KR100635718B1 - Dishwasher - Google Patents

Abstract

(Problem) By providing a simple device configuration, the sealing of the washing tank is monitored, and when the sealing is not maintained, the operation is stopped to provide a technique for preventing leakage.

(Solution means) The dish washing machine according to the present invention is provided with an opening, and includes a washing tank for holding dishes to be washed, a lid for blocking the opening of the washing tank, a means for transforming the pressure inside the washing tank, and a pressure fluctuation inside the washing tank. Means for detecting and means for determining the sealability of the opening portion based on the detected pressure variation inside the washing tank, characterized in that the operating state is changed when it is determined that the opening portion is not sealed.

Description

Dishwasher {DISHWASHER}

1 is a view showing the configuration of a dishwasher 10 having a pressure sensor 7 (first and second embodiments).

2 is a graph showing the pressure distribution of the washing water circulating in the washing tank (4)

3 is a graph showing the time change of the pressure inside the washing tank (4)

4 is a flowchart showing the operation of the dishwasher 10 (first embodiment).

5 is a flowchart showing the operation of the dishwasher 10 (second embodiment).

6 is a view showing the configuration of the dishwasher 100 provided with the displacement meter 9 (third embodiment).

7 is a graph showing the time change of the displacement of the upper cover 6

8 is a flowchart showing the operation of the dishwasher 100 (third embodiment)

Explanation of symbols on the main parts of the drawings

4-cleaning bath 6-top cover

7-Pressure sensor 8-Injection nozzle

9-displacement meter 10-dishwasher

12-seal 14-outer case

16-water inlet 20-solenoid valve

22-Drainage 24-Drainage

26-Drainage Trap 28-Cleaning Pump

30-flush water circuit 32-lowest water level switch

34-Drainage 36-Drainage pump

38-Water Level Switch 40-Door

42-Air port 44-Valve

45-Controller 46-Thermistor

48-Drying Fan 51-First Air Path

52-Heater 54-Dish basket

55-Second air passage 62-Atmospheric pressure

64-Pressure 70-Pressure

76-point 78-pressure

82-Pressure before starting operation 84-Pressure at starting operation

86-atmospheric pressure 88-pressure

90-Pressure 92-Pressure history

94-Pressure History 100-Dishwasher

102-Displacement before start of operation 104-Displacement before start of operation

108-Displacement 110-Displacement

112-Displacement History 114-Displacement History

The present invention relates to a dishwasher.

The dishwasher is provided with a washing tank for storing dishes and the like in the dish washing machine. In the washing tank, washing of dishes and the like is performed using washing water. At this time, when the washing water leaks from the washing tank, it adversely affects the electrical system provided in the dishwasher, or mold is generated due to the attachment of the washing ingredients contained in the washing water. Therefore, in order to prevent the wash water from leaking in the washing tank, the dish washing machine is provided with a cover for closing the washing tank together with the washing tank.

If the cover is not occluded enough, the seal of the wash tank cannot be maintained and the wash water leaks out of the wash bath. In order to prevent the leakage as described above, various techniques have been proposed in the past. These technologies can be classified into a technique for securing the performance of blocking the lid and the washing tank, and detecting the opening and closing state of the lid based on the positional relationship between the lid and the washing tub, and operating the dishwasher when the lid is opened. It is classified as a stationary technique.

As a technique of ensuring a practical performance, the technique of patent document 1 is mentioned, for example. Patent Literature 1 discloses a technique in which a seal between a lid and a washing tank is hollow packing, air is inserted into the hollow packing to swell, and the sealing pressure of the washing tank is maintained by the pressure.

As a technique of detecting the opening / closing state of a cover and stopping operation of a dishwasher when a cover is open, the technique of patent document 2 and the technique of patent document 3 are mentioned, for example.

Patent Literature 2 uses a magnet attached to a cover and a reed switch installed so as to face the magnet in a state where the washing tank is stored in the main body. A technique for stopping the operation of the dishwasher is disclosed.

Patent Document 3, in a state in which the washing tank is stored in the main body, forms a holding mechanism for holding the washing tank in the storage position, detects the position of the washing tank from the position of the movable cam of the holding mechanism, and the washing tank is not in the normal holding position. The technique which judges that a washing tank is not sealed by the cover and stops operation of a dish washing machine is disclosed.

[Patent Document 1] Japanese Unexamined Patent Publication No. 2003-180603

[Patent Document 2] Japanese Unexamined Patent Publication No. 2000-139798

[Patent Document 3] Japanese Unexamined Patent Publication No. 2002-17642

The sealing property of the washing tank is in a positional relationship in which the lid closes the opening of the washing tank, and the seal between the lid and the washing tank can be maintained by sufficient function. Even if the positional relationship between the cover and the cleaning tank is maintained correctly, leakage occurs when the seal does not function. On the contrary, even if the seal is functioning sufficiently, leakage occurs when the cover is removed from the washing tank.

In the technique of Patent Literature 1, since the positional relationship between the lid and the washing tank cannot be monitored, leakage occurs when the lid is operated away from the washing tank. In the techniques of Patent Literature 2 and Patent Literature 3, the positional relationship between the lid and the washing tank can be monitored, but leakage can be prevented when the seal does not function sufficiently, such as when the seal is deteriorated by using the dishwasher for a long time. Can't.

If the above technique is used in combination, water leakage can be reliably prevented, but the structure of the apparatus becomes complicated, and the apparatus becomes large and the weight becomes heavy.

A simpler device configuration requires a technique capable of preventing a leak in the washing tank even when the cover is separated from the washing tank or the seal does not function sufficiently.

In order to solve the above problems, the present invention provides a technique of preventing leakage by monitoring the sealing property of a washing tank by a simple device configuration, and by not changing the operating state and performing a washing operation when the sealing property is not maintained. do.

The dishwasher according to the present invention has an opening, and includes a washing tank accommodating the dishes to be washed, a lid for blocking the opening of the washing tank, a means for changing the pressure inside the washing tank, a means for detecting a pressure change in the washing tank; And means for determining the sealability of the opening portion based on the pressure variation inside the washing tank to be detected, and changing the operation state when it is determined that the opening portion is not sealed.

When the inside of the washing tank is transformed (pressurized or depressurized), the pressure inside the washing tank varies depending on the sealability of the washing tank. For example, when the cover completely closes the opening when the inside of the washing tank is depressurized, since the air hardly flows into the inside of the washing tank, the pressure inside the washing tank is greatly reduced. On the contrary, when the cover does not completely close the opening, air flows in between the cover and the washing tank with decompression, thereby reducing the pressure reduction inside the washing tank and not reducing the pressure inside the washing tank. Similarly, when the inside of the washing tank is pressurized, the degree of increase in pressure inside the washing tank changes depending on the sealing property of the opening. Therefore, the sealing property of the opening part can be known from the pressure fluctuation inside the washing tank.

As mentioned above, when the sealing property of an opening part is not ensured, the pressure fluctuation inside a washing tank is alleviated. Therefore, by closing the pressure inside the washing tank by detecting the pressure change inside the washing tank, and comparing the absolute value of the pressure change with a certain threshold value, it is possible to determine the sealability of the opening. If the absolute value of the pressure fluctuation exceeds the threshold, it is judged that the sealing property of the opening is secured, and normal operation is performed. If the absolute value of the pressure fluctuation does not exceed the threshold, the seal of the washing tank is not secured. By judging that it is not, the operation can be stopped to prevent leakage due to the cover being opened or the seal not functioning sufficiently.

As described above, the monitoring of the airtightness may be performed at that time if there is a process of transforming the pressure inside the washing tank during the process for washing the dishes, or the process for checking the airtightness may be performed separately. In the case where the process for checking the sealing property is separately performed, it is preferable to carry out the process at the stage before washing the dishes. If it is known that the sealing property is not secured before washing the dishes, the operation can be stopped completely before the water is actually leaked, thereby preventing the leak completely.

Preferably, the means for transforming the pressure inside the washing tank is a means for sucking water in the washing tank.

In general dishwashers, a means (for example, a pump) for sucking water in the washing tank is provided to circulate the washing water inside the washing tank or to discharge the used washing water. The present inventors have found that in the state where the opening of the washing tank is sealed with a cover, when water is sucked from the inside of the washing tank by using the above means, almost no air flows into the washing tank and the pressure inside the washing tank is reduced.

By using together the means which sucks water in the said washing tank as a means for transforming the pressure in the said washing tank, the structure of a dish washing machine can be made simpler.

The means for detecting the pressure fluctuation may use various techniques. For example, a pressure sensor for measuring the pressure inside the washing tank can be used to detect pressure fluctuations inside the washing tank. Since the pressure sensor can measure the pressure inside the washing tank in the state where the opening is closed by the lid, for example, the pressure sensor may be installed inside the lid or inside the washing tub.

Or the pressure fluctuation inside a washing tank can be detected using the displacement meter which measures the deformation amount of the cover of the direction perpendicular | vertical to the surface of a cover.

When the pressure inside the wash basin fluctuates, the cover floats in a direction perpendicular to the surface due to the pressure difference in and out of the wash basin. For example, when the pressure inside the washing tank is reduced, the lid is bent inward, and when the pressure inside the washing tank is increased, the lid is bent outward. The amount of warpage of the cover depends on the pressure difference, and the larger the pressure difference, the greater the amount of warpage of the cover. Therefore, by measuring the deformation amount of the cover in the direction perpendicular to the face of the cover, it is possible to detect the pressure variation inside the washing tank.

(The best form to carry out invention)

Hereinafter, an embodiment embodying the present invention will be described with reference to the drawings. First, the main features of the embodiment are listed.

(Form 1): The means for judging the sealing property of the opening part of a washing tank is

By comparing the absolute value of the pressure variation inside the washing tank detected with the threshold,

When the absolute value of the pressure fluctuation does not exceed the threshold, it is characterized in that it is determined that the opening of the washing tank is not sealed.

(Form 2): When it is judged that an opening part is not sealed, it is characterized by notifying an abnormality to a user, and stopping operation.

EXAMPLE

EMBODIMENT OF THE INVENTION Below, the dishwasher of this invention is demonstrated in detail, referring an accompanying drawing.

(First embodiment)

1, the cross section of the dishwasher 10 of a present Example is shown typically. A washing tank 4 is formed inside the outer case 14 of the dishwasher 10, and the dishes placed in the dish basket 54 are washed and dried. The washing tank 4 has a box shape with an upper opening, and a door 40 is formed on the front surface. The washing tank 4 may be withdrawn from the outer case 14 to withdraw dishes from the upper opening.

Inside the outer case 14, an upper lid 6 is formed to close the opening of the upper portion of the washing tank 4. The upper cover 6 is restricted in the moving range by the guide (not shown), and when the washing tank 4 is pulled out of the outer case 14, the upper lid 6 is obliquely upward upward with respect to the washing tank 4 ( Toward the upper left of FIG. 1, and stops inside the outer case 14. When the washing tank 4 is press-fitted into the outer case 14, the upper lid 6 moves obliquely downward to the washing tank 4 (downward to the right of FIG. 1), so that the washing tank 4 is moved around the opening of the washing tank 4 It comes in contact with the support surface through the seal 12 and closes the opening part of the washing tank 4. At the center of the lower surface of the upper lid 6, a pressure sensor 7 (corresponding to a means for detecting pressure fluctuation) is provided. The pressure sensor 7 measures the pressure inside the washing tank 4 and transmits it to the controller 45 (corresponding to a means for judging the sealing property of the opening).

At the bottom of the washing tank 4, a spray nozzle 8 having a temperature sensor 46, a heater 52, and a plurality of openings is provided.

When the heater 52 is energized, the heater 52 generates heat to heat the washing water stored in the bottom of the washing tank 4. The heating by the heater 52 is controlled by the controller 45, and the temperature of the washing water in the washing tank 4 matches the pre-programmed temperature pattern by feedback control using the temperature measured by the temperature sensor 46. Controlled to. In addition, the heater 52 heats the air transferred to the washing tank 4 by the drying fan 48.

The injection nozzles 8 are rotatably arranged. The injection nozzle 8 is connected to a washing water circulation path 30 which takes in the washing water at a lower position of the washing tank 4. The washing pump 28 is installed in the middle of the washing water circulation path 30, and when the washing pump 28 is operated, the washing water is sprayed from the spray nozzle 8.

The water supply passage 16 is connected to the washing tank 4. The upstream end part of the water supply path 16 is connected to the water supply port 22, and the water heated by the dishwasher 10 is supplied from the water heater outside the apparatus not shown. The solenoid valve 20 is provided downstream of the water supply port 22. The solenoid valve 20 controls the quantity of water supplied to the water supply path 16 by the instruction | indication of the controller 45. As shown in FIG.

The washing tank 4 is provided with a water level switch 38. The water level switch 38 is a float type water level switch and monitors the water level inside the washing tank 4. When the water level in the washing tank 4 reaches the prescribed water level, the water level switch 38 outputs ON to the controller 45. When the water level inside the washing tank 4 does not reach the prescribed water level, the water level switch 38 outputs OFF to the controller 45.

The drainage path 34, the washing water circulation path 30, and the lowest water level switch 32 are connected to the lowest position of the bottom of the washing tank 4. The downstream end of the drain path 34 is connected to the drain port 24, and the drain port 24 is connected to the drain pipe of the kitchen outside the apparatus. The drainage path 34 is provided with a drainage pump 36 (corresponding to a means for transforming the interior of the washing tank 4). When the drainage pump 36 is operated, the water stored in the washing tank 4 is drained. do. In addition, the drainage path 34 has a drain trap 26 and an air remover 50 on the downstream side of the drainage pump 36 further to prevent drainage backflow from the drain pipe of the kitchen to the washing tank 4.

A washing pump 28 is installed in the washing water circulation path 30, and pressurizes the washing water stored at the bottom of the washing tank 4 to spray the spray nozzle 8.

The lowest water level switch 32 is a pressure level switch and monitors the water level inside the washing tank 4. When the water level inside the washing tank 4 reaches the prescribed minimum water level, the lowest water level switch 32 outputs ON to the controller 45. When the water level inside the washing tank 4 does not reach the prescribed minimum water level, the lowest water level switch 32 outputs OFF to the controller 45.

The first air passage 51 is connected to the rear of the washing tank 4. The other end of the first air passage 51 is opened inside the outer case 14 at a position higher than the prescribed level of the washing tank 4, and the drying fan 48 rotates to the first air passage 51. Air is transferred The drying fan 48 rotates by the instruction | indication of the controller 45, and sends air toward the washing tank 4 via the 1st air path 51. FIG. The air transferred in the washing tank 4 is heated by the heater 52, becomes hot air, and dried dishes, and then is discharged from the second air passage 55 to the outside of the washing tank 4.

An end portion of one side of the second air passage 55 is connected to the front of the washing tank 4. The other end of the second air passage 55 is opened out of the device via the air port 42 formed in the door 40. An opening / closing valve 44 is provided in the second air passage 55, and the second air passage 55 is opened and closed in synchronization with the rotation of the drying fan 48. When the drying fan 48 is rotating, the opening / closing valve 44 opens the second air passage 55 to discharge the air sent from the washing tank 4 out of the apparatus. When the drying fan 48 is stopped, the on-off valve 44 closes the second air passage 55 to prevent water or air from leaking from the washing tank 4.

The dishwasher 10 performs a draining step, a washing step, three rinsing steps, a high temperature rinsing step and a drying step to wash and dry the dishes. In the above process except the drying process, water is sucked into the washing tank 4 by driving the drain pump 36 or the washing pump 28. By suction by this pump, the inside of the washing tank 4 is depressurized, and becomes negative pressure with respect to atmospheric pressure.

2 is a graph showing the pressure variation of the washing water circulating in the washing tank 4, the washing water circulation path 30, the washing pump 28, and the injection nozzle 8 in the washing process. In FIG. 2, x ₁ and x ₂ represent inlets and outlets of the washing pump 28, and x ₃ and x ₄ represent inlets and outlets of the injection nozzle 8. The pressure 64 of the washing water in the washing machine 4 is almost equal to the pressure of the air in the washing tank 4, and the pressure 64 is lower than the atmospheric pressure 62. When the washing tank 4 flows into the washing water circulation path 30 and is pressurized by the washing pump 28, the pressure 70 of the washing water increases and becomes higher than the atmospheric pressure 62. When the inside of the washing tank 4 is injected from the plurality of openings of the injection nozzle 8, the pressure 78 of the washing water is lower than the atmospheric pressure 62 again.

FIG. 3 is a graph showing the temporal change of the air pressure inside the washing tank 4 shown at the point 76 in FIG. 2. In FIG. 3, when the operation of the dishwasher 10 is started at a time t ₀ , the drain pump 36 is driven and water stored in the washing tank 4 is drained. When the upper lid 6 of FIG. 1 closes the washing tank 4 securely, and the sealing property of the opening part of the washing tank 4 is ensured, the pressure inside the washing tank 4 is decompressed by the drain pump 36, It descends along the pressure history 92. On the other hand, if the upper lid 6 of FIG. 1 does not close the washing tank 4 securely, and the sealing property of the opening part of the washing tank 4 is not ensured, the pressure inside the washing tank 4 will be applied to the drain pump 36. Pressure is reduced, but since air flows in between the upper cover 6 and the washing tank 4, the pressure reduction by the drain pump 36 is alleviated, and the pressure is lowered along the pressure history 94 higher than the pressure history 92. . The difference in the pressure inside the washing tank 4 is, for example, at a time t ₁ after a predetermined time (30 seconds in this embodiment) has elapsed from the start time t ₀ of the drainage pump 36. This can be obtained by measuring the pressure inside the washing tank 4 and taking a differential pressure with the atmospheric pressure 86. ΔP ₂ of FIG. 3 represents the pressure 88 and the atmospheric pressure 86 at the time t ₁ , which is 30 seconds after driving the drain pump 36 in a state where the sealing of the opening of the washing tank 4 is secured. Indicates the differential pressure. ΔP ₁ is the pressure difference between the pressure 90 and the atmospheric pressure 86 at the time t ₁ 30 seconds after the drain pump 36 is driven in a state where the sealing of the opening of the washing tank 4 is not secured. Indicates. By comparing the absolute value of the above-mentioned differential pressure with a predetermined threshold value, the sealing property of the opening part of the washing tank 4 can be judged.

An operation of the dishwasher 10 will be described with reference to FIG. 4.

When the operation is started in step S2, the drain pump 36 is driven in step S4 to start discharging the water stored in the bottom of the washing tank 4.

In step S6, it is determined whether or not the lowest water level switch 32 is turned off. When the lowest water level switch 32 is ON (NO at step S6), the controller 45 determines that the drainage is not completed and proceeds to step S8. In step S8, it is determined whether the elapsed time since the start of drainage has reached 3 minutes. If 3 minutes have elapsed since the start of drainage (YES in step S8) after the drainage was not completed, the flow proceeds to step SlO, and the user is notified of the abnormality of the drainage and the operation of the dishwasher 10 is stopped. do. If the draining is not completed but 3 minutes have not elapsed since the start of draining, the flow proceeds to Step S4 to continue draining.

When the lowest water level switch 32 is turned OFF (YES in step S6), the flow advances to step S12, and draining is continued until 30 seconds have elapsed after the lowest water level switch 32 outputs OFF (step) NO at S12). If 30 seconds elapse after the lowest water level switch 32 outputs OFF (YES in step S12), the flow proceeds to step S14.

In step S14, the pressure in the washing tank 4 is measured using the pressure sensor 7.

In step S16, the drain pump 36 is stopped to stop the drainage.

In step S18, a differential pressure is calculated from the pressure in the washing tank 4 measured in step S14, and it is judged whether the absolute value of the calculated differential pressure exceeds a threshold. When the absolute value of the differential pressure exceeds the threshold (YES in step S18), the pressure inside the washing tank 4 is reduced to the same level as when normal operation is performed, and the opening of the washing tank 4 is the upper cover 6 ), It is judged to be sealed, and the flow proceeds to step S22. If the absolute value of the differential pressure does not exceed the threshold (NO at step S18), it is determined that the pressure inside the washing tank 4 is not so reduced and that the opening of the washing tank 4 is not sealed, and the process proceeds to step S20. Proceed.

In step S20, the user is notified of the sealing property abnormality of the opening part of the washing tank 4, and operation | movement of the dishwasher 10 is stopped.

In step S22, a washing process is started, and a rinsing process, a high temperature rinsing process, and a drying process are performed after that.

In the above embodiment, the pressure in the washing tank 4 is detected at a time after a predetermined time has elapsed since the drain pump 36 is driven, and the pressure difference between the atmospheric pressure and the pressure is compared with a threshold value, whereby Judging. The method of determining the sealing property of the washing tank 4 is not limited to this, Various methods can be used. For example, after driving the drain pump 36, the pressure inside the washing tank 4 is sequentially detected, and the drain pump 36 is stopped when the differential pressure with the atmospheric pressure reaches a predetermined value, and the drain pump 36 The sealing property of the washing tank 4 can also be judged by measuring the time until the differential pressure reaches a predetermined value after the operation of?) And comparing the measured time with the threshold value. In the case of using the above method, it is determined that the sealability of the washing tank 4 is secured when the time until the differential pressure reaches the predetermined value does not exceed the threshold, and the time until the differential pressure reaches the predetermined value is the threshold value. If it is exceeded, it is determined that the sealing property of the washing tank 4 is not secured.

The dishwasher 10 of the present embodiment sucks water from the inside of the washing tank 4 using the drain pump 36 before performing the washing process, and checks the sealing property of the opening of the washing tank 4, thereby ensuring the sealing property. If not, the operation is stopped. For this reason, the water leak in the washing tank 4 can be prevented beforehand.

Although the pressure sensor 7 is used as a means for detecting the pressure fluctuation inside the washing tank 4 in the above embodiment, the means for detecting the pressure fluctuation inside the washing tank 4 is not limited to this. For example, the load current of the motor of the drain pump 36 may be measured, and the pressure fluctuation inside the washing tank 4 may be detected. When the sealing tank 4 is sealed and the inside of the washing tank 4 is sufficiently depressurized, the torque required for driving the drain pump 36 is increased, and the load current of the motor of the drain pump 36 is increased. . On the other hand, when the sealing property of the washing tank 4 is not secured and the decompression inside the washing tank 4 is alleviated, the torque required for driving the drain pump 36 does not increase so much, and the motor of the drain pump 36 does not increase. The load current of does not increase much. Therefore, by measuring the load current of the motor of the drain pump 36 and comparing the measured load current with a predetermined threshold value, the pressure fluctuation inside the washing tank 4 can be detected.

(Second embodiment)

Description of the same items as in the first embodiment will be omitted. The dishwasher 10 of this embodiment has the same configuration as that of the first embodiment, and the contents of the operation are different.

5, the operation of the dish washing machine 10 of the present embodiment will be described.

When the operation is started in step S32, the washing tank 4 drives the drain pump 36 in step S34, and starts discharging the water stored in the bottom of the washing tank 4.

In step S36, it is determined whether or not the lowest water level switch 32 is turned off. When the lowest water level switch 32 is ON (NO in step S36), the controller 45 determines that the drainage is not completed and proceeds to step S38. In step S38, it is determined whether or not the elapsed time since the start of drainage has reached 3 minutes. If 3 minutes have elapsed since the start of drainage (YES in step S38) without completing the drainage, the flow proceeds to step S40, in which the user is notified of the drainage abnormality and the operation of the dishwasher 10 is stopped. do. If the draining is not completed but 3 minutes have not elapsed since the start of draining, the flow advances to step S34 to continue draining.

When the lowest water level switch 32 is turned off (YES in step S36), the flow proceeds to step S42 to stop the drain pump 36 and stop the drainage.

In step S44, the drying pan 48 is rotated reversely, and air is sucked in the washing tank 4. By rotating the drying pan 48 with the on-off valve 44 closed, a part of the air in the washing tank 4 flows out into the outer case 14 via the first air passage 51. As a result, the pressure in the air inside the washing tank 4 decreases.

In step S46, the pressure in the washing tank 4 is measured using the pressure sensor 7.

In step S48, it is determined whether the elapsed time after starting the rotation of the drying fan 48 has reached 3 minutes. If the elapsed time since the start of rotation reaches 3 minutes (YES in step S48), the controller 45 determines that it is abnormal and proceeds to step S56. If 3 minutes have not elapsed since the start of the rotation (NO at step S48), the flow proceeds to step S50.

In step S50, the pressure measured in step S46 is compared with the specified pressure. If the measured pressure exceeds the prescribed pressure (NO at step S50), the flow proceeds to step S44 and the reverse rotation of the drying fan 48 is continued. If the measured pressure is equal to or less than the prescribed pressure (YES in step S50), the flow proceeds to step S52.

In step S52, rotation of the drying pan 48 is stopped and suction of air in the washing tank 4 is stopped.

In step S54, the elapsed time from the time when the reverse rotation of the drying fan 48 is started to the time when the reverse rotation of the drying fan 48 is stopped is compared with a threshold value. When the sealing property of the opening part of the washing tank 4 is not ensured, compared with the case where the sealing property is ensured, the pressure inside the washing tank 4 decreases moderately. Therefore, the sealing property of the opening part of the washing tank 4 can be judged by comparing the time required until a pressure falls and below a prescribed pressure with a threshold value. If the elapsed time exceeds the threshold (NO at step S54), the controller 45 determines that the sealability of the opening of the washing tank 4 is abnormal, and proceeds to step S56. If the elapsed time does not exceed the threshold (YES in step S54), the controller 45 determines that the sealing property of the opening of the washing tank 4 is secured, and proceeds to step S58.

In step S56, the user is notified of the sealing property abnormality of the opening part of the washing tank 4, and operation | movement of the dishwasher 10 is stopped.

In step S58, a washing process is started, and a rinsing process, a high temperature rinsing process, and a drying process are performed after that.

The dishwasher 10 of this embodiment sucks air from the inside of the washing tank 4 using the drying pan 48 before performing the washing process, confirms the sealing property of the opening of the washing tank 4, and ensures the sealing property. If not, the operation is stopped. For this reason, the water leak in the washing tank 4 can be prevented beforehand.

In the above embodiment, an example in which air is sucked in the washing tank 4 to depressurize the inside of the washing tank 4 and the sealing of the opening of the washing tank 4 has been described. In addition to the above, for example, the drying fan 48 is rotated forward while the on-off valve 44 is closed to supply air into the washing tank 4 to pressurize the inside of the washing tank 4, and the opening of the washing tank 4 is then opened. You may monitor the sealing property of the.

(Third embodiment)

Another dishwasher 100 according to the present invention will be described with reference to FIGS. 6 to 8.

In common with the dishwasher 10 of 1st Example and 2nd Example, the same code | symbol is attached | subjected and description is abbreviate | omitted.

6, the cross section of the dishwasher 100 of a present Example is shown typically. The dishwasher 100 has substantially the same configuration as the dishwasher 10 of FIG. 1, but the dishwasher 100 does not include the pressure sensor 7, and instead the displacement gauge 9 (pressure change detection). Equivalent to a means for performing the same).

The displacement gauge 9 is a contact displacement gauge and is provided outside the center of the upper lid 6. The displacement meter 9 measures the displacement in the direction perpendicular to the plane of the upper surface of the upper lid 6 (up and down direction in FIG. 6) and outputs it to the controller 45.

7 is a graph showing the time change of the displacement of the upper lid 6 measured by the displacement meter 9.

Before the dishwasher 100 starts to operate, no external force acts on the upper lid 6, and deformation due to the pressure inside the washing tank 4 does not occur. At this point in time, the displacement 102 measured by the displacement meter 9 is zero.

When operation of the dishwasher 100 is started at time t ₀ , the drainage process is started, and the dishwasher 100 discharges the water stored in the washing tank 4 by using the drain pump 36. As the water inside is sucked in, the inside of the washing tank 4 is depressurized, and a pressure difference is generated inside and outside the washing tank 4 so that the upper lid 6 is bent toward the inside of the washing tank 4. When the sealing property of the opening part of the washing tank 4 is ensured, the center part of the upper cover 6 is bent along the displacement history 114. FIG. On the other hand, when the sealing property of the opening part of the washing tank 4 is not ensured, air flows into the washing tank 4 with decompression, and the pressure difference in and out of the washing tank 4 is alleviated, and the upper lid 6 The central portion is bent along the displacement history 112. 7 of d ₂ is the displacement amount (110 of washing tanks in a (t ₁₎ (4) which drives the drainage pump (36) in the sealing is secured state of the opening, and 1 minute has elapsed since the time of the upper cover (6) ) Represents the size. d ₁ is the displacement amount 108 of the upper lid 6 at a time t ₁ after 1 minute has elapsed since the drain pump 36 was driven while the sealing property of the opening of the washing tank 4 was not secured. Indicates the size. The sealing property of the opening part of the washing tank 4 can be judged by comparing the absolute value of the said displacement amount with a predetermined threshold value.

The operation of the dishwasher 100 will be described using FIG. 8.

When the operation is started in step S62, the drain pump 36 is driven in step S64 to start discharging the water stored in the bottom of the washing tank 4.

In step S66, it is determined whether or not the lowest water level switch 32 is turned off. If the lowest water level switch is ON (NO in step S66), the controller 45 determines that the drainage is not completed and proceeds to step S68. In step S68, it is determined whether or not the elapsed time since the start of drainage reached 3 minutes. If 3 minutes have elapsed since the start of the drainage (YES in step S68) without completing the drainage, the flow proceeds to step S70, in which the abnormality of the drainage is notified to the user and the operation of the dishwasher 100 is stopped. do. If the draining is not completed but 3 minutes have not elapsed since the start of draining, the flow proceeds to Step S64 to continue draining.

When the lowest water level switch 32 is turned off (YES in step S66), the flow advances to step S72 to stop the drain pump 36 and stop the drainage.

In step S74, the solenoid valve 20 is opened, the water supply passage 16 is turned on, and hot water is supplied into the washing tank 4. The amount of hot water supplied in step S74 is set to a small amount compared to the amount of hot water supplied for performing the washing step. The amount of hot water supplied at step S74 is controlled by the length of time for opening the solenoid valve 20. When a small amount of hot water is supplied to the washing tank 4, the solenoid valve 20 is closed and it progresses to step S76.

In step S76, the washing pump 28 is driven to start the circulation of the warm water in the washing tank 4. The hot water in the washing tank 4 is sucked by the washing pump 28 and flows into the washing water circulation path 30, and is pressurized by the washing pump 28 to be inside the washing tank 4 from the opening of the spray nozzle 8. Sprayed.

In step S78, it is determined whether the elapsed time since the start of circulation of the warm water reached 1 minute. If one minute has not elapsed since the washing pump 28 was driven (NO at step S78), the flow proceeds to step S76 to continue circulation of the hot water using the washing pump 28. When 1 minute has elapsed since the washing pump 28 is driven (YES in step S78), the flow proceeds to step S80.

In step S80, the displacement of the center part of the upper lid 6 is measured using the displacement meter 9. When the measurement is finished, the flow proceeds to step S82.

In step S82, the washing pump 28 is stopped to stop the circulation of the hot water.

In step S84, it is determined whether or not the absolute value of the displacement of the upper lid 6 measured in step S80 exceeds the threshold. If the absolute value of the displacement exceeds the threshold (YES in step S84), the pressure inside the washing tank 4 is depressurized to the same level as when normal operation is performed, and it is determined that the opening of the washing tank 4 is sealed. The flow proceeds to step S88. If the absolute value of the displacement does not exceed the threshold (NO in S84), it is determined that the pressure inside the washing tank 4 is not so reduced and that the opening of the washing tank 4 is not sealed, and the flow proceeds to step S86. do.

In step S86, the user is notified of the sealing abnormality of the opening part of the washing tank 4, and operation | movement of the dishwasher 100 is stopped.

In step S88, the solenoid valve 20 is opened, the water supply passage 16 is turned on, and the amount of hot water required to perform the washing step is supplied to the washing tank 4. If it is determined that the water level inside the washing tank 4 has reached the prescribed level using the water level switch 38, the solenoid valve 20 is closed to stop the supply of hot water, and the flow proceeds to step S90.

In step S90, it advances to a washing | cleaning process, and a rinse process, a high temperature rinse process, and a drying process are performed after that.

The dishwasher 100 of the present embodiment sucks a small amount of water in the washing tank 4 using the washing pump 28 before performing the washing process to check the sealing property of the opening of the washing tank 4, If not secured, stop operation. Since a small amount of water is used compared to the amount used in the washing step, even if the sealing property of the opening of the washing tank 4 is not secured, a large amount of water leakage can be prevented from occurring.

In the first to third embodiments described above, the time required for determining the sealability of the washing tank, the threshold of the differential pressure inside the washing tank, or the threshold of the displacement amount of the upper lid is configured of the dish washing machine (for example, Needless to say, it depends on the size, the capacity of the pump or the capacity of the fan.

As mentioned above, although embodiment of this invention was described in detail, these are only illustrations and do not limit a claim. The technique described in the claims includes various modifications and changes to the specific examples exemplified above.

In addition, the technical elements demonstrated in this specification or drawing show technical usability independently or by various combinations, and are not limited to the combination as described in the claim at the time of application. In addition, the technique illustrated in the present specification or the drawings is to achieve a plurality of objects at the same time, and to have a technical usefulness itself to achieve one of the objects.

According to the dishwasher of the present invention, water leakage can be prevented by monitoring the sealing property of the washing tank with a simple device configuration, and changing the operating state when the sealing property is not maintained, and not performing the washing operation.

Claims (4)

A washing tank having an opening and accommodating dishes to be washed; A cover that closes the opening of the washing tank, Means for transforming the pressure inside the washing tank, Means for detecting pressure fluctuations in the washing tank; Means for determining the sealability of the opening portion based on a pressure change inside the washing tank detected; And when the opening is not determined to be closed, changing the operating state. The method according to claim 1, Means for transforming the pressure in the washing tank, And a means for sucking water in the washing tank. The method according to claim 2, Means for detecting the pressure fluctuation, Dishwasher, characterized in that the pressure sensor for measuring the pressure inside the washing tank. The method according to claim 2, Means for detecting the pressure fluctuation, A dishwasher, characterized in that it is a displacement meter that measures the amount of deformation of the cover in a direction perpendicular to the face of the cover.

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