provided at the bottom of the cleaning tank 2. A cleaning pump 5 is attached in communication with the drain hole 4. The washing pump 5 is configured to circulate washing water inside the washing tank 2. The drainage hole 4 is provided with a residue filter 6 for collecting residues contained in the washing water.

  When the cleaning pump 5 is driven, the cleaning water supplied into the cleaning tank 2 passes through the residual filter 6 and is sucked into the cleaning pump 5. Then, it is supplied to the cleaning nozzle 7 provided at the inner bottom portion of the cleaning tank 2 by the cleaning pump 5. The washing water jetted from the washing nozzle 7 circulates along a route of returning to the drainage hole 4 again after washing the object to be washed 8. Under the present circumstances, the residue etc. which fell off from the to-be-cleaned object 8 flow into the residue filter 6 with wash water. The residue of a size that can not pass through the residue filter 6 is collected by the residue filter 6.

  Between the cleaning nozzle 7 and the bottom of the cleaning tank 2, a cleaning water heater 9 for heating the cleaning water is provided. Above the cleaning nozzle 7, a tableware cage 10 configured to arrange the objects to be cleaned 8 in order is installed. The drainage pump 11 drains the cleaning water in the cleaning tank 2 to the outside through the drainage hose 12.

  A drying unit is provided inside the main body 1. The drying unit sends warm air to the cleaning tank 2 to dry the object to be cleaned 8. The drying unit is configured by providing a blower fan 13 as a blower and a heater 16 for heating air in the air passage 20. One end of the air passage 20 is in communication with the cleaning tank 2, and the other end is in communication with the outside of the main body 1 by the outside air suction port 14. A filter 15 is disposed at the outside air suction port 14. The filter 15 collects dust and the like contained in the outside air, and keeps the air taken into the air passage 20 from the outside air suction port 14 clean.

When the blower fan 13 is driven, the air from which dust and the like are removed by the filter 15 is taken into the air passage 20 from the outside air suction port 14. The air taken into the air passage 20 is heated by the heater 16 and then fed into the washing tank 2 to dry the object to be washed 8 and the washing tank 2. Thus, the air containing moisture in the cleaning tank 2 is exhausted from the exhaust port (not shown). The drying unit may include a dehumidifying unit, and air for drying may be configured to circulate between the cleaning tank 2 and the dehumidifying unit.

  A control unit 17 is provided inside the main body 1. The control unit 17 controls electric parts such as the water supply unit 3, the washing pump 5, the drainage pump 11, the washing water heater 9, the blower fan 13 and the heater 16 to perform a preliminary washing process, a main washing process, a rinsing process, and a drying process. Run. In addition, an operation unit (not shown) is provided on the front surface of the main body 1. The user sets the driving course and the like by the operation unit.

  Furthermore, as the ion generation unit, an electrostatic atomization device 18 is provided in the air passage 20 (introduction air passage). The electrostatic atomizer 18 generates negatively charged nanometer-sized charged fine particle water. The charged fine particle water thus produced is mixed with the air fed into the cleaning tank 2 through the air passage 20 by the blower fan 13 which is a blower, and is supplied into the cleaning tank 2. We perform sterilization and deodorization of the inside. In the present embodiment, the iontophoresis device is configured to include an electrostatic atomization device 18 (ion generation unit), a blower fan 13 which is also used as a drying unit, and an air passage 20. With this configuration, the dedicated air blower or air passage from the ion generation unit to the cleaning tank 2 is required by supplying charged fine particle water or ions into the cleaning tank 2 by using it also as the air blowing fan 13 for drying. Since it does not, it can provide an inexpensive dishwasher.

  In addition, an air blower and an air path may be separately comprised by an iontophoresis apparatus and a drying part. With this configuration, the control unit 17 can control the respective blowers individually and more accurately.

  The electrostatic atomizing device 18 is disposed in the air passage 20 downstream of the blower fan 13. The heater 16 is disposed in the air passage 20 downstream of the electrostatic atomizing device 18. The filter 15 is disposed at the outside air suction port 14. The filter 15 may be disposed at any position in the air passage 20 upstream of the electrostatic atomization device 18.

  Further, the air flow detection unit 23 that detects the air volume may be disposed downstream of the heater 16 in the air flow passage 20. The air flow detection unit 23 is not limited to the air flow rate meter that directly detects the air flow rate, and is configured to detect the wind speed and estimate the air flow rate, or detect the temperature downstream of the heater 16. Alternatively, the air volume may be estimated from the rate of cooling.

  Next, the configuration and operation of the air passage of the dishwasher in the first embodiment of the present invention will be described in detail with reference to the drawings.

  As shown in FIG. 2, the air passage 20 is constituted by a main air passage 20 a and a sub air passage 20 b branched from the main air passage 20 a to a part of the main air passage 20 a and provided in parallel. The electrostatic atomizer 18 is disposed in the sub air passage 20b. In the sub air passage 20b, a part of the air taken into the air passage 20 by the blower fan 13 branches from the main air passage 20a to the sub air passage 20b and passes through the electrostatic atomization device 18, and then enters the main air passage 20a. Configured to merge.

  The sub air passage 20b is configured so that the cross-sectional area of the air passage is smaller than the main air passage 20a at a predetermined ratio. As a result, the amount of air passing through the sub air passage 20b is reduced, and the flow velocity of air passing through the electrostatic atomizing device 18 is smaller than the flow velocity of air passing through the main air passage 20a.

A wall surface 22 is provided in the merging section 20c, which returns from the sub air passage 20b to the main air passage 20a, so as to protrude into the main air passage 20a. The wall surface 22 is formed on the upstream side of the merging portion 20c so as to be inclined to the downstream side. That is, the blower fan 13 side of the merging portion 20c is covered with the wall surface 22, and the cleaning tank 2 side is opened. The main air path 20a is configured to be narrowed locally at this portion by the wall surface 22.

  The electrostatic atomizer 18 is configured in the same manner as the electrostatic atomizer (ion generator 118) described in the conventional example. Therefore, the electrostatic atomizer 18 will be described with reference to FIG. The electrostatic atomizing device 18 (ion generating unit) cools the moisture in the air by the cooling unit 18a formed of a Peltier unit or the like to generate condensation water. Then, the generated condensed water is supplied to the discharge electrode 18b. In addition, the discharge electrode 18 b may be cooled so as to condense directly on the discharge electrode 18 b.

  When a high voltage is applied between the discharge electrode 18b and the counter electrode 18c in a state where the condensed water is supplied to the discharge electrode 18b, the condensed water at the tip portion has a large energy (the repulsion force of the charge having a high density) ), And negatively charged nanometer-sized charged fine particle water is produced and released. The charged fine particle water thus released is introduced into the cleaning tank 2 from the sub air passage 20b through the main air passage 20a.

  With regard to the dishwasher configured as described above, the operation and action in the case where the object to be cleaned is cleaned using the electrostatic atomizing device 18 operated and the generated charged fine particle water will be described.

  When the blower fan 13 is operated, outside air is taken into the main body 1 from the outside air suction port 14. The taken-in outside air passes through the filter 15 to remove dust and the like, and is then introduced into the cleaning tank 2 through the air passage 20. With this configuration, dust and the like can be prevented from adhering to the discharge electrode 18b and the counter electrode 18c of the electrostatic atomizing device 18, and the generation of charged fine particle water or ions can be stabilized.

  At this time, the sub air passage 20b branched from the main air passage 20a has a cross-sectional area smaller than that of the main air passage 20a. Therefore, a small flow of air flows through the sub air passage 20b with respect to the air flowing through the main air passage 20a. The flow velocity of the wind flowing through the sub air passage 20b is smaller than the flow velocity of the wind flowing through the main air passage 20a. The wind flowing through the sub air passage 20 b passes through the electrostatic atomizing device 18 disposed in the sub air passage 20 b.

  Thus, when the electrostatic atomization device 18 is operated by reducing the flow velocity of the air passing through the electrostatic atomization device 18, the condensed water generated by the cooling unit 18a such as the Peltier unit is a wind. Can be prevented from being appropriately generated under the influence of Further, by adjusting the speed of the air passing through the electrostatic atomizing device 18 by the branched configuration of the main and sub air paths, the supply of the generated condensed water to the discharge electrode 18 b can be stabilized.

  In addition, the charged fine particle water or ions are reliably attached to all the objects to be cleaned 8 set in the cleaning tank 2 and the entire inner surface of the cleaning tank 2, thereby alleviating odor and suppressing the reproduction of bacteria and eliminating bacteria. You can In order to reliably exhibit the effect, it is desirable to generate a predetermined amount of charged fine particle water or ions.

  Next, the drying process and the ion introduction operation of the object to be cleaned in the dishwasher will be described. In the present description, the item to be cleaned is referred to as a dish.

Drying of the dishes requires the amount of heat required to dry the dishes and efficient evaporation of water by the wind flowing on the surface of the dishes. Therefore, a relatively large air flow is required during drying. The ion introduction operation is to supply charged fine particle water or ions to the washing tank 2 for deodorization and sterilization before the main washing step or after the drying step, and the air volume as in the drying step is unnecessary. That is, because of the relatively slow wind speed required for the iontophoretic operation by the ion generating unit such as the electrostatic atomizer 18, it is not beneficial for the drying of the dishes to reduce the overall air volume. As a countermeasure against this, it is conceivable to provide a dedicated fan for the electrostatic atomizing device 18. However, providing a fan dedicated to the electrostatic atomizing device 18 separately from the blower fan 13 reduces the internal volume of the cleaning tank 2, the operation of the control unit 17 becomes complicated, and the dishwasher becomes expensive. Etc, it is not a good idea.

  As described above, it is desirable that the control unit 17 execute the air introduction operation and the drying process with different air volumes. The dishwasher in the present embodiment is configured to change and control the air volume so as to use an appropriate air volume in each of these operations. That is, the control unit 17 controls the amount of air suitable for the generation of the charged fine particle water in the electrostatic atomization device 18 in the ion introduction operation, and performs control to exhibit the drying performance of the dishes in the drying process. As a result, in the ion introduction operation, charged fine particle water or ions can be generated in a stable state, reliably supplied to all the positions in the washing tank, and the odor can be alleviated and disinfected. Further, in the drying step, the dishes can be dried in a short time.

  In the dishwasher according to the present embodiment, as shown in FIG. 2, in the air passage 20, the sub air passage 20b is branched from the main air passage 20a and provided in parallel with the main air passage 20a. The electrostatic atomizer 18 is disposed in the sub air passage 20b. The control unit 17 controls the blower fan 13 so that the air volume is suitable for the ion introduction operation by the electrostatic atomization device 18. With this configuration, a predetermined air volume branches and passes through the electrostatic atomizing device 18 in the sub air passage 20b. Then, the air containing the charged particulate water joins the main air passage 20a, and is supplied to the cleaning tank 2 on the air having a high flow velocity flowing through the main air passage 20a. As a result, the electrostatic atomizing device 18 can sufficiently generate charged particulate water, and the blower fan 13 can reliably supply the generated charged particulate water into the cleaning tank 2.

  The merging portion 20c returning from the sub air passage 20b to the main air passage 20a is provided with a wall surface 22 closed to the blower fan 13 side, opened toward the cleaning tank 2 side, and inclined to the downstream side. As a result, the main air passage 20a is configured such that the cross-sectional area is locally narrowed at the junction 20c returning from the sub air passage 20b to the main air passage 20a. With this configuration, even when pressure loss occurs in the main air passage 20a to the cleaning tank 2 side, a sub-air passage is generated by the venturi effect generated by the flow of air having a large flow rate in the main air passage 20a and a high flow velocity. The air of 20b is sucked. As a result, the air in the sub air passage 20b can be prevented from flowing backward in the direction of the electrostatic atomizing device 18, and the charged fine particle water can be stably supplied into the cleaning tank 2.

  In addition, at the time of the ion introduction operation | movement by the electrostatic atomization apparatus 18, it distributes downstream from the electrostatic atomization apparatus 18 in the main air path 20a more downstream than the junction part 20c which returns to the main air path 20a from the sub air path 20b. The provided drying heater 16 is not operated. By this, the state of the charged fine particle water generated by the electrostatic atomizing device 18 can be stably maintained.

  Further, on the downstream side of the electrostatic atomizing device 18, a blow detection unit 23 for detecting an air volume is disposed. The control unit 17 measures the amount of air passing through the air passage 20 based on the detection result of the air flow detection unit 23. The control unit 17 controls the blower fan 13 so as to obtain a predetermined air volume particularly in the ion introduction operation. Alternatively, the control unit 17 controls the electrostatic atomization device 18 so as to have a predetermined ion concentration in the ion introduction operation. As a result, the concentration of the charged fine particle water supplied into the cleaning tank 2 can be properly controlled to reduce odor and eliminate bacteria.

  In the method of adjusting the concentration of the charged fine particle water supplied into the cleaning tank 2, the amount of generation of the electrostatic atomizing device 18 may be changed with respect to the air volume of the blower fan 13.

  Furthermore, the control of the air volume at the time of the ion introduction operation may be a method of controlling the blower fan 13 by estimating it from the air volume at the drying step. That is, it is a method of utilizing the cooling state of heater 16 energized at the time of a drying process as blowing detection part 23 for measuring the amount of winds. Specifically, when the heater 16 is used in the drying step, the temperature rise of the air passing through the heater 16 is measured. When the temperature rise of the air is small with respect to the heat input to the heater 16, the cooling effect is high because the air volume is large. On the contrary, when the temperature rise of air is large, the cooling effect is low because the air volume is small. Thus, the air volume in the drying process can be estimated by the relationship between the heat input from the heater 16 and the air volume.

  If the blower fan 13 detects its rotational speed, the air volume can be determined from the characteristics of the rotational speed and the air volume. The control unit 17 can control the blower fan 13 to an air volume suitable for the ion introduction operation using this characteristic. Furthermore, the air flow rate of the blower fan 13 is reduced by clogging of the filter 15 of the outside air suction port 14. Therefore, if the air volume is measured each time the drying process, it is possible to grasp the change in the air volume due to clogging of the filter 15 or the like. And since clogging of the filter 15 is unlikely to change suddenly suddenly, it is possible to control the blower fan 13 by utilizing the air volume state of the drying process at the time of ion introduction operation and to blow air with a proper air volume.

  Next, the operation and action of the electrostatic atomization device 18 during the course operation of the dishwasher in the present embodiment will be described using the drawings. FIG. 3 is a diagram showing a sequence of the combined washing course operation of the dishwasher of the first embodiment.

  As shown in FIG. 3, the user first sets the object to be cleaned 8 such as tableware in the tableware basket 10 and stores the inside of the cleaning tank 2 (step S1). The user operates the operation unit to select a course for collectively washing, such as when additionally washing objects 8 after this, and collectively washing after additional setting, or when sending off the main washing for convenience. S2). The control unit 17 executes the pre-washing process on the set item to be washed 8 by selecting the collective washing course. In the preliminary washing step, a preliminary washing operation with washing water jetted from the washing nozzle 7 (step S3) and a charged fine particle water introducing operation (in which the charged fine particle water is supplied into the washing tank 2 by operating the electrostatic atomizer 18) And ion introduction operation, step S4).

  The control unit 17 performs the preliminary washing operation for a predetermined time (step S3). Next, the control unit 17 performs charged particle water introduction operation (step S4). Specifically, the control unit 17 operates the electrostatic atomizing device 18 and the blower fan 13. The electrostatic atomizer 18 generates charged particulate water. The charged fine particle water thus generated is supplied into the cleaning tank 2 by the blower fan 13 and suppresses the generation of odor and the growth of bacteria caused by food residue adhering to the to-be-cleaned object 8 stored in the cleaning tank 2 it can.

  The charged particulate water is supplied into the cleaning tank 2 by operating the electrostatic atomizer 18 continuously or intermittently. The charged fine particle water may be supplied for a predetermined time or continuously until the next main washing step is started, and the operation time is not particularly limited. About operating the electrostatic atomizer 18 which is an ion generation part continuously or intermittently, the performance and the life in operation of the device of an ion generation part should just be balanced. By this, the ion generation part can operate | move to long life, maintaining performance.

In the case of the combined washing course, the user additionally sets the object to be washed 8 in the tableware basket 10 until the main washing process is started, and stores the inside of the washing tank 2 (Yes in step 5). . In this case, the control unit 17 executes the preliminary washing process of steps S3 to S4 each time it is detected that the object to be washed 8 is stored in the washing tank 2 and the setting is completed. With this configuration, when the object to be cleaned 8 is set a plurality of times in the cleaning tank 2 before the main cleaning step, the preliminary cleaning operation and the ion introduction operation are performed as the preliminary cleaning step each time. Thereby, whenever the to-be-cleaned object 8 is newly set, sterilization and deodorizing of the to-be-cleaned object 8 and the washing tank 2 inner surface can be performed. And the main washing process performed after that can be performed efficiently, and the washing effect can be heightened.

  Next, when the user finishes the final setting of the object to be cleaned 8 or when it is time to perform the main washing process after setting (No in step S5), the user performs the setting completion operation using the operation unit ( Step S6). This operation is an instruction to shift to the next step, and the control unit 17 executes the main washing step, the rinsing step, and the drying step (step S7). Then, when all the steps of the combined washing course are completed, the washing operation is ended.

  Note that even after the drying step is completed, the short-time ion introduction operation may be repeated at predetermined time intervals until the object to be cleaned 8 is taken out of the cleaning tank 2 (step 8). As a result, charged fine particle water or ions can be appropriately supplied into the cleaning tank 2, and odor mitigation and sterilization can be continued.

  As described above, the dishwasher according to the first embodiment executes the washing operation of the collective washing course.

  Here, the details of the operation of the electrostatic atomizer 18 will be described with reference to FIG. FIG. 4 is a timing chart showing the operation of the electrostatic atomizer 18 and the blower fan 13 in the ion introducing operation of the dishwasher of the present embodiment. The configuration of the electrostatic atomizing device 18 is the same as that of the prior art, and FIG. 6 is used.

  As shown in FIG. 4, the control unit 17 starts the operation of the blower fan 13 with a delay of time T from the start of operation of the electrostatic atomizing device 18. The electrostatic atomizing device 18 cools the air by the cooling unit 18 a made of a Peltier unit or the like to generate condensed water. In the electrostatic atomizing device 18 of the present embodiment, the discharge electrode 18 b is cooled by the cooling unit 18 a. Thus, the dew condensation water is directly generated and supplied to the discharge electrode 18b, but the blower fan 13 is not operated in an initial state of the electrostatic atomization device 18 in order to make the condensation state more stable.

  By such control, the cooling unit 18a can rapidly cool the discharge electrode 18b, and can accelerate the generation of the condensed water. That is, continuous cooling including the same air in the vicinity of the discharge electrode 18b can be more efficiently cooled than cooling including air which is replaced with fresh air one after another by blowing air. Once the discharge electrode 18 b is cooled and condensation water begins to be generated, condensation water is continuously and stably generated. At this stage, the dew condensation water is sufficiently supplied to the discharge electrode 18b, and the generation of charged fine particle water by the discharge starts.

  The control unit 17 starts the operation of the blower fan 13 at the timing (for example, after the time T) at which the condensed water is continuously generated and the charged particulate water is generated as described above, and the charged particulate water is cleaned. Supply into the tank 2 Thereby, the electrostatic atomizer 18 can rapidly cool the cooling unit 18a to accelerate the generation of condensed water and generate charged particulate water in a short time.

  The length of time T until the electrostatic atomizer 18 is started and the blower fan 13 is started is not particularly limited. For example, when the time from the stop of the electrostatic atomizer 18 to the start of the next operation is short, it may be possible to stably generate charged particulate water immediately while the dew condensation state is maintained. The time T may be determined by the time of the operation stop. Moreover, since the time which dew condensation generate | occur | produces changes with the humidity of the air to be cooled, you may determine the time T by detecting the generation situation of dew condensation water.

  In the above, the washing operation of the dishwasher in the present embodiment has been described by exemplifying the washing course. However, it is also possible to perform the ion introduction operation after the rinsing step, the drying step, or the end of the operation, and the above description is effective when the electrostatic atomizing device 18 is operated.

  As described above, the dishwasher in the present embodiment includes the cleaning tank 2 for storing the object to be cleaned 8, the cleaning nozzle 7 for cleaning the object to be cleaned 8, and the electrostatic atomizing device 18 for generating charged particulate water. And an air passage 20 (introduction air passage) for supplying charged fine particle water generated by the electrostatic atomization device 18 into the cleaning tank 2 and a blower fan 13 (ion introduction device). The electrostatic atomizing device 18 is provided in the sub air passage 20 b, and the air passage 20 is a part of the air flowing in the sub air passage 20 b. The flow velocity is configured to be smaller than the flow velocity of the air flowing through the main air passage 20a.

  With this configuration, by reducing the flow velocity of the sub air passage 20b provided with the electrostatic atomizing device 18, it is possible to stably generate charged particulate water. As a result, the influence of the environment inside the washing tank 2 or the outside of the dishwasher can be suppressed, and the concentration of the charged fine particle water can be controlled. In addition, the generated charged fine particle water can be put on the flow of air having a high flow velocity flowing through the main air passage 20 a and supplied into the cleaning tank 2. As a result, charged particulate water reliably adheres to all the objects to be cleaned 8 set in the cleaning tank 2 and all the inner surfaces of the cleaning tank 2, thereby reliably reducing odor and suppressing reproduction of bacteria and eliminating bacteria. You can

  Further, a wall surface 22 is provided in the merging portion 20c where the sub air passage 20b merges with the main air passage 20a, and the wall surface 22 is provided on the upstream side of the merging portion 20c and inclined downstream. It is formed. With this configuration, air in the sub air passage 20b is sucked by the venturi effect generated in the flow of the main air passage 20a due to the presence of the wall surface 22. As a result, the air in the sub air passage 20b can be prevented from flowing backward in the direction of the electrostatic atomizing device 18, and the charged fine particle water can be stably supplied into the cleaning tank 2.

  Further, a blower fan 13 for blowing drying air into the cleaning tank 2 and an air passage 20 for communicating the blower fan 13 with the cleaning tank 2 are provided, and the air passage 20 is supplied with charged particulate water. The blower fan is also configured to be used as an iontophoretic device that supplies charged particulate water generated by the electrostatic atomizer 18 into the cleaning tank 2. This configuration makes it possible to realize the configuration and control unit 17 related to the generation and supply of charged particulate water with a simple configuration. Thereby, the internal volume of the washing tank 2 is large and it can provide a cheap dishwasher.

  Furthermore, a filter 15 for collecting dust and the like contained in the air is disposed upstream of the electrostatic atomizing device 18 in the air flow in the air passage 20. With this configuration, dust and the like can be prevented from adhering to an internal device (such as a discharge electrode) of the electrostatic atomization device 18, and generation of charged particulate water can be stabilized.

  Furthermore, an outlet air passage (not shown) through which air flows out from the cleaning tank 2 and an inlet air passage (not shown) through which air flows into the cleaning tank 2 are provided, and the outlet air passage and the inlet air passage Even if a circulating air passage (not shown) independent of the air passage 20 is formed, and an ion generating unit such as the electrostatic atomizing device 18 and an ion introducing device such as a fan are provided in the circulating air passage. Good. With this configuration, the charged particulate water or ions supplied into the cleaning tank 2 circulates and is not released to the outside, so more charged particulate water or ions can be supplied into the cleaning tank 2.

Although the electrostatic atomization device 18 is automatically operated as a standard in the above-mentioned collective washing course, it is set as an optional function, and is configured to operate according to the user's judgment if necessary. It is also good.

  Further, in the present embodiment, although the ion generation unit is an electrostatic atomizer, by generating ions, the ion generator performs sterilization and deodorization of the inner surface of the object to be cleaned and the cleaning tank. The same effect can be obtained.

  As described above, the dishwasher according to the present invention generates charged particulate water or ions in a stable state, reliably supplies it to all the positions in the cleaning tank, and all the objects to be cleaned set in the cleaning tank. It is possible to ensure that charged particulate water or ions adhere to the inner surfaces of the objects and the cleaning tank. Moreover, the influence of the inside of a washing tank and the external environment of a dishwasher can be suppressed, and control of the density | concentration of charged fine particle water is attained. As a result, the generation of odor and the growth of bacteria caused by food residue adhering to the material to be washed in the washing tank can be suppressed, and therefore, it is useful as a domestic dishwasher, dish washer / dryer or dish dryer.

1 main body 2 washing tank 7 washing nozzle (washing section)
13 Blowing fan (blowing device, ion introduction device)
14 outside air suction port 15 filter 16 heater 17 control unit 18 electrostatic atomizer (ion generating unit)
18a cooling unit 20 air passage 20a main air passage 20b sub air passage 22 wall surface 23 air flow detection unit

Claims (5)

The cleaning tank for storing the object to be cleaned, the cleaning part for cleaning the object to be cleaned, charged fine particle water or ion generating part for generating ions, charged fine particle water or ion generated by the ion generating part Equipped with an inlet air passage and an iontophoresis device.
The introduction air path is constituted by a main air path and a sub air path branched from the main air path,
The ion generating unit is provided in the sub air passage,
The introduction air passage is configured such that the flow velocity of air flowing through the sub air passage is smaller than the flow velocity of air flowing through the main air passage.
dishwasher. A wall surface is provided by causing the sub air passage to project into the main air passage at a junction where the sub air passage joins the main air passage.
The wall surface is formed to be inclined to the downstream side on the upstream side of the merging portion.
A dishwasher according to claim 1. A blower for blowing external air into the cleaning tank, and an air passage for communicating the blower with the cleaning tank are provided.
The air passage is configured to double as the introduction air passage,
The blower is configured to double as the iontophoresis device,
A dishwasher according to claim 1 or 2. A filter for collecting dust and the like contained in the air is provided in the air passage,
The filter is disposed upstream of the ion generation unit.
A dishwasher according to claim 3. There is provided an outlet air passage from which the air flows out from the cleaning tank,
The derived air passage is connected to the introduced air passage to form a circulating air passage,
The ion generating unit and the ion introducing device are provided in the circulation air passage,
A dishwasher according to claim 1 or 2.