JP5628595B2 - Dishwasher - Google Patents

Description

  The present invention provides ventilating means through a ventilating path extending between a water supply port for supplying hot and cold water for cleaning and rinsing into an openable and closable cleaning space, an air suction port from the cleaning space, and an air supply port to the cleaning space. A dehumidifying section that condenses and dehumidifies moisture in the air by cooling the air in the cleaning space circulated in contact with hot water for dehumidification, and heating means for heating the air in the cleaning space A hot and cold intermittent means for intermittently supplying hot water to the water supply port and intermittently supplying hot water to the dehumidifying unit, a cleaning process for cleaning the cleaning object in the cleaning space, and a rinsing process for the cleaning object And a control means for performing a drying process for drying the object to be cleaned, wherein the control means supplies hot water from the water supply port into the cleaning tank in the cleaning process and the rinsing process. Cleaning and In order to perform rinsing, the hot water intermittent means is controlled, and in the drying process, while the air in the cleaning space is heated by the heating means, the dehumidified hot water and the air passing through the ventilation path It is related with the dishwasher comprised so that the said ventilation | gas_flowing means, the said heating means, and the said hot-water intermittent means might be controlled to make it contact.

Such dishwashers are used for washing dishes such as dishes and teacups.
That is, the dishwasher is used in various usage forms, and the standard usage form is that the object to be cleaned is stored in the cleaning space, and the cleaning space is cleaned from the water supply port. The hot water is supplied to the cleaning space, and the cleaning water is ejected as cleaning water from the cleaning nozzle equipped in the cleaning space. Next, the hot water in the cleaning space is discharged and then cleaned from the water supply port. Rinsing is performed by supplying rinsing hot water into the space and ejecting the rinsing hot water from a cleaning nozzle equipped in the cleaning space, and then draining the hot water in the cleaning space, followed by drying. It is a form.

As another usage form of the dishwasher, for example, there is a form for washing an object to be washed that does not require a washing process or a rinsing process such as hand washing, and in such a case, a drying process is performed. Become.
That is, the dishwasher is used for washing and drying dishes in a standard usage pattern or a different form.

  Moreover, the above-described dishwasher cools the air passing through the ventilation path by contacting with the hot water for dehumidification while heating the air in the washing space by the heating means as a drying process. Since moisture is condensed and dehumidified, when performing the drying process, moist air is not discharged outside the machine, so the moist air is installed by the user or the dishwasher. Therefore, it can be prevented from being sprayed on other devices existing in the place where the operation is performed, and is easy to use (see, for example, Patent Document 1).

  In Patent Document 1, a detailed description of the drying process is not described. However, in the drying process, a heater as a heating unit provided at the bottom of the cleaning space is operated so that the air in the cleaning space is discharged. It will be heated.

JP-A-8-131391

By the way, in the dishwasher, after starting the execution of the drying process, the object to be cleaned is newly stored in the cleaning space in order to dry the object to be cleaned such as hand-washed. Sometimes it is desirable.
As described above, when it is desired to newly store the cleaning target object to be dried in the cleaning space after starting the drying process, the drying process is interrupted and the target of the drying process is stopped. The object to be cleaned is stored in the cleaning space, and then the drying process is resumed.
When the drying process is interrupted, generally, the ventilation operation of the ventilation means for circulating the air in the cleaning space and the heating operation of the heating means for heating the air in the cleaning space are stopped and added. It is conceivable to stop supplying dehumidified hot water to the dehumidifying section.

  In other words, when opening the openable / closable cleaning space to accommodate a new cleaning object to be dried, air will blow out from the cleaning space if the ventilation means is left in operation. Therefore, the air that blows out may cause discomfort to the user, so that the ventilation means will be stopped, and the heating means will be stopped accordingly, and in addition to dehumidifying the dehumidifying part It is conceivable to stop supplying hot water.

However, in this case, when the drying operation is resumed by restarting the ventilation operation of the ventilation means, the heating operation of the heating means, and the supply of the dehumidifying hot water to the dehumidifying part, the dehumidifying hot water is supplied to the dehumidifying part. Even if the supply of the water is resumed, there is a possibility that the drying process cannot be resumed properly because it is difficult to quickly resume the dehumidifying action by the dehumidifying unit.
In other words, when the hot water intermittent means is switched from the supply stop state to the hot water supply state in order to resume the supply of dehumidified hot water to the dehumidifying part, it takes time for hot water to flow from the hot water intermittent means to the dehumidifying part. It is difficult to quickly resume the dehumidifying action by the dehumidifying part because it takes time or it takes time until the dehumidifying action is performed properly after the dehumidifying hot water is supplied to the dehumidifying part. As a result, there is a possibility that the drying process cannot be resumed properly.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a dishwasher capable of interrupting a drying process and storing an object to be cleaned in a cleaning space, and appropriately restarting the drying process. The point is to provide.

The dishwasher of the present invention includes a water supply port for supplying hot and cold water for washing and rinsing into an openable and closable washing space,
By cooling the air in the cleaning space circulated by the ventilation means through the ventilation path extending from the air suction port to the cleaning space and the air supply port to the cleaning space by contact with hot water for dehumidification, A dehumidifying part that dehumidifies by condensing moisture in the air;
Heating means for heating the air in the cleaning space;
Hot water intermittent means for intermittently supplying hot water to the water supply port and intermittently supplying hot water to the dehumidifying section;
A cleaning unit that cleans an object to be cleaned in the cleaning space, a rinsing process for rinsing the object to be cleaned, and a control unit that executes a drying process for drying the object to be cleaned;
The control means is
In the cleaning process and the rinsing process, the hot water intermittent means is controlled so as to perform cleaning and rinsing by supplying hot water from the water supply port into the cleaning tank, and
In the drying treatment, the heating means, the heating means, and the air passing through the ventilation path are brought into contact with the hot water for dehumidification and the air passing through the ventilation path. A dishwasher configured to control hot and cold intermittent means, the first characteristic configuration is
When the control unit is instructed to interrupt the drying process during the execution of the drying process, the control unit executes the drying interruption process to interrupt the execution of the drying process, and when the restart instruction is instructed thereafter, the drying process is performed. It is configured to resume, and as the drying interruption process, the ventilation unit and the heating unit are controlled to stop the ventilation operation of the ventilation unit and the heating operation of the heating unit, and the dehumidifying unit Configured to control the hot water intermittent means to continue the supply of hot water for dehumidification ,
The hot water interrupting means is branched from a first on-off valve for opening and closing a water supply path connected to a water supply source, a washing tank branch path branched from the water supply path and connected to the water supply port, and the water supply path. Of the dehumidifying branch connected to the dehumidifying section, a second on-off valve that opens and closes the cleaning tank branch, and the first on-off valve and the second open / close equipped on the dehumidifying branch. A constant flow valve that restricts the flow rate of hot water flowing through the dehumidifying branch path to be less than the flow rate of hot water flowing through the washing tank branch path when the valve is open;
When the control means supplies hot water in the cleaning process and the rinsing process, the first on-off valve and the second on-off valve are opened, and when hot water is supplied in the drying process, the first on-off valve And is configured to close the second on-off valve,
The second on-off valve can be switched between a valve housing, a valve seat provided in the valve housing, a closed state in contact with the valve seat, and an open state separated from the valve seat The valve body is formed in the valve body so as to communicate the back side pressure chamber of the valve body into which the fluid in the upstream flow passage portion from the valve seat flows and the downstream flow passage portion from the valve seat. A valve operating body for opening and closing the through hole,
When the valve operating body operates the through hole in a closed state, fluid in a flow path portion upstream from the valve seat flows into the back-side pressure chamber of the valve body to bring the valve body into the closed state. When the valve operating body is operated and the through-hole is opened, the fluid in the flow path portion upstream of the valve seat operates the valve body in the open state. Features a point.

  That is, if an interruption command is issued during the execution of the drying process, the drying interruption process for interrupting the execution of the drying process is executed. Therefore, when it is desired to add an object to be dried, the drying process is performed. The object to be cleaned can be stored in the cleaning space, and when the restart command is issued, the drying process is resumed, so the drying process is interrupted and the object to be cleaned is cleaned. After storing in the space, the drying process can be continued by giving a restart command.

  Then, as the drying interruption process, the ventilation means, the heating means, and the hot water intermittently, in order to stop the ventilation operation of the ventilation means and the heating operation of the heating means, and to continue supplying hot water for dehumidification to the dehumidifying section. Since the means is controlled, when the drying process is interrupted, the ventilation operation of the ventilation means and the heating operation of the heating means are stopped, but the supply of hot water for dehumidification to the dehumidifying unit is continued. Therefore, when the drying process is resumed, the dehumidifying action in the dehumidifying section can be quickly resumed, and the drying process can be resumed appropriately.

  In other words, in the drying interruption process, when the supply of dehumidified hot water to the dehumidifying unit is stopped, the hot water is supplied to the dehumidifying unit when the hot water intermittent means is operated by the restart command to supply the dehumidified water. This is because it takes time for hot water to flow from the intermittent means to the dehumidifying part, and it takes time for dehumidification to be performed properly after the dehumidifying hot water is supplied to the dehumidifying part. However, it is difficult to quickly resume the dehumidifying action by the dehumidifying part, but since the supply of dehumidifying hot water to the dehumidifying part is continued even during the suspension of the drying process, the dehumidifying action of the dehumidifying part Can be restarted quickly, and the drying process can be restarted appropriately.

  In short, according to the first characteristic configuration of the present invention, it is possible to provide a dishwasher that can interrupt the drying process and store the object to be cleaned in the cleaning space, and can appropriately restart the drying process.

According to the first characteristic configuration of the present invention, when hot water is supplied to the cleaning space in the cleaning process and the rinsing process, the first on-off valve and the second on-off valve are opened, so that the hot water from the water supply passage is cleaned. It is performed by being supplied to the cleaning space from the water supply port through the branch for the tank, and hot water from the water supply path is supplied to the cleaning space from the dehumidifying part through the branch for dehumidification In processing, the time required to store hot water at the cleaning space suitable for cleaning and rinsing in the cleaning space is shorter than when only hot water is supplied from the water supply port into the cleaning space. Therefore, it can be shortened.

Further, in the drying process, the first on-off valve is opened and the second on-off valve is closed, so that the hot water flow through the washing tank branch passage is stopped and the supply from the water supply passage is stopped. Hot water is supplied to the dehumidifying section through the dehumidifying branch.
The dehumidification branch is equipped with a flow valve that restricts the flow rate of hot water flowing through the dehumidification branch to be smaller than the flow rate of hot water flowing through the branch for the cleaning tank. Therefore, the flow rate of hot water supplied through the dehumidifying branch path is limited to a small amount necessary for the dehumidifying action in the dehumidifying section.

  Furthermore, with regard to stopping the supply of hot water to the cleaning space through the cleaning tank branch, the first on-off valve provided in the water supply path and the second on-off valve provided in the cleaning tank branch are doubled. Even if one of the first on-off valve and the second on-off valve cannot be properly shut off due to a foreign object or the like, the cleaning tank branch passage is passed. The supply of hot water to the washed space is stopped, and it is prevented that hot water is stored in an abnormally high water level in a short time, so that a large amount of water is not wasted. Will be.

  In other words, when hot water is stored in an abnormally high water level in the cleaning space, such an abnormal state is detected by the abnormal water level detection means, and discharge processing for discharging hot water in the cleaning space. However, if such a discharge process is repeatedly performed in a short cycle, a large amount of hot water is consumed wastefully. It is necessary to prevent the water from being stored.

  In the open state of the first on-off valve and the second on-off valve, the flow rate of hot water through the washing tank branch passage is constant so that hot water can be quickly stored in the cleaning space. Since it is configured to be larger than the flow rate of hot water through the dehumidifying branch with a flow valve, supply hot water appropriately when the supply of hot water to the cleaning space through the cleaning tank branch is stopped. When it cannot be stopped in a short time, the hot water is stored in the cleaning space at an abnormally high water level in a short time, and there is a possibility that the above-mentioned discharge treatment may be repeatedly performed in a short cycle. The hot water supply to the washing space through the branch passage is stopped because it is shut off twice by the first on-off valve installed in the water supply passage and the second on-off valve installed in the branch for the washing tank. Hot water supply to the washing space through the tank branch Accordingly, hot water in the washing space that is ready to be stored in the abnormally high level becomes to be minimized.

  In addition, when the first on-off valve installed in the water supply path cannot be properly shut off due to a foreign object or the like, hot water flows through the dehumidifying branch and passes through the dehumidifying section. Although it will flow into the cleaning space, the flow rate of hot water through the dehumidifying branch is limited to a small amount by the constant flow valve, so the first on-off valve equipped in the water supply channel should be properly Even if it cannot be shut off, it takes a long time for hot water to be stored in an abnormally high water level in the cleaning space, and the above-described discharge process is repeatedly performed in a short cycle. And a large amount of hot water is not wasted.

  By the way, in addition to the first on-off valve and the second on-off valve described above, an on-off valve for opening and closing the dehumidifying branch is provided, and the first on-off valve and the dehumidifying valve are also used for stopping hot water supply to the dehumidifying branch. It is possible to adopt a structure that shuts off twice by using an open / close valve that opens and closes the branch path, but the flow rate of hot and cold water through the dehumidification branch path is limited to a small amount by a constant flow valve. Paying attention to a simple configuration with a first on-off valve that opens and closes the water supply path and a second on-off valve that opens and closes the branch path for the washing tank without providing an on-off valve that opens and closes the dehumidifying branch path Thus, it can be avoided that a large amount of hot and cold water is consumed.

In short, according to the first characterizing feature of the present invention, in addition to the work for the above effects, it is possible to shorten the time for storing the hot water of the water level for washing in the washing space in a cleaning process and rinsing process In addition, it is possible to provide a dishwasher that can avoid wasteful consumption of a large amount of hot water with a simple configuration.

Moreover, according to the 1st characteristic structure of this invention, the 2nd on-off valve which opens and closes the branch path for washing tanks is opened and closed by opening and closing a through-hole with a valve operating body.
That is, when the through hole is operated in the closed state by the valve operating body, the fluid in the upstream flow passage portion from the valve seat flows into the pressure chamber on the back side of the valve body and presses the valve body to the valve seat side. As a result, the valve body is operated in the closed state.
Further, when the valve operating body is operated to open the through hole, the pressure in the pressure chamber on the back side of the valve body is reduced to the pressure in the flow passage portion downstream from the valve seat, and the flow passage upstream from the valve seat When the valve body is pressed to the side away from the valve seat by the fluid of the part, the valve body is operated in the open state.

  As described above, the second on-off valve operates the valve body between the closed state and the open state using the pressure of the fluid by operating the through hole between the closed state and the open state by the valve operating body. Therefore, even when the valve operating body is operated with an electromagnetic force, for example, the opening / closing operation force can be reduced, for example, the electromagnetic force for the operation can be reduced.

By the way, in such a second on-off valve, if there is no fluid pressure in the upstream flow passage portion from the valve seat, the valve body cannot be opened / closed properly, and the second opening / closing valve opens / closes the water supply passage. In a state in which the 1 on-off valve is closed, there is no fluid pressure in the upstream flow passage portion from the valve seat of the second on-off valve.
In addition, the first on-off valve is operated from the closed state to the open state from the state where the fluid pressure in the upstream-side flow passage portion does not exist from the valve seat of the second on-off valve, and the upstream side of the valve seat of the second on-off valve. Immediately after switching to a state in which the fluid pressure in the side channel portion is present, there is no fluid pressure in the pressure chamber in the back side of the valve body, so even if the through hole is operated to be closed by the valve operating body. The valve body is temporarily pressed to the side away from the valve seat by the fluid pressure in the upstream flow passage portion from the valve seat of the second on-off valve, and the fluid flows to the downstream flow passage portion from the valve seat. There is a risk of doing.

  In other words, when the drying process is interrupted, if the first on-off valve is configured to be closed, when the drying process is resumed and the first on-off valve is opened, the hot water from the water supply channel is opened and closed second. Although it may flow downstream through the valve and spout from the water supply port into the cleaning space, the object to be cleaned may be wetted. As described above, the first opening and closing is also performed when the drying process is interrupted. Since the valve is kept open, when the drying process is resumed after interrupting the drying process, hot water is prevented from being ejected from the water supply port, and the object to be cleaned during drying is removed. You can avoid getting wet.

In short, according to the first characterizing feature of the present invention, in addition to the work for the effects mentioned above, while to achieve a reduction in the opening and closing force of the second on-off valve for opening and closing the cleaning tank branch path was interrupted When the drying process is resumed, it is possible to provide a dishwasher that can avoid wetting the object to be cleaned during drying.

The second characteristic configuration of the present invention, in addition to the first feature structure,
When the elapsed time from the execution of the drying interruption process reaches the notification time, the control means executes a drying interruption notification process for operating the notification means to notify that the drying process is being interrupted. It is characterized by being configured to do so.

That is, when the elapsed time since the execution of the drying interruption process reaches the notification time, it is notified that the drying process is being interrupted.
In this way, since it is notified that the drying process is interrupted, even if the user forgets that the drying process is interrupted, the user is aware that the drying process is interrupted. Thus, it is possible to prompt the user to resume the drying process.

In short, according to the second characterizing feature of the present invention, prompt the addition to the effects according to the first feature structure, by recognizing that it is in the drying process to a user interrupt, resume drying process A dishwasher can be provided.

The third feature configuration of the present invention is in addition to the second feature configuration,
When the control means has reached a stop time set to a time longer than the notification time after the drying interruption process has been performed, the dehumidifying hot water to the dehumidifying part A feature is that the hot water intermittent means is controlled to stop the supply.

That is, when the elapsed time since the drying interruption process reaches the stop time set to be longer than the notification time, the supply of dehumidified hot water to the dehumidifying unit is stopped. Become.
That is, when the elapsed time since the execution of the drying interruption process reaches the stop time set to a time longer than the notification time, the drying process is unlikely to be resumed thereafter. As described above, it is possible to suppress unnecessary consumption of hot water for dehumidification by stopping the supply of hot water for dehumidification to the dehumidifying unit.

In short, according to the third characteristic configuration of the present invention, it is possible to provide a dishwasher that can suppress unnecessary consumption of hot water for dehumidification in addition to the operational effects of the second characteristic configuration.

In addition to any of the first to third feature configurations described above, the fourth feature configuration of the present invention includes:
The air supply port and the air supply port are formed at lower positions in the side wall portion of the cleaning space,
The ventilation path is configured in an inverted U shape including an upward path portion extending upward from the air suction port and a downward path portion extending downward from the upper end portion of the upward path portion toward the air supply port. ,
The dehumidifying part is
Ejecting means for ejecting dehumidified hot water downward with respect to the air passing through the ascending path portion in the ventilation path, and air venting the ascending path portion upward by the ejecting means. It is configured to dehumidify by condensing moisture in the air by cooling with contact with dehumidified hot water sprayed downward, and the dehumidified hot water and condensed hot water are the air. It is characterized by being configured to flow into the cleaning space through a suction port.

  That is, the air suction port and the air supply port are formed at lower positions in the side wall portion of the cleaning space, and the ventilation path extends from the air suction port to the upper side and the upper end portion of the lift path portion. Since it is configured in an inverted U shape including a downward path portion extending downward toward the air supply port, it is possible to suppress clogging of leftovers in the cleaning space in the ventilation path.

  In addition, there is a risk that leftovers attached to the object to be cleaned may be scattered in the ventilation path through the air suction port or air supply port during the rinsing process or the rinsing process. The air suction port extends in the vertical direction with the air suction port positioned at the lowest position, and the descending path portion extends in the vertical direction with the air supply port positioned at the lowest position. The scattered leftovers do not move to the upper side of the ventilation path, and the leftovers scattered in the ventilation path fall into the washing space by their own weight and return to the washing space. It becomes possible to suppress the clogging of vegetables in the ventilation path.

  In addition, since the air suction port and the air supply port are formed at lower positions in the side wall portion of the cleaning space, the air flow path configured in an inverted U shape composed of the ascending path part and the descending path part is used as the air path. Ventilation means and dehumidifying parts that can be easily caught by leftovers can be formed from the location where the suction port and the air supply port are formed, and greatly upward from the air suction port and the air supply port. It can arrange | position in a distant position, and can make it easy to avoid that the vegetables left in the ventilation path penetrate | invade and adhere to a ventilation means or a dehumidification part.

  Then, the dehumidifying section causes the dehumidifying water to be ejected downward by the ejecting means with respect to the air passing upward through the ascending path portion by the ventilation operation of the ventilating means, and the air passing upward through the ascending path portion. Since the water in the air is condensed by being cooled by contact with the dehumidifying water that ejects the air, it is possible to dehumidify the air in the cleaning space while reducing the amount of the dehumidifying water used.

  In other words, since the air passing upward and the dehumidifying water ejected downward by the ejecting means are brought into contact with each other to condense moisture in the air, the dehumidifying hot water to be ejected is The dehumidifying water will be contacted while moving in the opposite direction, and the dehumidified hot water sprayed downward will come into contact with the air before dehumidification that is ventilated upward. The state where hot water for hot water comes into contact with air and condenses moisture in the air continues over a long region.

  As a result, when performing the drying process, it is possible to dehumidify the air in the cleaning space while reducing the amount of hot water used for dehumidification.

Therefore, according to the fourth feature configuration of the present invention, in addition to the operational effects of any of the first to third feature configurations, it is avoided that the leftovers scattered in the cleaning process and the rinsing process are clogged in the ventilation path. In addition, it is possible to provide a dishwasher that can be used satisfactorily over a long period of time and that can dehumidify the air in the washing space while reducing the amount of hot water used for dehumidification. .

Perspective view of dishwasher Notched side view with the cleaning tank stored The perspective view which looked at the washing tank which removed the front door from the front side Perspective view of the cleaning tank as seen from the back Schematic diagram of dishwasher Schematic perspective view showing the flow state of drying air Cutaway side view of the second on-off valve in the closed state Cutaway side view of the second on-off valve in the open state Flow chart showing control operation Flow chart showing control operation Notched perspective view of water level detector Perspective view of the device Perspective view of the device Longitudinal side view of detection state of hot water discharge water level Longitudinal side view of washing water level detection status Vertical side view of abnormal water level detection Float perspective view

Embodiment
Next, embodiments of the present invention will be described with reference to the drawings.
As shown in FIG. 1 to FIG. 4, a main body 1 is provided as a main body case with an opening on the front surface, and a drawer 2 including a cleaning tank D having a square shape in plan view is provided on the main body 1. On the other hand, the drawer-type dishwasher as an example of the dishwasher is provided so that it can be pulled out and stored along the horizontal direction.
Although not illustrated, a slide-type rail mechanism is provided that supports the drawer portion 2 so as to be movable with respect to the main body portion 1, and the drawer portion 2 exposes most of the main body portion 1 to the outside. It is configured so that it can be pulled out to the state.

  And the inner cover part which obstruct | occludes the upper surface part of the washing tank D in the state which accommodated the drawer part 2 in the main-body part 1, and opens the upper surface part of the washing tank D in the state which pulled out the drawer part 2 from the main body part 1 3 is provided, and an openable / closable cleaning space Q is formed in the internal space of the cleaning tank D.

The front part of the drawer part 2 is provided with a door body A that opens and closes the opening of the front part of the main body part 1, and the door body A is gripped when the drawer part 2 is pulled out from the main body part 1 or stored. A holding part B is provided. Although not described in detail, an engaging means P that engages with the engaging portion Pa of the main body 1 as the drawer 2 is housed in the main body 1 is provided at the inner side portion of the grip B. When the engaging means P is engaged with the engaging portion Pa, the drawer portion 2 is held in the state of being housed in the main body portion 1. Then, the engaging means P can be operated in a released state in which the engagement is released with the fingers supporting the gripping part B when the drawer part 2 is pulled out from the main body part 1.
Further, the door body A is provided with an operation unit SS for performing various operations for driving.

As shown in FIGS. 2 and 5, a water supply channel 4A connected to a water supply source such as a water supply, a washing tank branch channel 4B branched from the water supply channel 4A, and a dehumidifying branch branched from the water supply channel 4A A path 4C is provided.
The washing tank branch 4B is connected to a water supply port 5 for supplying hot water for cleaning and rinsing into the washing space Q of the washing tank D, and the dehumidifying branch 4C is connected to the front side wall Df of the washing tank D. It is connected to a dehumidifying part G to be described later.

The first on-off valve V1 that opens and closes the water supply path 4A, the second on-off valve V2 that opens and closes the washing tank branch path 4B, and the dehumidification branch path 4C are equipped with the first on-off valve V1 and the second on-off valve. A constant flow valve V3 for limiting the flow rate of hot water flowing through the dehumidification branch 4C to be smaller than the flow rate of hot water flowing through the washing tank branch 4B in the open state of the on-off valve; The hot water supply / interruption means E is provided, and is configured to intermittently supply hot water to the water supply port and intermittently supply hot water to the dehumidifying section from the first on / off valve V1, the second on / off valve V2, and the constant flow valve V3. Has been.
That is, when hot water is supplied to the water supply port 5, the first on-off valve V1 and the second on-off valve V2 are opened. When hot water is supplied to the dehumidifying unit G, the first on-off valve V1 is opened. The second on-off valve V2 is closed.
Although the flow rate of hot water flowing through the washing tank branch 4B is sufficiently larger than the flow rate of hot water flowing through the dehumidification branch 4C, the first on-off valve V1 has an excessive flow rate. A constant flow valve V4 that restricts the occurrence of this is equipped in a state of being integrated.

  In addition, a first on-off valve V1, a second on-off valve V2, and a constant flow valve V3 are disposed on the back side of the main body 1, and the second on-off valve V2 and the water supply port 5 in the washing tank branch 4A. Are connected by a flexible hose R1, and a portion connecting the constant flow valve V3 and the dehumidifying part G in the dehumidifying branch 4C is formed by a flexible hose R2.

  The second on-off valve V2 will be described. As shown in FIGS. 7 and 8, the second on-off valve V2 includes a valve housing 50 disposed in the middle of the cleaning tank branch 4B, and the valve housing 50. , A valve body 53 that can be switched between a closed state in contact with the valve seat 52 and an open state in which the valve seat 52 is separated from the valve seat 52, and a flow upstream of the valve seat 52. The valve body 53 is connected so that the back-side pressure chamber 51B of the valve body 53 into which the fluid of the passage portion 51A flows, and the back-side pressure chamber 51B of the valve body 53 and the flow path portion 51C downstream of the valve seat 52 are communicated. And a valve operating body 54 that opens and closes the through hole 53b.

The valve body 53 is formed so that a part thereof faces the upstream channel portion 51A, and is configured to be pressed to the side away from the valve seat 52 by the fluid pressure of the upstream channel portion 51A, and A bleed hole 53a that guides the fluid in the upstream flow path portion 51A to the back pressure chamber 51B is formed in a portion of the valve body 53 that faces the upstream flow path portion 51A.
When the valve operating body 54 operates the through hole 53b in the closed state, the fluid in the upstream flow passage portion 51A from the valve seat 52 flows into the back side pressure chamber 51B of the valve body 53 to close the valve body 53. When the valve operating body 54 is operated to the open state and the through-hole 53b is opened, the fluid in the flow passage portion 51A upstream of the valve seat 52 operates the so-called pilot valve. It is structured in a way.

When describing each part, a valve seat contact portion 53c that comes into close contact with the valve seat 52 is provided at a portion of the valve body 53 that faces the valve seat 52.
A cylindrical valve operating body casing 58 closed at one end side is assembled to the valve housing 50, and the valve operating body 54 is slidably mounted in the valve operating body casing 58. A spring 56 is provided to return and urge the through hole 53b toward the closed state side.
A contact portion 54b that contacts the through hole 53b is provided at the end of the valve operating body 54 on the valve body 53 side.

A solenoid 55 for operating the valve operating body 54 to open the through hole 53 b against the return biasing force of the spring 56 is provided on the outer peripheral portion of the valve operating body casing 58.
That is, when the valve operating body 54 is moved and operated against the urging force of the spring 56 by the solenoid 55, the contact portion 54b of the valve operating body 54 is separated from the through hole 53b of the valve body 53, and the through hole 53b is opened.
Further, when the operation of the valve operating body 54 by the solenoid 55 is released, the valve operating body 54 moves by the biasing force of the spring 56, and the contact portion 54 b of the valve operating body 54 enters the through hole 53 b of the valve body 53. The contact state is established, and the through hole 53b is closed.

  When the valve operating body 54 is operated so as to close the through hole 53b, as shown by an arrow in FIG. 7, the upstream flow passage portion 51A is changed from the upstream flow passage portion 51A to the back pressure chamber 51B through the bleed hole 53a. The fluid (hot water) flows in, the fluid pressure in the back side pressure chamber 51 </ b> B increases, and the valve body 53 comes into contact with the valve seat 52. Accordingly, the space between the upstream channel portion 51A and the downstream channel portion 51C in the valve housing 50 is closed, and the supply of hot water to the water supply port is stopped.

  When the valve operating body 54 is operated so as to open the through-hole 53b, the back-side pressure chamber 51B communicates with the downstream-side flow passage portion 51C through the through-hole 53b, and the back-side pressure chamber 51B. Since the internal fluid pressure is lower than that of the upstream flow path portion 51 </ b> A, the valve body 53 is operated to the open state, and the valve body 53 is opened to be separated from the valve seat 52. Therefore, as shown by the arrow in FIG. 8, the upstream flow path portion 51A and the downstream flow path portion 51C in the valve housing 50 are connected, and hot water is supplied to the water supply port.

  In addition, the flow rate of hot water flowing through the washing tank branch 4B is flown at the upstream side of the valve housing 50, although the flow rate is sufficiently larger than the flow rate of hot water flowing through the dehumidification branch 4C. A constant flow valve V4 that restricts the set amount is provided, and a filter 57 that prevents foreign matter from flowing into the second on-off valve V2 is provided in the constant flow valve V4.

  Below the bottom of the washing tank D in the drawer 2, a dual-purpose pump 6 that functions as a cleaning pump in forward rotation and functions as a drainage pump in reverse rotation is provided, and in the cleaning space Q of the cleaning tank D, A cleaning nozzle 8 and an electric heater 9 as a heating means are arranged, and a cleaning basket 10 for storing and placing an object to be cleaned such as tableware is detachably mounted in the cleaning tank D. .

The dual-purpose pump 6 is connected to a water storage recess S formed at the bottom of the cleaning tank D by a suction pipe 11 and a drain pipe 12 is connected thereto.
As shown in FIG. 2, a drain pan 14 for receiving water leakage is provided at the bottom of the main body 1. Although not illustrated, the presence or absence of water received and collected by the drain pan 14 is detected. It will be equipped with a leak sensor.

Further, as shown in FIG. 5, a water level sensor J as a water level detecting means is connected to the water storage recess S through a guide tube 13 as a communication path.
As will be described later, the water level sensor J is configured such that the level of hot water stored in the cleaning space Q of the cleaning tank D is a cleaning water level (high water level), and hot water stored in the cleaning space Q of the cleaning tank D. The water level is equivalent to a state in which most of the hot water has been discharged from the cleaning space Q, and is a hot water discharge water level (low water level) that is low enough to expose the heater 9, and is stored in the cleaning tank D. The hot water is detected to be an abnormal water level that is higher than the cleaning water level by a set amount.

As shown in FIGS. 2, 3 and 5, of the four side walls forming the cleaning space Q in the cleaning tank D, the front side wall Df corresponding to the front side of the machine body, that is, the front side of the drawer part, A drying unit K is attached.
That is, as shown in FIG. 6, the air supply port 21 that supplies the air from the drying unit K to the cleaning space Q and the drying unit K suck the air in the cleaning space Q into the front side wall portion Df. The air suction port 22 is formed at a position corresponding to the lower side of the cleaning space Q and at positions separated on both the left and right sides. Specifically, the air supply port 21 and the air suction port 22 are formed so as to be positioned below the cleaning basket 10, and in the present embodiment, the air supply port 21 is on the right side. The air suction port 22 is positioned on the left side.

The drying unit K circulates the air in the cleaning space Q through the ventilation path F extending between the air suction port 22 and the air supply port 21 inside the casing 20 fixed to the front side wall portion Df of the cleaning tank D. And the above-mentioned dehumidifying part G for dehumidifying the air circulated through the ventilation path F.
The ventilation path F has an inverted U-shape composed of an ascending path part f1 extending upward from the air suction port 22 and a descending path part f2 extending downward from the upper end of the ascending path part f1 toward the air supply port 21. The dehumidifying part G is disposed in the ascending path part f1, and the circulation fan 23 is disposed in the descending path part f2.

The dehumidifying part G includes a plurality of heat transfer plates 24 juxtaposed at intervals along the plate thickness direction and ejects hot water for dehumidification from the ejection nozzle 25 toward the heat transfer plates 24. The air flowing upward through the heat transfer plates 24 is cooled by contact with dehumidification water flowing down the surface of the heat transfer plate 24 and contact with dehumidification water flowing down between the heat transfer plates 24. Thus, the moisture in the air is condensed and dehumidified.
The dehumidified hot water and condensed hot water ejected from the ejection nozzle 25 flow into the cleaning space Q of the cleaning tank D through the air suction port 22 and are stored in the water storage recess S.

  Then, with the electric heater 9 heated, the circulation fan 23 is ventilated and the ejection nozzle 25 is ejected with dehumidifying water. After the dehumidification, the drying air is supplied to the cleaning space Q as drying air, and the supplied air is heated by the electric heater 9 to dry the cleaning object in the cleaning space Q. It is configured to do so.

  In addition, with the electric heater 9 stopped, the circulation fan 23 is ventilated and the ejection nozzle 25 is ejected with dehumidifying water to dehumidify odor components in the air sucked from the cleaning space Q. After being absorbed in dehumidification water by the part G, the deodorizing operation for deodorizing the cleaning space Q can be performed by supplying it to the cleaning space Q.

The air flow in the drying operation will be described. As shown in FIG. 6, the air supplied to the cleaning space Q from the air supply port 21 formed in the front side wall portion Df of the cleaning tank D rises as a main flow. While flowing toward the rear side wall, and then moving downward toward the air suction port 22 formed on the lower side of the front side wall Df and at a position separated from the air supply port 21 in the left-right direction. It flows and flows in a form discharged from the air suction port 22, and air easily flows also to a lower portion of the cleaning tank where the air suction port 22 is located.
Therefore, it is possible to shorten the drying time by allowing air to flow through the entire cleaning object in the cleaning tank and drying the cleaning object efficiently.

  As shown in FIG. 5, the drawer 2 is equipped with a control unit H as a control means for controlling the operation, and the control unit H is based on a command input from the operation unit SS. The operation of the electric heater 9, the circulation fan 23, and the hot water intermittent means E is controlled to clean the object to be cleaned in the cleaning space Q formed in the cleaning tank D with hot water as a cleaning liquid. A cleaning operation as a cleaning process, a rinsing operation as a rinsing process for rinsing an object to be cleaned with rinsing water stored in the water storage recess S of the cleaning tank D and heated by an electric heater 9, and cleaning The drainage operation as a drainage treatment for draining the rinse water stored in the water storage recess S of the tank D, the ventilation operation of the circulation fan 23 and the dehumidification of the ejection nozzle 25 in a state where the electric heater 9 is heated. Water jet operation Deodorizing process as a deodorizing process for causing the circulation operation of the circulation fan 23 and the ejection operation of the dehumidifying water of the ejection nozzle 25 in a state where the electric heater 9 is stopped while the drying operation is performed as a drying process. It is configured to drive.

  In addition, when an interruption command is issued during the execution of the drying operation, the control unit H executes a drying interruption process that interrupts the execution of the drying operation, and then resumes the drying operation when the restart command is issued. In order to stop the ventilation operation of the circulation fan 23 and the heating operation of the heater 9 and to continue supplying hot water for dehumidification to the dehumidifying part G as a drying interruption process, the circulation fan 23, The heater 9 and the hot and cold intermittent means E are configured to be controlled.

  Furthermore, the control unit H is equipped in the operation unit SS to notify that the drying operation is being interrupted when the elapsed time since the execution of the drying interruption process reaches the notification time (for example, 2 minutes). It is comprised so that the dry interruption notification process which operates the speaker L as the alerting | reporting means performed may be performed.

  In addition, when the elapsed time after executing the drying interruption process reaches a stop time (for example, 5 minutes) that is set longer than the notification time, the control unit H The hot and cold intermittent means E is controlled so as to stop the supply of hot water for dehumidification.

Next, a description will be given of the operation performed by the control unit H. The user can operate the operation unit SS in the order of the cleaning operation, the rinsing operation, the drainage operation, the drying operation, and the deodorizing operation in this order, or only the drying operation. Although it is configured so that various driving courses such as a dry-only course to be operated can be selected, and a standard driving course, a careful driving course, a speedy driving course, and a fast driving course can be selected as a continuous driving course. In this embodiment, only the standard operation course of the continuous operation course will be described.

Based on the flowcharts of FIGS. 9 and 10, the control operation of the control unit H will be described.
First, it is detected by a storage switch (not shown) that the drawer 2 is stored in the storage position of the main body 1 (# 1). Is selected (# 3). In the present embodiment, the description will be continued assuming that the standard driving course is selected.
When the start switch of the operation unit SS is turned ON (# 4), the standard operation course is started, and the cleaning operation (# 5), the rinsing operation (# 10), the drain operation (# 15), and the drying operation (#) 16) The deodorizing operation (# 24) is sequentially executed.

  In the washing operation, first, the first on-off valve V1 and the second on-off valve V2 are opened, and hot water is supplied into the washing space Q from the water supply port 5 through the water supply passage 4A and the washing tank branch passage 4B. Then, hot water is supplied to the dehumidifying part G through the dehumidifying branch 4C, and hot water is supplied into the cleaning space Q through the dehumidifying part G or the air suction port 22. When the water level sensor J detects that the water level in the cleaning space Q has reached the cleaning water level, the first on-off valve V1 and the second on-off valve V2 are closed to stop the supply of hot water to the cleaning space Q. To do.

Thereafter, the dual-purpose pump 6 is rotated forward and the heater 9 is operated, and the cleaning operation for spraying the cleaning water from the cleaning nozzle 8 toward the object to be cleaned is performed until the set time for the cleaning operation elapses. In addition, the combined use pump 6 is operated in reverse to drain the washing water in the washing tank D until the water level sensor J detects that the hot water discharge water level is reached.
In addition, before the user turns on the start switch of the operation unit SS, the cleaning detergent can be put into the cleaning tank D to perform cleaning using the detergent.

Then, after the cleaning operation (# 5) is started, it is determined whether or not the cleaning operation has ended after the set time for the cleaning operation has passed (# 6). 10).
When it is determined in # 6 that the cleaning is not finished, it is determined whether or not an interruption command is instructed in the operation unit SS (# 7), and when the interruption command is instructed, the dual-purpose pump 6 is stopped. An interruption process for interrupting the cleaning operation is performed (# 8).

Thereafter, the cleaning operation is interrupted until a restart command is issued by the operation unit SS (# 9). When the cleaning command is interrupted while the cleaning operation is interrupted (# 9), The cleaning operation will be resumed.
Since the cleaning operation can be interrupted in this way, when it is desired to add a cleaning object, the cleaning object can be stored in the cleaning space Q.

In the rinsing operation, hot water is supplied to the cleaning space Q and the supply of hot water is stopped when the water level sensor J detects the cleaning water level, as in the above-described cleaning operation.
Thereafter, the dual-purpose pump 6 and the heater 9 are operated, and the rinsing operation for rinsing the object to be cleaned with the rinse water heated by the heater 9 until the set time elapses, and the dual-purpose pump 6 is operated in reverse. Thus, the rinsing operation for sequentially draining the rinsing water stored at the bottom of the cleaning tank D until the above-described hot water discharge water level is reached is performed twice, and finally the heating rinsing operation is performed.

In the heating rinse operation, hot water is supplied to the cleaning space Q and the supply of hot water is stopped when the water level sensor J detects the cleaning water level, as in the above-described cleaning operation.
Thereafter, the dual-purpose pump 6 and the heater 9 are operated, and the object to be cleaned is rinsed with the rinse water heated by the heater 9, and the temperature of the rinse water is set by the temperature sensor (not shown). When the set temperature for finishing (for example, 67 ° C.) is reached, the heating rinsing operation is terminated.

Then, after the rinsing operation (# 10) is started, it is determined whether or not the rinsing operation is completed after all the steps of the rinsing operation are completed (# 11). 15).
If it is determined in # 11 that the rinsing has not been completed, it is determined whether or not an interruption command has been instructed by the operation unit SS (# 12). If the interruption command has been instructed, the combined pump 6 and the heater An interruption process for interrupting the rinsing operation such as stopping 9 is performed (# 13).

Thereafter, the rinsing operation is interrupted until a restart command is issued from the operation unit SS (# 14). When the restart command is issued when the rinse operation is interrupted (# 14), the rinsing operation is performed. Will resume.
Since the rinsing operation can be interrupted in this way, when it is desired to add an object to be rinsed, the object to be washed can be stored in the washing space Q.

In the drainage operation, the dual-purpose pump 6 is reversely operated to drain the rinse water stored in the bottom of the cleaning space Q of the cleaning tank D until the hot water discharge water level is detected by the water level sensor J. become.
In addition, when the hot water discharge water level is not detected by the water level sensor J after the set time elapses after the reverse operation of the dual-purpose pump 6 is started in the drainage operation, the control unit H performs the drainage operation. An error is reported when it is not properly performed.

  In the drying operation, while the electric heater 9 is heated, the circulation fan 23 is ventilated and the ejection nozzle 25 is ejected with dehumidifying water. , 25 minutes). And if the set time for drying passes, the drain operation which drains the dehumidification water stored by the bottom part of the washing tank D will be performed.

Then, after the drying operation (# 16) is started, it is determined whether or not the drying has been completed after the set time for drying has elapsed (# 17). 24).
If it is determined in # 17 that the drying has not been completed, it is determined whether or not an interruption command is instructed in the operation unit SS (# 18). If the interruption command is instructed, the heating operation of the heater 9 is performed. Then, a drying interruption process that stops the ventilation operation of the circulation fan 23 and interrupts the drying operation is performed (# 19).
In the drying interruption process, the supply of dehumidifying hot water to the dehumidifying unit is continued, that is, the spraying operation of the spray nozzle 25 is continued without stopping the spraying operation of the spray nozzle 25, thereby performing the drying process. When restarted, the dehumidification process can be started properly.

After the drying interruption process is performed in # 19, it is determined whether or not the elapsed time since the drying interruption process has reached a notification time (for example, 2 minutes) (# 20). When the service time is reached, the drying interruption notification process (# 21) is executed to notify the user that the drying process is being interrupted.
In this drying interruption notification process, a notification sound is generated using the speaker L equipped in the operation unit SS as a notification means. Instead of the notification sound, it is also possible to output a sound such as “It has passed XX minutes since the drying process was interrupted” from the speaker L.

  In # 20, when it is determined that the notification time has not been reached, and after the drying interruption notification process is executed, the elapsed time after the execution of the drying interruption process is longer than the notification time. It is determined whether or not the stop time (for example, 5 minutes) set in step S3 is reached (# 22). When the stop time is reached, the supply of dehumidified hot water to the dehumidifier G is stopped. It is configured as follows.

If it is determined at # 22 that the stop time has not been reached, then it is determined whether or not a restart command has been issued at the operation unit SS (# 23), and it is determined that a restart command has been issued. Sometimes, the drying operation is restarted, and when it is determined that the restart command is not issued, the drying interruption process is continued.
Since the drying operation can be interrupted in this way, when it is desired to add a cleaning object to be dried, the cleaning object can be stored in the cleaning space Q.

  In addition, as a case where the drying interruption process for interrupting the drying operation is executed, in addition to the case where the interruption command is instructed by the operation unit SS as described above, the drawer unit 2 is drawn during the execution of the drying operation. There is. In this case, when the open state is detected by an open / close detection unit (not shown) that detects whether the drawer unit 2 is in the opened state in which the drawer unit 2 is pulled out or in the closed state in which the drawer unit 2 is housed, the drying interruption process is performed. Is executed, and the drying operation is resumed when the open / close detection unit detects the closed state.

  In the deodorizing operation, with the electric heater 9 stopped, the circulation fan 23 is ventilated and the ejection nozzle 25 is ejected with dehumidifying water. Repeat until it has passed. When the set time for deodorization elapses, the drainage operation for draining the deodorized water stored in the bottom of the cleaning tank D is performed until the water level sensor J detects the hot water discharge water level.

  Although not illustrated in the flowchart of FIG. 9, the control unit H is more than the hot water supply amount per unit time supplied to the cleaning space Q through the water supply channel 4A, the cleaning tank branch channel 4B, and the dehumidification branch channel 4C. The dual-purpose pump 6 is configured to operate in a state where the amount of drainage per unit time is increased, and the first on-off valve V1 and the second on-off valve V2 are opened in the cleaning operation and the rinsing operation. When hot water is being supplied to the cleaning space Q of the cleaning tank D and an abnormal water level is detected by the water level sensor J, the first on-off valve V1 and the second on-off valve V2 are closed, and the dual-purpose pump It is comprised so that the water leakage prevention driving | operation process which operates 6 for drainage may be performed.

In addition, when the water level sensor J detects that the water level is lower than the above-described cleaning water level while executing the water leakage prevention operation process, the control unit H stops the dual-purpose pump 6 and performs the water leakage prevention operation. It is configured to stop processing.
Incidentally, the time when the water level sensor J detects that the water level is lower than the cleaning water level is when the water level sensor J changes from a state where the water level sensor J detects the cleaning water level to a state where the water level is not detected.

As shown in FIGS. 4 and 5, there is provided pressure adjusting means W for automatically adjusting the internal pressure of the cleaning space Q in the closed state to be the external pressure of the machine.
That is, for example, in the final rinsing process in the rinsing process, that is, in the middle of performing the high temperature rinsing by operating the electric heater 9, an operation for additionally storing the object to be cleaned or one of the objects to be cleaned being cleaned. When the cleaning space Q is opened after the operation is temporarily stopped, the cleaning space Q is opened and the necessary work is performed after starting the operation for performing the high temperature rinsing again. A large amount of air that has entered the cleaning space Q is heated by high-temperature rinsing and rapidly expands, and the internal pressure of the cleaning space Q tends to increase greatly. By the action of W, the internal pressure of the cleaning space Q is automatically adjusted so as to become the external pressure.

  In the cleaning process, when the electric heater 9 is heated, the temperature in the cleaning space Q is considerably high (for example, 67 ° C.). Thereafter, the washing water is discharged, and the rinsing water is supplied to the washing space Q for the rinsing process, and the rinsing water is ejected from the washing nozzle 8 by the operation of the combined pump 6. The temperature is low (for example, 13 to 17 ° C.). For this reason, when low-temperature rinse water is ejected from the cleaning nozzle 8, the temperature in the cleaning space Q rapidly decreases. As a result, a large amount of air in the cleaning space Q contracts rapidly, and the cleaning space Q In some cases, the internal pressure of Q tends to decrease greatly. In such a case, the internal pressure of the cleaning space Q is automatically adjusted to the external pressure by the action of the pressure adjusting means W.

The pressure adjusting means W is configured to adjust the pressure in the cleaning space Q by communicating with the cleaning space Q in the cleaning tank D through the communication hole 32 formed in the back wall DR of the cleaning tank D. However, in the present embodiment, description of the detailed configuration is omitted.
Note that condensed water may be generated in the pressure adjusting means W, and the condensed water is collected in the cleaning tank D via the water level sensor J.

Hereinafter, the water level sensor J will be described.
As shown in FIGS. 11 to 13, a hot water storage tank 40 for detecting a water level connected to the bottom of the cleaning tank D by a guide tube 13 and into which hot water in the cleaning tank D is introduced, and a hot water storage tank 40. A float 41 for detecting the water level that moves up and down according to the level of the hot water stored in the hot water storage tank 40 and a shaft portion 41B that extends upward from the main body 41A of the float 41 are guided so as to be raised and lowered. And a pair of a first water level detection unit T1 and a second detection unit T2 that are positioned above the upper end of the hot water storage tank 40 and that detect two up and down positions of the float 41 are provided. It has been.

  The hot water storage tank 40 is formed in a bottomed cylindrical shape having a quadrangular cross-sectional shape, and a connecting cylinder portion 40C is provided at the bottom as a communication port to which the above-described guide tube 13 is connected. The upper opening is covered with a lid body 42 that is formed and is fitted on the upper portion thereof.

Incidentally, the upper end portion of the hot water storage tank 40 is provided with a washing water receiving portion 40A and a dew condensation water receiving portion 40B for receiving dew condensation water from the pressure adjusting means W in a protruding state outward, and a lid 42 is provided. In addition, the opening for connecting with the pressure adjusting means W is formed in the cover 42 so as to cover the storage portion 40A and the condensed water receiving portion 40B for receiving the washing water, and covering the condensed water receiving portion 40B in the lid body 42. Vk is formed.
The function of the washing water receiving unit 40A will be described later.

  The two upper and lower lift positions of the float 40 are the above-described lift position for detecting the cleaning water level (see FIG. 15) and the lift position for detecting the above-described hot water discharge water level (see FIG. 14). The first water level detection unit T1 detects that the float 41 is located at the elevation position for detecting the higher water level for washing, and the second water level detection unit T2 is located at the elevation position for detecting the lower-side hot water discharge water level. It is configured to detect that the float 41 is located.

  The first water level detection unit T1 and the second detection unit T2 are configured using a photo-interrupter type optical sensor, and the first water level detection unit T1 is provided on the first sensor mounting unit 42a protruding from the upper part of the lid body 42. The second water level detection unit T2 is mounted on the second sensor mounting portion 42b that protrudes from the top of the lid body 42.

Further, the above-described abnormal water level detecting electrode 43 for detecting the abnormal water level is located on the lid body 42 such that the upper end side is positioned above the lid body 42 and the lower end side protrudes into the hot water storage tank 40. Is provided.
That is, as shown in FIG. 16, the abnormal water level detection electrode 43 has a second water level detection unit T1 on the high water level side of the first water level detection unit T1 and the second detection unit T2. When the set amount is higher than the water level detected at, the lid body 42 is equipped in a conductive state where it is conducted by hot water stored in the hot water storage tank 40.

As shown in FIGS. 11 and 14, the shaft portion 41 </ b> B of the float 41 is in a state where the float 41 is located at a lower / lower position on the low water level side among a plurality of elevating positions, that is, for detecting a hot water discharge water level. In the state located in the raising / lowering position, it forms in the length which positions the upper end part below the upper end of the hot water storage tank 40. As shown in FIG.
In addition, the guide unit U is configured to guide the shaft 40B of the float 40 positioned below the upper end of the hot water storage tank 40 so as to be positioned below the upper end of the hot water storage tank 40. Yes.

And the rocking lever 44 provided with the to-be-detected part 44a detected by the 2nd detection part T2 of the low water level side among the 1st water level detection part T1 and the 2nd detection part T2 is the shaft part 41B of the float 41. It is provided in a state where it is linked to the upper end of the upper and lower parts and swings up and down.
In other words, the swing lever 44 is pivotally supported by the second sensor mounting portion 42b so as to swing up and down around the horizontal axis X, and one end side portion of the horizontal axis X is the above-described detected portion. The other end side portion of the horizontal axis X is formed in the linkage portion 44b with the shaft portion 41B.
The linkage portion 44b is formed in a bifurcated shape, and is configured such that the upper end of the shaft portion 41B is engaged with the linkage portion 44b.

That is, as shown in FIG. 17, a pair of left and right flag bodies 41a project from the upper end portion of the shaft portion 41B and below the upper end, and the upper end of the shaft portion 41B is prevented from coming off. The projecting portion 41b is formed so as to protrude in the same direction as the pair of left and right flag bodies 41a.
Then, the bifurcated linkage portion 44b of the swing lever 44 is inserted between the protrusion 41b for preventing the detachment and the pair of left and right flag bodies 41a, and the upper end of the shaft portion 41 is a bifurcated linkage portion. 44b is configured to penetrate through 44b.

As shown in FIG. 15, the shaft 41B of the float 41 has its upper end in a state where the float 41 is located at the elevated position on the high water level side among the plurality of elevated positions, that is, in the state where the cleaning water level is detected. It is formed in such a length that the portion is positioned above the upper end of the hot water storage tank 40.
Then, one of the pair of flag bodies 41a described above is configured to function as a detected portion detected by the first detection portion T1.

The guide portion U is configured as a guide groove U1 that engages one of a pair of flag-like bodies 41a provided at the upper end portion of the shaft portion 41B over the entire lifting / lowering range of the float 41. That is, one of the pair of flag bodies 41a is configured to function as a guided piece engaged with the guide groove U1.
Incidentally, the guide unit U is also configured to include an auxiliary guide groove U2 that engages the flag-like body 41a that functions with the detected part detected by the first detection unit T1 of the pair of flag-like bodies 41a. However, although this auxiliary guide groove U2 exists up to the vicinity of the first detection unit T1, it does not exist at a place where the flag-like body 41a that functions as the detected unit is detected by the first detection unit T1. Therefore, the float 41 is not guided over the entire lifting / lowering range of the float 41.

  When the guide portion U is described further, the cover 42 that covers the upper opening of the hot water storage tank 40 is a downward concave that protrudes downward from the upper end of the water storage tank in a state where the lid 41 is positioned lower as the shaft 41B is inserted. 42A and an upper protruding portion 42B for forming a guide groove are formed, and the guide groove U1 is formed in a state extending over the recessed portion 42A and the upper protruding portion 42B of the lid body. Yes.

  Further, the lid body 42 is formed in a state having an upper protruding portion 42C for forming the auxiliary guide groove for forming the auxiliary guide groove U2, and the auxiliary guide groove U2 is formed in the recessed portion 42A and the lid in the lid body 42. It is formed in a state extending over the upper projecting portion 42C of the body 42.

When the above-described washing water receiving unit 40A is described, as shown in FIG. 5, when performing drainage operation, a part of hot water flowing through the drain pipe 12 passes through the branch pipe 12a to the water level sensor J side. The branch pipe 12 is configured to branch and flow, and is connected to a pipe connection portion 40a provided in the washing water receiving portion 40A.
Accordingly, when a drainage operation is performed, a part of hot water drained by the dual-purpose pump 6 flows into the washing water receiving portion 40A and then discharged into the hot water storage tank 40, whereby the hot water storage tank 40 The wall surface can be cleaned.

[Another embodiment]
Next, another embodiment will be described .

(B) In the above embodiment, the cleaning tank has been illustrated drawer and accommodating freely provided are drawer type dishwasher along the horizontal direction with respect to the main body case portion, the cleaning tank is housed in the body case portion The present invention can also be applied to a dishwasher in which the washing space of the washing tub is opened and closed by opening and closing the front door of the main body case.

( B ) In the above-described embodiment, the dehumidifying unit includes the ejection means for ejecting hot water for dehumidification downward with respect to the air passing through the ascending path part in the ventilation path, and the ascending path part is directed upward. The case where the air to be ventilated is cooled by contact with dehumidified hot water jetted downward by the jetting means to condense moisture in the air and dehumidify is exemplified. The configuration of the part can be variously changed.
For example, by installing a heat exchanger with heat exchange fins in the ventilation path and flowing hot water for dehumidification through the heat exchanger, the air flowing through the ventilation path is cooled by contact with the heat exchanger. The moisture in the air may be condensed and dehumidified.

( C ) In the above embodiment, when the elapsed time since the execution of the drying interruption process reaches the notification time, the drying interruption notification process for operating the notification means to notify that the drying process is being interrupted. However, it is configured to execute the drying interruption notification process at every notification set time interval based on the time when the elapsed time from the execution of the drying interruption process reaches the notification time. May be. If comprised in this way, it will become possible to notify a user more reliably that the drying process is being interrupted. In this case, the notification setting time is set to be less than ½ of the stop time.

( D ) In practicing the present invention, various forms of water level detection means can be applied instead of the water level detection sensor described in the above embodiment.

4A Water supply path 4B Cleaning tank branch path 4C Dehumidification branch path 5 Water supply port 6 Combined pump 9 Heating means 21 Air supply port 22 Air suction port 23 Ventilation means 25 Ejection means D Cleaning tank E Hot water intermittent means F Ventilation path f1 Ascending path Part f2 Lowering path part G Dehumidifying part H Control means J Water level detection sensor Q Cleaning space K Drying unit R1 Flexible hose R2 Flexible hose V1 First on-off valve V2 Second on-off valve V3 Constant flow valve V4 Constant flow valve

Claims (4)

A water supply port for supplying hot and cold water for cleaning and rinsing in an openable and closable cleaning space;
By cooling the air in the cleaning space circulated by the ventilation means through the ventilation path extending from the air suction port to the cleaning space and the air supply port to the cleaning space by contact with hot water for dehumidification, A dehumidifying part that dehumidifies by condensing moisture in the air;
Heating means for heating the air in the cleaning space;
Hot water intermittent means for intermittently supplying hot water to the water supply port and intermittently supplying hot water to the dehumidifying section;
A cleaning unit that cleans an object to be cleaned in the cleaning space, a rinsing process for rinsing the object to be cleaned, and a control unit that executes a drying process for drying the object to be cleaned;
The control means is
In the cleaning process and the rinsing process, the hot water intermittent means is controlled so as to perform cleaning and rinsing by supplying hot water from the water supply port into the cleaning tank, and
In the drying process, the ventilation unit, the heating unit, and the heating unit are configured to contact the hot water for dehumidification and the air passing through the ventilation path while heating the air in the cleaning space by the heating unit. A dishwasher configured to control the hot water intermittent means,
The control means is
When an interruption command is instructed during the execution of the drying process, the drying interruption process for interrupting the execution of the drying process is executed, and then when the restart instruction is instructed, the drying process is resumed. And as said drying interruption processing, in order to stop the ventilation operation of said ventilation means and the heating operation of said heating means, and to continue supply of hot water for said dehumidification to said dehumidification part, said ventilation means, said heating And a means for controlling the hot water intermittent means ,
The hot water interrupting means is branched from a first on-off valve for opening and closing a water supply path connected to a water supply source, a washing tank branch path branched from the water supply path and connected to the water supply port, and the water supply path. Of the dehumidifying branch connected to the dehumidifying section, a second on-off valve that opens and closes the cleaning tank branch, and the first on-off valve and the second open / close equipped on the dehumidifying branch. A constant flow valve that restricts the flow rate of hot water flowing through the dehumidifying branch path to be less than the flow rate of hot water flowing through the washing tank branch path when the valve is open;
When the control means supplies hot water in the cleaning process and the rinsing process, the first on-off valve and the second on-off valve are opened, and when hot water is supplied in the drying process, the first on-off valve And is configured to close the second on-off valve,
The second on-off valve can be switched between a valve housing, a valve seat provided in the valve housing, a closed state in contact with the valve seat, and an open state separated from the valve seat The valve body is formed in the valve body so as to communicate the back side pressure chamber of the valve body into which the fluid in the upstream flow passage portion from the valve seat flows and the downstream flow passage portion from the valve seat. A valve operating body for opening and closing the through hole,
When the valve operating body operates the through hole in a closed state, fluid in a flow path portion upstream from the valve seat flows into the back-side pressure chamber of the valve body to bring the valve body into the closed state. When the valve operating body is operated and the through-hole is opened, the fluid in the flow path portion upstream of the valve seat operates the valve body in the open state. Dishwasher. When the elapsed time from the execution of the drying interruption process reaches the notification time, the control means executes a drying interruption notification process for operating the notification means to notify that the drying process is being interrupted. A dishwasher according to claim 1, wherein the dishwasher is configured to do so . When the control means has reached a stop time set to a time longer than the notification time after the drying interruption process has been performed, the dehumidifying hot water to the dehumidifying part The dishwasher according to claim 2, wherein the dishwasher is configured to control the hot water intermittent means to stop the supply . The air suction port and the air supply port are formed at lower positions in the side wall portion of the cleaning space,
The ventilation path is configured in an inverted U shape including an upward path portion extending upward from the air suction port and a downward path portion extending downward from the upper end portion of the upward path portion toward the air supply port. ,
The dehumidifying part is
Ejecting means for ejecting dehumidified hot water downward with respect to the air passing through the ascending path portion in the ventilation path, and air venting the ascending path portion upward by the ejecting means. It is configured to condense and dehumidify moisture in the air by cooling with contact with hot water for dehumidification ejected downward, and the hot water after dehumidification is washed through the air suction port. The dishwasher of any one of Claims 1-3 comprised so that it may flow in a tank .

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