JPH06178752A - Dish washer - Google Patents

Abstract

PURPOSE:To eliminate useless initial drainage and shorten a time taken for washing dishes while improving the durability of a drainage device. CONSTITUTION:Immediately after making a power switch 41, a control circuit 40 operates a electric motor 35a to turn on a drain pump and to make initial drainage of washing water from a washing water tank. Then, the control circuit 40 is response to the making of a start switch 44 practices aseries of washing operations of either of 'standard course', 'powerful course' or 'ringsing course'. In this initial drain, an amount of washing water in the washing water tank is detected by a float switch 37. When the amount of the washing water is much, the drain pump is turned on for 30 secs. and when the amount of the washing water is few the drain pump is turned on for 15 secs. to shorten an initial water supply time. Also, during the early drain, a course changing switch 45 is turned on to enable the selection of the respective courses.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dishwasher for washing the dishes by circulating the washing water in a washing water tank provided at the bottom of the washing tank and spraying the dishes in the washing tank. In particular, the present invention relates to a dishwasher in which the previously used washing water remaining in the washing water tank is initially discharged before the dishes are washed.

[0002]

2. Description of the Related Art Conventionally, as shown in Japanese Utility Model Publication No. 2-20988, for example, as shown in Japanese Utility Model Publication No. 2-20988, a dishwasher of this type has a combination of water supply, washing and drainage. Before starting the operation of the sequence, the drainage device is always operated for a certain period of time to initially discharge the wash water remaining in the wash water tank, and the previously used wash water is not used in the new wash sequence. I am trying.

[0003]

However, in the above-mentioned conventional apparatus, since the drainage device is always operated for a certain period of time before starting the operation of the cleaning sequence, the previously used cleaning water remains in the cleaning water tank. If there is no wash water or the amount of remaining wash water is very small, there is a problem that the time for this initial drainage is wasted and the time for washing dishes is unnecessarily long, and this wasteful initial drainage is There is a problem that it is not preferable in terms of durability of the drainage device. The present invention has been made to address the above problems, and its purpose is to:
It is an object of the present invention to provide a dishwasher in which wasteful initial drainage is eliminated to shorten the dishwashing time and the drainage device has good durability.

[0004]

In order to achieve the above-mentioned object, a structural feature of the invention according to claim 1 is that it has a washing water tank at the bottom and a washing tank for storing dishes, and a washing water tank. Water supply device for supplying cleaning water to the interior, a cleaning device for circulating the cleaning water in the cleaning water tank and spraying it on the dishes to wash the dishes, a drainage device for draining the cleaning water in the cleaning water tank, and a power supply A power switch installed in the passage, a start switch for instructing the start of the dishwashing operation, a detection switch for detecting that the amount of wash water in the wash water tank is more than a predetermined amount, a power switch, a start switch, and A dishwasher equipped with a control circuit that is connected to a detection switch and electrically controls a water supply device, a washing device, and a drainage device in response to a signal from each switch to control a dishwashing operation. The control circuit activates the drainage device based on the detection result of the detection switch immediately after turning on the power switch to drain the wash water in the wash water tank. Initial drainage control means that activates the drainage device for a long period when the amount is above a certain amount, and activates the drainage device for a short period when the amount of wash water in the wash water tank is less than the specified amount, and a start after turning on the power switch. The sequence control means controls the water supply device, the cleaning device, and the drainage device in response to the turning on of the switch to execute a series of dishwashing sequences including water supply, cleaning, and drainage.

Further, the structural feature of the invention according to claim 2 is that, in the dishwasher according to claim 1, a change switch for instructing a change of a mode of a washing sequence is further provided, and a control circuit is provided. The cleaning sequence mode determining means determines the mode of the cleaning sequence executed by the sequence control means in response to the operation of the change switch after the power switch is turned on and before the start switch is turned on.

[0006]

In the invention according to claim 1 configured as described above, the sequence control means controls the water supply device, the cleaning device and the drainage device in response to the closing of the start switch to supply water, clean and Before executing a series of dishwashing sequences including drainage, in response to turning on the power switch, the initial drainage control means activates the drainage device to initially drain the wash water in the wash water tank. In this initial drainage, the initial drainage control means controls the operating time of the drainage device based on the detection result by the detection switch, and when the wash water in the wash water tank is a predetermined amount or more, the drainage device is operated for a long period of time. The drainage device is operated for a short period when the cleaning water in the cleaning water tank is less than a predetermined amount. This shortens the time for this initial drainage when the previously used wash water does not remain in the wash water tank or when the remaining wash water is very small.
Therefore, it is possible to avoid useless operation of the drainage device, reduce the time required to wash dishes, and improve the durability of the device.

Further, in the invention according to claim 2 configured as described above, in addition to the operation of the invention according to claim 1, the cleaning sequence mode determining means is provided after the power switch is turned on and after the start switch is turned on. Since the mode of the cleaning sequence executed by the sequence control means is determined in response to the operation of the change switch before the turning on, the mode of the cleaning sequence can be changed during the initial drainage of the cleaning water. As a result, in addition to the effect of the invention according to claim 1, time for changing the cleaning sequence mode can be saved, and the total time required for cleaning dishes can be shortened.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 schematically shows the whole of the dishwasher according to the embodiment. This dishwasher includes a washing tank 20 housed in a box-shaped housing 10. Cleaning tank 2
The rack 0 accommodates a rack 23 on the center of which a tableware 22 is loaded and unloaded through the door 21, and a pair of cleaning nozzles 24 and 25 are supported on the upper and lower surfaces thereof. The cleaning nozzles 24, 25 are the cleaning water tank 2 formed at the bottom of the cleaning tank 20 by the operation of the circulation pump 26.
The wash water circulated and supplied from 7 through the circulation pipe 28 is rotated and sprayed toward the tableware 22. A water supply pipe 31 is connected to the back wall 20a of the cleaning tank 20 at its outlet, and the water supply pipe 31 supplies high-temperature cleaning water from an external water supply source to the cleaning water tank 27 via a water supply valve 32. .

A drain pipe 33 and a sub-tank pipe 34 are branched from the circulation pipe 28. Drainage pipe 3
A drainage pump 35 is installed in the pump 3, and the pump 35
By its operation, the cleaning water in the cleaning water tank 27 is discharged to the outside of the machine through the drainage pipe 33. The tip of the sub-tank pipe 34 communicates with the sub-tank 36, and a float switch 37 is housed in the tank 36. The float switch 37 detects that the surface of the wash water in the wash water tank 27 has reached a reference level indicating the height required for cleaning, etc., and is turned on if the height of the water surface is higher than the reference level. If the water level is lower than the standard level, it will be turned off.

Next, an electric control device for electrically controlling the dishwasher configured as described above will be described with reference to the drawings. FIG. 2 shows the device in a block diagram. This electric control device is provided with a control circuit 40, and electric power is supplied to the circuit 40 via input buses L ₁ and L ₂ . An AC of 120 V is applied to the input bus L ₁ , and the input bus L ₂ is grounded. The coil X ₁ of the power switch 41 and the relay switch 42 is connected in series between the input buses L ₁ and L ₂ .
The power switch 41 is connected to the movable contact 41a which is turned on and off by a manual operation, and is connected at one end to the control circuit 40 and at the other end to a connection point between the movable contact 41a and the coil X ₁ to excite the movable contact 41a. Coil 41b to turn off
It has and. The coil X ₁ of the relay switch 42 is
Normally open contact X with both ends connected to the control circuit 40 by excitation
_It turns on ₁₁ .

An electric motor 35a of a drain pump 35 is connected between the input bus L ₁ and the output side of the control circuit 40,
Between the connection point of the movable contact 41a of the power switch 41 and the coil X ₁ of the relay switch 42 and the output side of the control circuit 40, the electric motor 26a of the circulation pump 26 and the water supply valve 3 are provided.
The second electromagnetic solenoid 32a and the display 43 are connected. In addition to the float switch 37 described above, a start switch 44 and a course changing switch 45 are connected to the input side of the control circuit 40. Control circuit 40
Is a microcomputer including a CPU, a ROM, a RAM, a timer, an I / O, etc., which repeatedly executes the main program of FIG. 3 (including the subprograms of FIGS. 5 to 8) and the “switch detection program of FIG. 4”. "
Is executed every predetermined time.

Next, the operation of the embodiment configured as described above will be described. When power is supplied to the control circuit 40 via the input buses L ₁ and L ₂ , the circuit 40 starts executing the “main program” in step 100 of FIG. The flag FLG for distinguishing the state before the cleaning operation from the state after the cleaning operation is initially set to "0", and the cleaning course number M indicating each of the standard, strong and rinse courses in the cleaning is initialized to "0". After the setting, the circulation process including steps 104 to 134 is repeatedly executed. Further, the electric motor 35a can be operated by supplying the electric power to the input buses L ₁ and L ₂ .

In this circulation processing, step 104
At, it is determined whether or not the power switch 41 is turned on by the state of the normally open contact X ₁₁ of the relay switch 42. Until the power switch 41 is turned on, the control circuit 40 continues to determine “NO” in step 104,
The determination process of 4 is continuously executed. After the user stores the rack 23 with the dishes 22 placed in the washing tank 21 and puts the detergent into the washing tank 21, when the movable contact 41a of the power switch 41 is turned on, the electromagnetic solenoid 32a, the electric motor 26a, and the indicator 43 are activated. At the same time, the coil X ₁ of the relay switch 42 is excited and the normally open contact X ₁₁ is turned on. As a result, the control circuit 40 determines “YES” in step 104 and advances the program to step 106.

In step 106, it is determined whether the float switch 37 is on. If a large amount of previously used cleaning water remains in the cleaning water tank 27 and the float switch 37 is on, it is determined to be “YES” in step 106 and the first timer T ₁ is measured in step 108. Set the time value to the required 30 seconds for drainage. If the previously used cleaning water does not remain in the cleaning water tank, or if the remaining cleaning water is in a very small amount and the float switch 37 is off, “N” is determined in step 106.
If it is determined to be “O”, the measured time value of the first timer T ₁ is set to 15 seconds, which is shorter than the above, at step 110. In addition,
The first timer T ₁ and other timers measure elapsed time by a program process (not shown). Next, in step 112, the time measurement of the first timer T ₁ is started, and in step 114, the electric motor 35a is operated to turn on the drainage pump 35. As a result, the wash water in the wash water tank 27 is drained to the outside via the drain pipe 33. After the processing of step 114,
In step 116, it is determined whether the first timer T ₁ has finished measuring the set time (30 seconds or 15 seconds). If the first timer T ₁ has not finished measuring the set time, it is determined to be "NO" at step 116 and the circulation process including steps 114 and 116 is repeatedly executed. Then, during the circulation process, when the second timer T ₁ finishes measuring the set time, it is determined to be “YES” in step 116, and the operation of the electric motor 35a is stopped in step 118 to stop the drainage pump. Turn off 35. As a result, the previously used cleaning water in the cleaning tank 27 is discharged to the outside.

Next, at step 120, the flag FLG is set to "
In this case, if the flag FLG is kept set to "0" by the process of step 102 (or step 134 described later), the process of step 120 is executed. On the other hand, while the "main program" is being executed, the control circuit 40 interrupts the "switch detection program" at predetermined time intervals. This "switch detection program" is shown in detail in FIG. 4, and the control circuit 40 starts its execution at step 200 and the flag FL at step 202.
It is determined whether G is "1". As described above, if the flag FLG is "0", "N" is entered in step 202.
When it is determined to be “O”, the cleaning course number M is sequentially changed to any of “0” to “2” every time the course changing switch 45 is turned on by the processing of steps 204 to 210, and the cleaning is performed by the processing of step 212. The name of the cleaning course is displayed on the display 43 based on the course number M. In the display of the cleaning course name, if the cleaning course number M is "1", letters or numbers representing the standard course are displayed on the display unit 43. If the washing course number M is “2”, the letters or numbers representing the strong course are displayed on the display 43. If the washing course number M is “0”, the letters or numbers representing the rinsing course are displayed on the display 43.

Next, at step 214, it is judged if the start switch 44 has been turned on. If the start switch 44 is not turned on, it is determined to be "NO" in step 214 and the program is advanced to step 218. In step 218, the "switch detection program" is entered.
To finish. In this way, the flag FLG is kept at "0" until the start switch 44 is turned on.
In response to the ON operation of the course change switch 45, steps 204 to 212 of the "switch detection program".
The cleaning course number M is changed by the processing of. On the other hand, when the start switch 44 is turned on, the determination in step 214 is "YES" and the program proceeds to step 216. Flag FLG in step 216
Is set to "1" and the "switch detection program" is ended in step 218. In this way, the flag FLG
Is changed to "1", the "switch detection program"
Since the switch 202 determines “YES” and the process including steps 204 to 216 is not executed,
It is impossible to change the cleaning course number M.

Further, by changing the flag FLG to "1", the control circuit 40 determines "YES" in step 120 of the "main program" (FIG. 3) and advances the program to steps 122 and 124. . Step 12
In Nos. 2 and 124, it is determined whether the cleaning course number M is "1", "2", or "0".
If the cleaning course number M is "1", it is determined to be "YES" in step 122, the program proceeds to step 126, and the "standard course routine" is executed in step 126. As shown in detail in FIG. 5A, the control circuit 40 starts the execution of the “standard course routine” at step 300 and executes the “hot water supply routine” at step 301. This "hot water supply routine" is started in step 400 of FIG. 6, and in steps 402 to 406, the water supply valve 32 is turned on by exciting the electromagnetic solenoid 32a until the float switch 37 is turned on, and the float switch 37 is turned on. When is turned on, the excitation of the electromagnetic solenoid 32a is released to turn off the water supply valve 32. As a result, the high-temperature clean wash water flows into the wash water tank 27 through the water supply pipe 31 until it reaches the reference level. Then, in step 408, this "hot water supply routine" is ended.

After execution of this "hot water supply routine", the control circuit 40 sets the measured time value of the second timer T ₂ to 3 minutes in step 302 of FIG. Execute. This "cleaning routine" is shown in FIG.
Is started in step 410, the time measurement of the second timer T ₂ is started in step 412, and steps 414-
By the processing of 418, the circulation pump 26 is continuously turned on by operating the electric motor 26a until the second timer T ₂ finishes measuring the time of 3 minutes, and the second timer T ₂ becomes 3 seconds.
When the time measurement of minutes is completed, the circulation pump 26 is turned off by stopping the operation of the electric motor 26a. This completes the 3-minute dishwashing with the cleaning water containing the detergent. Then, in step 420, this "cleaning routine" is ended.

After the execution of this "cleaning routine", the control circuit 40 sets the measured time value of the third timer T ₃ to 30 seconds necessary for draining in step 304 of FIG. To execute the “drainage routine”. This “drainage routine” is started in step 430 of FIG. 8, the time measurement of the third timer T ₃ is started in step 432, and the time of the third timer T ₃ is 30 seconds by the processing of steps 434 to 438. Until the measurement is completed, the drainage pump 35 is turned on by operating the electric motor 35a, and when the third timer T ₃ finishes measuring the time of 30 seconds, the drainage pump 35 is stopped by stopping the operation of the electric motor 35a. Turn off. As a result, the wash water in the wash water tank 27 is drained to the outside via the drain pipe 33. Then, in step 440, this "drainage routine" is ended.

Next, the control circuit 40 executes the "hot water supply routine" in step 306 of FIG. 5A, which is similar to step 301. As a result, high-temperature clean cleaning water is supplied again to the cleaning tank 27. After execution of the "hot-water supply routine" in step 306, the control circuit 40 sets the second measurement time value of the timer T ₂ to 30 seconds at step 307, executes the "cleaning routine" the same at step 308 To do. As a result, the clean wash water in the wash water tank 27 is passed through the circulation pipe 28 to the wash nozzle 2
Since the cleaning nozzles 24 and 25 are rotated, the cleaning water is sprayed onto the dishes 22 while the cleaning nozzles 24 and 25 are rotated, the dishes 22 are rinsed for 30 seconds. After that, the control circuit 4
0 is a step 3 similar to the steps 304 and 305.
By the treatment of 09 and 310, the cleaning water used for the rinsing is discharged to the outside in 30 seconds. This step 3
After executing the "drainage routine" of 10, the control circuit 40 executes the same processing as that of steps 306 to 310 in steps 311 to 315, so that the tableware 22 is rinsed again for 30 seconds, and in step 316, " The execution of the "standard course routine" is completed. As a result, in this standard course, the dishes 22 are washed with washing water containing detergent for 3 minutes and then rinsed twice for 30 seconds each.

If the cleaning course number M is set to "2" by the processing of steps 204 to 210 (FIG. 4), it is determined "YES" in step 124 and the program proceeds to step 128. Same step 128
"Perform the powerful course routine". This "strong course routine" comprises steps 320 to 336 as shown in detail in FIG.
Compared with, the only difference is that the measurement time value of the second timer T ₂ is set to 10 minutes in step 322. As a result, in this strong course, the dishes 22 are washed with washing water containing a detergent for 10 minutes, and then the dishes 22 are washed for 30 seconds each.
It is rinsed over time.

Further, if the cleaning course number M is set to "0" by the processing of steps 204 to 210 (FIG. 4), both of the steps 122 and 124 are "NO".
Then, the program proceeds to step 130, and the “rinse course routine” is executed at step 130.
This "rinsing course routine" is, as shown in detail in FIG. 5C, step 30 of the "standard course routine".
Steps 341-350 similar to steps 6-315.
As a result, in this rinsing course, the tableware 22 is only rinsed twice for 30 seconds each.

Steps 126 to 13 of FIG. 3 as described above.
0 "Standard course routine", "Strong course routine"
Alternatively, after the "rinsing course routine" is completed, the control circuit 40
Executes the auto-off process in step 132. In this auto-off process, the electromagnetic solenoid 41b of the power switch 41 is excited to turn off the movable contact 41a. As a result, except for the electric motor 35a of the drainage pump 35, the electromagnetic solenoid 32a of the water supply valve 32, the electric motor 26a of the circulation pump 26, and the display 43 are connected to the input busbar L _1.
Separated from. Next, at step 134, the flag FL
Change G to "0" and return the program to step 104. Therefore, the determination process of step 104 is repeatedly executed until the power switch 41 is turned on again, and the switch 41 is kept waiting. When the power switch 41 is turned on, the processes of steps 106 to 118 are executed, and then step 120
The start switch 44 is placed in a waiting state by the circulating process of. In this case, since the flag FLG has been returned to "0" by the processing of step 134, the washing course number M can be changed again.

As described above, according to the above embodiment, the drainage pump 35 is operated immediately after the power switch 41 is turned on, and the wash water in the wash water tank 27 is initially drained.
Then, in response to turning on of the start switch 44, a series of cleaning sequence operations of any one of the "standard course", the "strong course" and the "rinse course" is executed. In this initial drainage, if a large amount of cleaning water remains in the cleaning water tank 27 and the float switch 37 is on, the drainage pump 35 is operated for 30 seconds, and a large amount of cleaning water remains in the cleaning water tank 27. If the float switch 37 is turned off without it, the drainage pump 35 is operated for 15 seconds. Therefore, when the previously used cleaning water does not remain in the cleaning water tank 27 or when the remaining cleaning water is very small, the time for this initial drainage is shortened,
It is possible to avoid useless operation of the drainage pump 35, reduce the time for cleaning the entire tableware 22, and improve the durability of the pump 35. Further, during the initial drainage, the flag FLG is set to "0", and by turning on the course change switch 45, any one of "standard course", "strong course" and "rinse course" can be selected. Since this is possible, the time for changing each course can be saved and the total time required for cleaning the dishes 22 can be shortened.

[Brief description of drawings]

FIG. 1 is a vertical sectional side view schematically showing a dishwasher according to an embodiment of the present invention.

FIG. 2 is a block diagram of an electric control device for the dishwasher.

3 is a flowchart of a "main program" that is repeatedly executed by the control circuit of FIG.

FIG. 4 is a flowchart of a “switch detection program” executed by the control circuit in an interrupt manner.

5A is a flowchart showing details of a "standard course routine" of FIG. 3, FIG. 5B is a flowchart showing details of a "strong course routine" of FIG. 3, and FIG.
3 is a flowchart showing details of the "rinse course routine" of FIG.

FIG. 6 is a flowchart showing details of a “hot water supply routine” of FIGS. 5 (A) (B) (C).

FIG. 7 is a flowchart showing details of a “cleaning routine” of FIGS. 5 (A) (B) (C).

FIG. 8 is a flowchart showing details of a “drainage routine” of FIGS. 5 (A) (B) (C).

[Explanation of symbols]

20 ... Wash tank, 21 ... Door, 22 ... Tableware, 24, 25 ...
Cleaning nozzle, 26 ... Circulation pump, 26a ... Electric motor,
27 ... Wash water tank, 32 ... Water supply valve, 32a ... Electromagnetic solenoid, 35 ... Drainage pump, 35a ... Electric motor, 36
... Sub tank, 37 ... Float switch, 40 ... Control circuit (microcomputer), 41 ... Power switch, 4
4 ... Start switch, 45 ... Course change switch.

Claims (2)

[Claims] 1. A washing tank having a wash water tank at the bottom and containing dishes, a water supply device for supplying wash water to the wash water tank, and circulating the wash water in the wash water tank and spraying it on the dishes And a washing device for washing the dishes, a drainage device for draining the washing water in the washing water tank, a power switch interposed in the power supply path, and a start switch for instructing the washing operation of the dishes A detection switch for detecting that the amount of cleaning water in the cleaning water tank is a predetermined amount or more, and the water supply device, the cleaning device, and the water supply device, which are connected to the power switch, the start switch and the detection switch, in response to signals from the switches. In a dishwasher equipped with a control circuit for electrically controlling a drainage device to control a dishwashing operation, the control circuit is provided with the control circuit immediately after turning on the power switch. The drainage device is operated based on the detection result of the discharge switch to drain the wash water in the wash water tank. When the wash water in the wash water tank is a predetermined amount or more, the drainage device is lengthened. Initial drainage control means for operating for a short period of time and operating the drainage device for a short period of time when the amount of wash water in the wash water tank is less than a predetermined amount; and in response to turning on the start switch after turning on the power switch, A dishwasher comprising: a sequence control means for controlling a water supply device, a washing device and a drainage device to execute a series of dishwashing sequences consisting of water supply, washing and drainage. 2. The dishwasher according to claim 1, further comprising a change switch for instructing a change of a mode of the cleaning sequence, and the control circuit after the power switch is turned on and after the start. A dishwasher comprising: a washing sequence mode determining unit that determines a mode of a cleaning sequence executed by the sequence control unit in response to an operation of the change switch before the switch is turned on.