JP2782857B2 - dishwasher - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a dishwasher for washing dishes.

2. Description of the Related Art Conventionally, this type of dishwasher has been configured as shown in FIG.

That is, the washing tank 2 is provided inside the main body 1, and water or hot water is supplied into the washing tank 2 by the water supply valve 3. When the apparatus is driven, the cleaning water is attached to a pump chamber communicating with the other side of the drain hole 4 and circulates inside the cleaning tank 2 by a cleaning pump 6 driven by a motor 5. That is, in this circulation, after the washing water is sucked into the washing pump 6 from the drain hole 4, the washing water is supplied to the washing nozzle 7 at the bottom of the washing tank 2 from the washing pump 6, and is jetted from the washing nozzle 7 to wash the dishes. The process is performed again by returning to the drain hole 4. A heater 8 for heating cleaning water is provided between the cleaning nozzle 7 and the bottom of the cleaning tank 2. In addition, tableware can be arranged neatly above the washing nozzle 7,
A tableware basket 9 is provided, which is designed to inject washing water into the tableware effectively. The tableware basket 9 is provided with a plurality of moving rollers, which can be pulled out of the front of the main body 1. In addition, on the front part of the cleaning tank 2,
An openable and closable door 10 is attached. Further, a drain pump 11 is provided for discharging the washing water out of the machine.

Here, some conventional dishwashers drive the cleaning pump 6 and the drainage pump 11 by one motor 5. The structure of this type of pump is shown in FIGS.
This will be described with reference to the drawings.

In FIG. 6, the cleaning pump 12 and the drainage pump 13 are driven by the motor 5. The washing pump 12 has an impeller 12-a coaxially with the shaft 5-a of the motor, and its rotation is transmitted by a joint 14. Also drain pump
The thirteen impellers 13-a are transmitted with the rotation of the motor 5 by a pulley 14-a formed on the outer portion of the joint 14, a belt 15, and a pulley fixed to the impeller 13-a of the drainage pump. . A sealing mechanism 16 is provided on the impeller 12-a of the washing pump and the impeller 13-a of the drainage pump so that washing water does not leak from the respective pump casings to the motor 5 side.
Is provided. The cleaning pump 12 and the drainage pump 13 are both volute pumps, which suction cleaning water from the front of each impeller and discharge the cleaning water toward the outer periphery of the pump casing. Next, the operation of these pumps will be described. A clutch 17 is incorporated in the joint 14, and transmits only one-way rotation to the impeller 12-a of the cleaning pump. This is due to both rotations of the motor 5,
Since the cleaning pump 12 and the drainage pump 13 are driven,
At the time of drainage, it is necessary to stop the rotation of the impeller 12-a of the drainage pump. This is because, when the impeller 12-a of the cleaning pump is rotated during drainage, a very loud noise is generated when the amount of cleaning water is reduced and the air is aerated. Also,
Since the clutch mechanism is not provided in the impeller 13-a of the drainage pump, the motor 5 rotates by either rotation.
Therefore, a valve (not shown) is provided so that water is not supplied so as not to drain during cleaning. As described above, the structure is very complicated using the clutch 17, the belt 15, and the valve mechanism.

Next, the pump shown in FIG. 7 will be described. In this type of pump, a cleaning pump 12 and a drainage pump 13 are arranged on one side of a motor 5 so as to be arranged in the axial direction. The impeller 12-a of the washing pump and the impeller 13-a of the drainage pump are directly connected to the shaft 5-a of the motor, and each rotation of the motor 5 also rotates the respective impeller. At this time, the cleaning pump
12 is a volute pump as above, but a drain pump
13, a vortex pump is used. This is because when the impeller 13-a of the drain pump rotates counterclockwise (Y direction), the washing water is drained out of the machine. Conversely, when the impeller 13-a of the drain pump rotates clockwise, washing water or air flows from the drain hose toward the drain hole 4. Therefore, even without a valve, the impeller 14
-A does not rotate and drain. Here, in this type of pump, as shown in FIG. 7, the shaft 5-a of the motor is not only horizontal but also vertical. Rather, it is more common in the vertical direction.

Problems to be Solved by the Invention However, looking at such a structure, the structure shown in FIG. 6 is very complicated as described above, and is therefore very expensive. . Further, since the transmission by the belt is used, noise is easily generated, and the eccentricity of the shaft is increased due to the wear of the bearing, which may cause water leakage. Further, a valve is used, and if a failure occurs in this valve, drainage occurs during cleaning, and the heater 8 may be in a state of being burned in an empty state, resulting in a dangerous state.

Next, with the structure shown in FIG. 7, a very simple and inexpensive structure can be obtained. However, since the impeller 12-a of the washing pump is rotating even during draining, as described above, a very loud noise is generated when the washing water is reduced and the air is aerated. This is true whether the shaft 5-a of the motor is horizontal or vertical. Here, as a countermeasure against noise, for example, a clutch is to be provided for the impeller 12-a of the cleaning pump (A in FIG. 7).
Clutches are limited to those that can be used underwater. However, in practice, it is very difficult to use the clutch due to various problems such as rust, elimination of food waste, and heat resistance in hot water supply. Further, since the impeller 12-a of the washing pump and the impeller 13-a of the drainage pump are fixed on the same axis as the shaft 5-a of the motor, the shaft 5-a of the motor becomes long. Accordingly, the eccentricity of the impeller 13-a of the cleaning pump tends to be large, and in order to prevent contact with the pump, the manufacturing accuracy of the shaft 5-a of the motor is increased, or the impeller 12-a of the cleaning pump and the pump casing are connected. It is necessary to open a gap. However, this means that
It is not preferable to increase the cost or to secure the capacity of the pump.

Therefore, an object of the present invention is to provide a cleaning pump and a drainage pump on the same axis of a motor shaft, and to obtain a high-performance pump with a simple configuration that reduces noise during drainage.

Means for Solving the Problems To achieve the above object, the present invention provides a cleaning tank, a cleaning pump including a volute pump that sucks cleaning water from an inner bottom portion of the cleaning tank and injects cleaning water from a cleaning nozzle, A vortex-type drain pump for discharging the wash water out of the machine is provided, and the wash pump and the drain pump are respectively disposed at both ends of one motor shaft.

Further, the present invention includes a washing tank, a washing pump that sucks washing water from an inner bottom portion of the washing tank, and injects washing water from a washing nozzle, and a drain pump that discharges washing water out of the machine. The pump and the drainage pump are provided at both ends of one motor shaft, respectively, and the washing pump is provided with a clutch mechanism for transmitting the drive of the motor to the drainage pump at the time of washing and at the time of drainage.

Further, a clutch mechanism is provided at least between the impeller of the washing pump and the motor.

Operation In the dishwasher pump according to the present invention, the washing pump and the drainage pump can be disposed coaxially with the motor shaft by the above configuration.

In addition, by making the drainage pump a vortex pump,
The washing and draining steps can be performed by both rotations of the motor without having a valve mechanism. Further, by providing a clutch mechanism between the motor and the impeller, the rotation of the motor is not transmitted during unnecessary steps, so that the pump can be operated without generating noise generated when the impeller rotates. It is.

Embodiment FIG. 1 shows a sectional view of an embodiment of a dishwasher pump according to the present invention.

In the drawings, the same reference numerals as those in FIGS. 5 to 7 denote the same parts,
The same parts are shown.

In the figure, a cleaning pump 12 is provided on the left side, and a drainage pump 13 is provided on the right side. The structure of the cleaning pump is similar to that of the cleaning pump shown in FIG. 6, and the cleaning pump 12 is an efficient volute pump. To the impeller 13-a. That is, the rotation of the motor 5 is transmitted in the counterclockwise direction (X direction) of the left side view shown in FIG. 2 to discharge the washing water. Therefore, cleaning can be performed in this case. Conversely, clockwise, motor 5
Of the washing pump, the impeller 12-a of the washing pump remains stopped during drainage. Therefore, no noise is generated by the impeller 12-a of the washing pump during drainage. At this time, the rotation of the impeller 12-a of the cleaning pump is stopped by the frictional resistance of the seal mechanism 16 for preventing water leakage from the pump casing to the motor 5 side. Here, when we look at the clutch 17, the clutch
17 is in the air outside the cleaning pump 12, and is advantageous in terms of the use of the clutch 17 against problems such as rust.

Next, regarding the configuration on the drain pump side, the drain pump 13 is a vortex pump, and does not particularly have a valve mechanism. Also,
The impeller 14-a of the drain pump is connected to the shaft 5-a of the motor.
And the rotation of the motor 5 is transmitted. In the counterclockwise direction (Y direction (clockwise on the cleaning pump 12 side)) of the right side view shown in FIG. 3, the cleaning water can be discharged. Conversely, in the clockwise rotation, water or air flows from the drain hose toward the drain hole 4 as described above. Therefore, by using a vortex pump, both rotations of the motor 5 can be used without a valve mechanism.

As described above, in the present invention, by disposing the cleaning pump and the drain pump at both ends of one motor, one motor can drive two pumps by using both rotations thereof. In addition, the clutch can be used in the washing pump to prevent the generation of noise during drainage, and the clutch can be used in the air, so that the reliability of the clutch is high. Further, by using a vortex pump as the drainage pump 13, a special valve mechanism is not required for both rotations of the motor, so that the configuration can be simplified.
Therefore, it is possible to supply an inexpensive pump having a single motor and a relatively simple configuration.

 A second embodiment will be described.

In FIG. 4, the clutch 17 is also used on the drain pump side. The cleaning pump has the same configuration as that of FIG.

Next, in the configuration on the drain pump side, the drain pump 13 is also a volute pump. And the impeller 13-
a also transmits the rotation of the motor 5 by the joint 14 incorporating the clutch 17. When viewed from the right side, when rotating counterclockwise, the impeller 13-a of the drain pump rotates, and the washing water can be discharged. When rotating clockwise in reverse, clutch 17
Is idle, and the impeller 14-a of the drain pump does nothing. In this configuration, only necessary impellers are driven when necessary, both during washing and drainage, so that the load on the motor 5 can be reduced and the noise is advantageous. Further, in this configuration, the drain pump 13 is a volute pump because the following points are more advantageous than the vortex pump. That is, in a dishwasher, foreign substances such as a part of food leftovers and pieces of tableware may enter the pump. Therefore, when using the vortex pump, it is necessary to provide a clearance so that these foreign substances do not become jammed. In this case, the impeller 13-a of the drainage pump must be increased in order to increase the capacity of the pump, and the load on the motor 5 also increases. In this respect, the volute pump is used here because it is more advantageous than the vortex pump. However, there is no problem even if a vortex pump is used. In the second embodiment, since the clutch 17 and the joint 14 are used, the price is relatively high as compared with the first embodiment.

Advantageous Effects of the Invention The present invention includes a washing pump that sucks washing water from an inner bottom portion of a washing tank and jets washing water from a washing nozzle and a drain pump that discharges washing water outside the machine. Are disposed at both ends of one motor, respectively, and further, by using a vortex pump as the drainage pump and a volute pump as the cleaning pump,
A jet nozzle with strong jetting power is generated from the washing nozzle to enhance the washing effect, and a vortex pump is used for the drainage pump, so no special valve mechanism is required for both rotations of the motor. Drainage can be performed. In addition, the clutch can be used in the washing pump to prevent the generation of noise during drainage, and the clutch can be used in the air, so that the reliability of the clutch is high. Therefore, since there is only one motor and the configuration is relatively simple, an inexpensive pump can be supplied. Further, although the pump of the present invention is slightly longer in the axial direction, it does not take up as much space as the conventional two pumps. Therefore, the space in the dishwasher can be effectively used. For example, in an installation type dishwasher, effects such as facilitating construction work at the time of installation are produced.

Further, when the clutch is used at both ends, the load on the motor can be reduced and the noise performance can be improved although the price is slightly higher.

[Brief description of the drawings]

FIG. 1 is a sectional view of a main part of a dishwasher according to a first embodiment of the present invention, FIG. 2 is a structural view of the washing pump, FIG. 3 is a structural view of the drainage pump, and FIG. FIG. 5 is a longitudinal sectional view of a conventional dishwasher, FIG. 6 is a longitudinal sectional view of a conventional dishwasher, FIG. 7 is another principal dishwasher of the conventional dishwasher. It is principal part sectional drawing of a machine. 2 ... cleaning tank, 5 ... motor, 5-a ... motor shaft, 7 ... cleaning nozzle, 12 ... cleaning pump, 12-a ...
... Impeller of cleaning pump, 13 ... Drainage pump, 13-a ...
Impeller of drainage pump, 14 joint, 16 seal mechanism, 17 clutch.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) A47L 15/42

Claims (3)

(57) [Claims] 1. A cleaning pump comprising a cleaning tank, a volute pump for sucking cleaning water from an inner bottom portion of the cleaning tank, and spraying the cleaning water from a cleaning nozzle, and a vortex drain pump for discharging the cleaning water out of the machine. A dishwasher, wherein the washing pump and the drainage pump are respectively disposed at both ends of one motor shaft. 2. The washing pump, comprising: a washing tank; a washing pump for sucking washing water from an inner bottom of the washing tank and jetting washing water from a washing nozzle; and a drain pump for discharging the washing water out of the machine. And a drain pump are provided at both ends of one motor shaft, respectively, and a dishwasher is provided with a clutch mechanism for transmitting the drive of the motor to the cleaning pump for washing and to the drain pump for draining. 3. The dishwasher according to claim 1, wherein a clutch mechanism is provided at least between the impeller of the washing pump and the motor.