JP4191178B2 - Dishwasher - Google Patents

Description

  The present invention relates to a dishwasher. In detail, it is arrange | positioned in the washing tank of a tableware washing machine, and is related with the nozzle which injects washing water.

  2. Description of the Related Art A dishwasher that cleans dishes stored in a washing tank by pressurizing washing water in the washing tank with a washing pump and spraying the pressurized washing water from a nozzle is known. Until now, the shape of the nozzle has been devised so that the cleaning water is jetted over a wide area in the cleaning chamber. For example, the dishwasher of Patent Document 1 employs a nozzle having a rotating fountain arm and a tower nozzle arranged at the center thereof. In the tower nozzle, the upper nozzle is slidably accommodated in the lower nozzle, and the upper nozzle is raised by the pressure of the washing water. In this dishwasher, the discharge force of the washing pump is periodically changed. As the water pressure of the cleaning water fluctuates, the upper nozzle moves up and down, and the cleaning water is jetted over a wide area in the cleaning chamber. The upper nozzle is provided with a plurality of injection ports for injecting cleaning water upward.

JP-A-4-279139

The upper nozzle of the tableware washing machine of Patent Document 1 is provided with an injection port for injecting cleaning water upward. The cleaning water sprayed upward from the upper nozzle is for cleaning the tableware stored immediately above the upper nozzle, and is sprayed to an extremely limited position. If the tableware is not accommodated in the limit position, the cleaning water sprayed upward from the upper nozzle does not contribute to the cleaning and is sprayed wastefully. If the cleaning water is to be jetted unnecessarily from the upper nozzle, a storage method in which tableware is not stored immediately above the upper nozzle is taken, and the cleaning water amount is directed to a direction that contributes to cleaning. Therefore, it is reasonable that an accommodation method in which tableware is not accommodated above the upper nozzle is an optimum accommodation method, and the upper nozzle is not provided with an injection port for injecting cleaning water upward.
However, there are various shapes and sizes of tableware stored in the washing tank, and the tableware is not always stored in an optimal storage method intended by the designer. Accordingly, assuming that tableware is arranged above the upper nozzle, it is necessary to provide an injection port for injecting above the tower nozzle so that the tableware arranged above the upper nozzle can be washed. .
The present invention was developed to eliminate the above-mentioned problems. That is, when the tableware is stored by the optimal storage method and the tableware is not located above the upper nozzle, the cleaning water is not sprayed upward, but directed to the amount of cleaning water in the direction that contributes to cleaning. On the other hand, when the tableware is arrange | positioned above an upper stage nozzle, it aims at providing the tableware washing machine which can wash the tableware by injecting washing water above a tower nozzle.

The dishwasher of this invention is equipped with the washing tank which accommodates tableware, the nozzle which injects washing water, and the washing pump which sends washing water to a nozzle. Nozzle is placed into the cleaning tank, and a tower nozzle.
The tower nozzle includes a lower nozzle and an upper nozzle. The upper nozzle is disposed inside the lower nozzle and rises due to the water pressure of the washing water sent from the washing pump. On the upper end surface of the lower nozzle, an opening through which the upper nozzle enters and exits and an injection port for injecting the cleaning water upward are formed. The opening and the injection port may be separated or may be continuous. That is, a part of the opening may be an injection port. The lower end of the upper nozzle is formed with a large-diameter flange than the opening formed in the lower nozzle, when the upper stage nozzle increases its flange closes the contact with the injection port to the upper end surface of the lower nozzle, upper nozzle When the nozzle descends from the uppermost position, the flange is separated from the upper end surface of the lower nozzle and the injection port is opened .

When the tableware is not disposed above the tower nozzle, upper nozzle by pressure of washing water is raised to push up the top level, a flange formed at the lower end of the upper nozzle, it is formed on the upper end surface of the lower nozzle Close the injection port. As a result, cleaning water is not sprayed above the tower nozzle. When the tableware is not located above the upper nozzle, the cleaning water is not sprayed upward unnecessarily, but is directed to the amount of cleaning water in a direction that contributes to cleaning.
On the other hand, when the tableware is located above the tower nozzle, the upper nozzle does not rise to the highest position because it comes into contact with the upper tableware. Since the flange formed at the lower end of the upper nozzle does not contact the upper end surface of the lower nozzle, the injection port formed at the upper end surface of the lower nozzle is not blocked. Washing water is jetted above the tower nozzle from the jet port formed in the upper end surface of the lower nozzle. Tableware located above the tower nozzle is washed.
According to the dishwasher of the present invention, when the tableware above the upper nozzle not located, without wastefully injecting the washing water upward, thus direct the washing water to contribute direction wash On the other hand, when the tableware is arranged above the upper nozzle, it is possible to wash the tableware by spraying washing water above the tower nozzle.
In the dishwasher of the present invention, the tower nozzle is rotatably arranged in the washing tank, the shoulder of the flange is chamfered, and when the upper nozzle rises, the upper end of the nozzle swivels as the nozzle rotates. It is preferable. According to the dishwasher described above, when the upper nozzle is pushed upward, the upper end of the upper nozzle rotates as the nozzle rotates. As a result, the cleaning water is sprayed over a wide range from the rotating upper nozzle.

Hereinafter, preferred embodiments of the present invention will be described.
(Embodiment 1) Wash water is sprayed in the horizontal direction from the spray port formed in the upper nozzle.
(Mode 2) When the upper nozzle of the tower nozzle rises to the uppermost position, the dishes disposed around the tower nozzle are washed with the washing water sprayed horizontally from the jet nozzle of the upper nozzle.

(Example 1)
A dishwasher 10 according to a first embodiment embodying the present invention will be described with reference to the drawings.
FIG. 1 shows the dishwasher 10 with the door 15 closed with respect to the main body 12. The door 15 is provided with a handle 15a, an operation panel 16, a lock lever 13, and an exhaust port 18. The operation panel 16 is provided with various buttons and lamps. By sliding the lock lever 13 in the lateral direction, the door 15 can be locked and unlocked (FIG. 1 shows a state in which the lock lever 13 is disposed at the lock position).
When the user puts his hand on the handle 15 a and pulls it forward, the cleaning tank 14 is pulled out from the main body 12 together with the door 15. FIG. 2 illustrates the dishwasher 10 with the washing tub 14 drawn out. The main body 12 slidably supports the cleaning tank 14 via rollers and rails (not shown). The cleaning tank 14 is formed in a box shape with an open top, and a rotary nozzle 20, a leftover filter 17, a heater cover 30a, and the like are mounted therein. In addition, although the tableware basket 61 which accommodates the tableware 17 is attached in the washing tank 14, the illustration is abbreviate | omitted in FIG. 2 (the tableware basket 61 is illustrated in FIG. 3). The rotary nozzle 20 includes a tower nozzle portion 23 composed of an upper nozzle 21 and a lower nozzle 22 and a horizontal nozzle portion 24. The rotary nozzle 20 is formed with a plurality of injection ports. The rotating nozzle 20 will be described in detail later. The leftovers filter 17 is formed in a mesh shape, and is provided to filter out the leftovers washed away from the dishes 17 when the dishes 17 are washed. The leftover filter 17 can be removed from the washing tank 14, and the leftovers filtered off can be discarded. The heater cover 30a has a snowboard shape, and a heater (30: see FIG. 3) is attached below the heater cover 30a.

As shown in FIG. 3, a tableware basket 61 is disposed in the cleaning tank 14. The tableware basket 61 is formed in a shape corresponding to the tableware 19 in order to hold various tableware (large plate, small plate, bowl, cup, ladder, spoon, etc.) 19.
A suction recess 31 is formed at the bottom of the cleaning tank 14. The upper opening of the suction recess 31 is covered with a mesh-like leftover filter 17. A pump 27 is provided below the bottom surface 39 of the cleaning tank 14. The pump 27 rotates the impeller 28 by a built-in electric motor. The pump 27 can rotate the impeller 28 in one direction and can also rotate in the opposite direction. A portion where the impeller 28 of the pump 27 is disposed and the suction recess 31 are communicated with each other by a suction flow path 32. An electric heater 30 is mounted above the bottom surface 39 of the cleaning tank 14.

A rotary nozzle 20 is rotatably attached to the bottom surface 39 of the cleaning tank 14. The rotary nozzle 20 and the first discharge port 11 of the pump 27 communicate with each other. Some of the plurality of injection ports formed in the rotary nozzle 20 cause the rotary nozzle 20 to generate a rotating moment when water is injected. The rotating nozzle 20 will be described in detail later.
A drain hose 34 is connected to the rear wall 33 of the main body 12. The drain hose 34 and the second discharge port 35 of the pump 27 are communicated with each other by a drain channel 36. The middle of the drainage flow path 36 and the inside of the cleaning tank 14 are communicated by an air vent path 37. A drainage check valve 38 is mounted in the vicinity of the portion of the drainage channel 36 connected to the drainage hose 34. The drainage check valve 38 prevents drainage from flowing backward from the drainage hose 34 to the drainage flow path 36.
A water supply hose 40 is connected to the horizontal portion of the rear wall 33 of the main body 12. The water supply hose 40 may be directly supplied with tap water (cold water) or may be supplied with hot water heated by a water heater.
A water supply valve 41 is attached to the inside of the rear wall 33. The water supply valve 41 is driven by a built-in solenoid to open and close. The inlet 44 of the water supply valve 41 and the water supply hose 40 are communicated with each other by a first water supply channel 42. The outlet 64 of the water supply valve 41 and the inside of the cleaning tank 14 are communicated with each other by the second water supply channel 43.

A water level detector 45 is provided at the lower portion outside the front portion of the cleaning tank 14. The water level detector 45 has a water level chamber 46, a float 47, a bar 48, and a switch 49. The water level chamber 46 communicates with the suction recess 31 by a water level path 50. The float 47 is disposed in the water level chamber 46. The bar 48 is fixed to the float 47 and protrudes upward from the water level chamber 46. The switch 49 is disposed above the bar 48.
A drying fan 52 is attached to the outside of the rear wall 51 of the cleaning tank 14. The drying fan 52 rotates the fan 53 with a built-in motor. The drying fan 52 and the cleaning tank 14 are communicated with each other through a drying path 63. The drying fan 52 is disposed higher than the water level 54 (hereinafter referred to as “normal water level”) when the cleaning water is normally supplied to the cleaning tank 14. Therefore, water can be prevented from entering the drying fan 52.
A thermistor 55 is mounted on the bottom surface 39 of the cleaning tank 14. The thermistor 55 detects the temperature of the water when the cleaning water and the rinsing water are put in the cleaning tank 14, and detects the air temperature when the cleaning water and the rinsing water are not put.
A recess 58 is formed in the bottom surface 57 of the main body 12. Two electrodes of the water leak sensor 59 are inserted into the recess 58. When water leaks from the cleaning tank 14 to the outside, and the leaked water flows into the recess 58, the electrodes are connected and the water leak sensor 59 is turned on.

A controller 60 is mounted in the door 15. The controller 60 includes a CPU, a ROM, a RAM, and the like, and controls the operation of the dishwasher 10. The controller 60 is connected to the operation panel 16, pump 27, heater 30, water supply valve 41, water level detector 45, drying fan 52, thermistor 55, and water leak sensor 59.
A seal lid 56 is disposed above the cleaning tank 14. The seal lid 56 is connected to the cleaning tank 14 by a lifting mechanism (not shown). In a state where the cleaning tank 14 is accommodated in the main body 12 (the state shown in FIGS. 1 and 3), the seal lid 56 is lowered to cover the upper opening of the cleaning tank 14. When the cleaning tank 14 is pulled out from the main body 12 (when the cleaning tank 14 is in the state shown in FIG. 2), the seal lid 56 rises to open the upper opening of the cleaning tank 14.

  The dishwasher 10 operates in the order of a cleaning process, a rinsing process, and a drying process. When the user turns on the operation start button provided on the operation panel 16, the cleaning process is started. In addition, before starting a washing | cleaning process, the detergent is thrown into the predetermined site | part of the tableware basket 61 by the user. In the cleaning process, the water supply valve 41 is first opened. When the water supply valve 41 is opened, tap water is supplied to the cleaning tank 14 through the water supply hose 40, the first water supply channel 42, and the second water supply channel 43. When the water is supplied, the water level of the cleaning water in the cleaning tank 14 rises. The washing water flows through the suction recess 31 and the water level path 50 and enters the water level chamber 46 of the water detector 45. As the cleaning water level rises, the water level in the water level chamber 46 also rises. When the water level in the water level chamber rises, the float 46 rises. As the float 46 floats, the bar 48 rises with it. When the bar 48 rises and the upper end contacts the switch 49, the water level detector 45 is turned on. When the water level detector 45 is turned on, the water supply valve 41 is closed, whereby the water supply to the cleaning tank 14 is completed. The water level (normal water level 54) when the water level detector 45 is turned on and the water supply to the cleaning tank 14 is finished is slightly higher than that of the heater 30.

When the water supply valve 41 is closed, the pump 27 is cleaned and the heater 30 is turned on. Here, the cleaning operation of the pump 27 means that the impeller 28 of the pump 27 rotates in one direction, sucks cleaning water from the suction recess 31 via the suction flow path 32, and the sucked cleaning water is used as a rotary nozzle. This means an operation state to be sent to the No. 20. As described above, the middle of the drainage flow path 36 communicates with the inside of the cleaning tank 14 by the air vent path 37. For this reason, when the pump 27 is performing a cleaning operation, air enters the drainage flow path 36. Further, a part of the drainage channel 36 is formed in an inverted U shape. For this reason, the pump 27 performing the cleaning operation is prevented from sucking the wastewater through the drainage flow path 36.
The washing water sent to the rotary nozzle 20 is ejected vigorously from the ejection port. The rotating nozzle 20 is rotated by a rotating moment generated by the ejection of the washing water while ejecting the cleaning water. The tableware 19 is washed by the washing water ejected from the ejection port. The washing water that has washed the tableware 19 is again sucked into the pump 27 from the suction recess 31. In this way, the wash water sucked into the pump 27 is jetted from the jet port of the rotary nozzle 20 and the circulation sucked into the pump 27 is repeated. The leftovers washed away from the tableware 19 are filtered out by the leftover filter 17.
When the heater 30 is turned on, the temperature of the cleaning water increases. The temperature of the washing water is detected by the thermistor 55. The heater 30 is ON / OFF controlled based on the temperature detected by the thermistor 55, and the washing water temperature is maintained within a predetermined range (for example, 45 to 60 ° C.).

  When a predetermined time (for example, 10 minutes) elapses after the cleaning water temperature is maintained within a predetermined range, the heater 30 is turned off and the pump 27 is drained. Here, the drainage operation of the pump 27 means that the impeller 28 of the pump 27 rotates in the other direction, so that the wash water is sucked from the suction recess 31 via the suction flow path 32, and the sucked wash water is discharged into the drainage flow. This means an operation state in which the fuel is discharged to the outside through the passage 36 and the drain hose 34. The drainage operation of the pump 27 ends when a predetermined time (for example, 40 seconds) elapses. The predetermined time is set as a time sufficient to drain all the cleaning water from the cleaning tank 14. When the drainage operation of the pump 27 is completed, air enters the drainage path 36 through the air vent path 37.

  In the rinsing process, the water supply valve 41 is opened and water is supplied to the cleaning tank 14. When water is supplied to the cleaning tank 14 and the water level detector 45 is turned on, the water supply valve 41 is closed, the pump 27 is operated for cleaning, and the heater 30 is turned on. When the pump 27 is washed, rinsing water is jetted from the jet nozzle of the rotary nozzle 20 and the tableware 19 is rinsed. The heater 30 that is turned on heats the rinse water to warm water. When a predetermined time (for example, 1 minute) elapses after the cleaning operation of the pump 27 is started, the pump 27 stops. Then, the rinsing water is drained from the cleaning tank 14 by performing the drainage operation of the pump 27. The rinsing process is repeated a predetermined number of times (for example, 5 times).

  In the drying process, the drying fan 52 is operated and the heater 30 is turned on. When the drying fan 52 is operated, external air is sent into the cleaning tank 14 via the drying path 63. The sent air passes through the cleaning tank 14 and is exhausted to the outside through the exhaust port 18. When the heater 30 is turned on, the air temperature in the cleaning tank 14 increases. While the outside air is fed into the cleaning tank 14 and the temperature in the cleaning tank 14 becomes high, the temperature-controlled drying of the tableware 19 is performed. When a predetermined time (for example, 25 minutes) elapses after the temperature-controlled drying of the tableware 19 is started, the heater 30 is turned off and air drying is performed. When a predetermined time (for example, 5 minutes) elapses after the air-drying of the tableware 19 is started, the operation of the fan 52 is stopped and the drying process is ended. A buzzer sounds, the completion of all processes is notified, and the power of the dishwasher 10 is turned off.

  The rotating nozzle 20 will be described. As shown in FIG. 4, the lower nozzle 22 of the tower nozzle portion 23 of the rotary nozzle 20 has a substantially cylindrical tube portion 22 a that is slightly narrowed upward, and an upper end surface portion 22 b at the upper end. A hole 22c is formed in the center of the upper end surface portion 22a. At the upper part of the lower nozzle 22, an injection port 22d is formed so as to straddle the cylindrical portion 22a and the upper end surface portion 22b. In addition, an injection port (22e: see FIGS. 5, 7, and 8) is formed in the upper portion of the cylindrical portion 22a of the lower nozzle 22.

  As shown in FIG. 6, the upper nozzle 21 of the tower nozzle portion 23 of the rotary nozzle 20 is slightly narrowed upward, and the upper end is closed. A flange portion 21 a is formed at the lower end of the upper nozzle 21. Five injection ports 21b, 21b,... (See FIGS. 7 and 8) are formed on the side surface of the upper nozzle 21.

  When the cleaning operation is started, the upper nozzle 21 of the tower nozzle portion 23 of the rotary nozzle 20 is pushed up by the water pressure of the cleaning water sent out by the pump 27. As shown in FIG. 7, the upper nozzle 21 is pushed up until the upper surface of the flange portion 21 a contacts the rear surface of the upper end surface portion 22 b of the lower nozzle 22. At this time, the position of the upper nozzle 21 is the highest. The washing water fed into the tower nozzle portion 23 is ejected in a substantially horizontal direction from the ejection ports 21b, 21b,... Formed in the upper nozzle 21 and the ejection ports 22d, 22e formed in the lower nozzle 22. . The injection port 22d of the lower nozzle 22 is formed so as to straddle the cylinder portion 22a and the upper end surface portion 22b, but the flange portion 21a of the upper nozzle 21 prevents the cleaning water from being injected upward.

  When the tableware 19 is accommodated in the tableware basket 61, the tableware 19 may be disposed so as to cover the tower nozzle portion 23. In this case, the upper end of the upper nozzle 21 of the tower nozzle portion 23 during the cleaning operation comes into contact with the tableware 19 covering the upper side, and the upper nozzle 21 may not be pushed up to the uppermost state shown in FIG. is there. As shown in FIG. 8, when the upper nozzle 21 is not pushed up until the flange portion 21 a of the upper nozzle 21 of the tower nozzle portion 23 comes into contact with the back surface of the upper end surface portion 22 b of the lower nozzle 22, the tower nozzle portion 23 is fed into the tower nozzle portion 23. The washed water is formed in the lower nozzle 22 and the jet nozzles 21b, 21b, 21b (three in FIG. 8) formed in the upper nozzle 21 protruding upward from the hole 22c of the lower nozzle 22. It ejects from the ejection ports 22d and 22e. Wash water is ejected substantially horizontally from the ejection ports 21b, 21b, 21b of the upper nozzle 21 and the ejection port 22e of the lower nozzle 22. Further, the cleaning water is jetted not only in the horizontal direction but also upward from the jet port 22d of the lower nozzle 22. Since the flange portion 21 a of the upper nozzle 21 is not in contact with the back surface of the upper end surface portion 22 b of the lower nozzle 22, the cleaning water sprayed from the injection port 22 d is not blocked by the flange portion 21 a of the upper nozzle 21. Water is also ejected upward from the ejection port 22d.

Since the upper nozzle 21 has a tapered shape, when the upper nozzle 21 is not pushed up to a position where the flange portion 21a of the upper nozzle 21 contacts the back surface of the upper end surface portion 22b of the lower nozzle 22, the side surface of the upper nozzle 21; A gap 26 is formed between the lower nozzle 22 and the hole 22c. If this gap 26 is large, the wash water sent into the tower nozzle portion 23 will escape from this gap, and the injection force from the injection ports 22d and 22e of the lower nozzle 22 will be weakened.
Although the upper nozzle 21 of the present embodiment has a tapered shape, the amount of change in diameter is slight, so the gap 26 formed between the side surface of the upper nozzle 21 and the hole 22c of the lower nozzle 22 is small. Accordingly, since the washing water does not escape from the gap 26 as the injection force from the injection ports 22d and 22e of the lower nozzle 22 is weakened, the injection ports 21b, 21b and 21b of the upper nozzle 21 and the lower nozzle The injection force from the 22 injection ports 22d and 22e can be ensured.

When the tableware 19 is arranged without covering the tower nozzle portion 23 of the rotary nozzle 20, there is no tableware to be cleaned above the tower nozzle portion 23. There is no need to spray the cleaning water upward from the injection port. On the other hand, when the tableware 19 is disposed so as to cover the tower nozzle portion 23 of the rotary nozzle 20, the tableware 19 is formed in the tower nozzle portion 23 to wash the tableware covering the tower nozzle portion 23. The cleaning water needs to be jetted upward from the jetting port.
In the dishwasher of the present embodiment, an injection port 22d is formed in the upper part of the lower nozzle 22 so as to straddle the cylindrical portion 22a and the upper end surface portion 22b. If the tableware 19 is not covered above the tower nozzle portion 23, the upper nozzle 21 is pushed up by the water pressure of the washing water until the flange portion 21a contacts the back surface of the upper end surface portion 22b of the lower nozzle 22. At this time, since the wash water is prevented from being jetted upward from the jet port 22d by the flange portion 21a, the wash water is jetted only in the horizontal direction from the jet port 22d. According to this configuration, when there is no tableware to be cleaned above the tower nozzle portion 23, the cleaning water is not jetted upward from the jet port 22d, so there is no wasteful jetting of washing water, and the washing water for that amount. In addition, since the jetting is performed in the horizontal direction from the jetting port 22d and the other jetting ports 21b, 21b, ..., 22e, the tableware 19 arranged around the rotary nozzle 20 can be washed well.
On the other hand, if the tableware 19 is covered above the tower nozzle part 23, even if the upper nozzle 21 is pushed up by the water pressure of the washing water, the upper nozzle 21 comes into contact with the tableware 19 at the upper end, and the flange It is not pushed up until the part 21a contacts the back surface of the upper end surface part 22b of the lower nozzle 22. At this time, since the flange portion 21a does not prevent the cleaning water from being jetted upward from the jet port 22d, the flush water is jetted upward from the jet port 22d. According to this configuration, when the tableware is covered above the tower nozzle portion 23, the cleaning water is jetted upward from the injection port 22d, so that the tableware covered by the tower nozzle portion 23 is washed well. can do. In addition, since the cleaning water is sprayed from the upper side in the horizontal direction from the jet port 22d and is jetted in the horizontal direction from the other jet ports 21b, 21b, ..., 22e, it is arranged around the rotary nozzle 20. The tableware 19 that has been used can also be cleaned well.

(Example 2)
A second embodiment embodying the dishwasher 10 of the present invention will be described with reference to the drawings. The configuration of the dishwasher of the present embodiment is similar to the configuration of the dishwasher of the first embodiment, but the shape of the tower nozzle portion of the rotary nozzle disposed in the cleaning tank 14 is the same as that of the present embodiment. And the first embodiment is different. Therefore, here, the difference between the present embodiment and the first embodiment will be mainly described, and the description of the common portions will be omitted. Moreover, the same code | symbol is used about the site | part which is common in a present Example and 1st Example.

As shown in FIG. 9, the upper nozzle 121 of the tower nozzle portion (123: see FIG. 10) of the rotating nozzle is slightly narrowed upward, and the upper end is closed. A flange portion 121 a is formed at the lower end of the upper nozzle 121. Four injection ports 121b, 121b,... (See FIGS. 10 and 11) are formed on the side surface of the upper nozzle 121.
On the side surface of the upper nozzle 121, six vertical ribs 121c, 121c,... Extending in the vertical direction are formed. Each of the six vertical ribs 121c, 121c,... Has a slightly longer protruding length from the side surface toward the upper side. The outer diameter of the upper nozzle 121 formed by the protruding ends of the six vertical ribs 121c, 121c,... Is from the upper end to the lower end of the portion where the vertical ribs 121c, 121c,. .., And is substantially the same as the outer shape of the lower part of the upper nozzle 121 where the vertical ribs 121c, 121c,... Are not formed.
Further, on the side surface of the upper nozzle 121, three horizontal ribs 121d, 121e, and 121f that extend in the horizontal direction and make a round around the side surface of the upper nozzle 121 are formed. The lateral ribs 121d, 121e, and 121f are formed at equal intervals in order from the top on the upper side surface of the upper nozzle 121. The protruding lengths of the three lateral ribs 121d, 121e, and 121f are slightly different from each other, and are slightly larger in the order of the lower lateral rib 121f, the intermediate lateral rib 121e, and the upper lateral rib 121d. The outer diameters of the upper nozzles 121 formed by the protruding ends of the respective lateral ribs 121d, 121e, and 121f are all the same, and are substantially equal to the outer shape of the lower part of the upper nozzle 121.
The vertical ribs 121c, 121c,... And the horizontal ribs 121d, 121e, 121f are all formed at locations that do not hinder the injection of cleaning water from the injection ports 121b, 121b,.

  When the cleaning operation is started, the upper nozzle 121 of the tower nozzle portion 123 of the rotary nozzle is pushed up by the water pressure of the cleaning water sent out by the pump 27. As shown in FIG. 10, the upper nozzle 121 is pushed up until the upper surface of the flange portion 121 a contacts the rear surface of the upper end surface portion 22 b of the lower nozzle 22. The washing water fed into the tower nozzle portion 123 is ejected in a substantially horizontal direction from the ejection ports 121b, 121b,... Formed in the upper nozzle 121 and the ejection ports 22d, 22e formed in the lower nozzle 22. . The injection port 22d of the lower nozzle 22 is formed so as to straddle the cylinder portion 22a and the upper end surface portion 22b, but the flange portion 121a of the upper nozzle 121 prevents the cleaning water from being injected upward.

  When the tableware 19 is accommodated in the tableware basket 61, the tableware 19 is arranged so as to cover the tower nozzle portion 123, and the upper end of the upper nozzle 121 of the tower nozzle portion 123 during the cleaning operation is covered upward. The upper nozzle 121 may not be pushed up to the uppermost state shown in FIG. As shown in FIG. 11, when the upper nozzle 121 is not pushed up until the flange 121a of the upper nozzle 121 of the tower nozzle 123 abuts the back surface of the upper end surface 22b of the lower nozzle 22, it is fed into the tower nozzle 123. The washing water thus formed is formed in the lower nozzle 22 and the jet nozzles 121b, 121b, 121b (three in FIG. 10) formed in the upper nozzle 121 in the portion protruding upward from the hole 22c of the lower nozzle 22. It ejects from the ejection ports 22d and 22e. The washing water is ejected substantially horizontally from the ejection ports 121b, 121b, 121b of the upper nozzle 121 and the ejection port 22e of the lower nozzle 22. Further, the cleaning water is jetted not only in the horizontal direction but also upward from the jet port 22d of the lower nozzle 22. Since the flange portion 121a of the upper nozzle 121 is not in contact with the back surface of the upper end surface portion 22b of the lower nozzle 22, the cleaning water sprayed from the injection port 22d is not blocked by the flange portion 121a of the upper nozzle 121. Water is also ejected upward from the ejection port 22d.

Since the upper nozzle 121 has a tapered shape, when the upper nozzle 121 is not pushed up to a position where the flange portion 121a of the upper nozzle 121 contacts the back surface of the upper end surface portion 22b of the lower nozzle 22, the side surface of the upper nozzle 121, A gap 126 is formed between the lower nozzle 22 and the hole 22c. If this gap 126 is large, the wash water sent into the tower nozzle portion 123 will escape from this gap, and the injection force from the injection ports 22d and 22e of the lower nozzle 22 will be weakened.
Although the upper nozzle 121 of the present embodiment has a tapered shape, the amount of change in diameter is slight, and therefore the gap 126 formed between the side surface of the upper nozzle 121 and the hole 22c of the lower nozzle 22 is small. Further, on the side surface of the upper nozzle 21, vertical ribs 121c, 121c,... And horizontal ribs 121d, 121e, 121f are formed. The gap 126 is further reduced by the vertical ribs 121c, 121c,. Further, the lateral ribs 121d, 121e, 121f prevent the cleaning water from coming out of the gap 126. Further, when any one of the lateral ribs 121d, 121e, 121f is aligned with the position of the hole 22c of the lower nozzle 22, the gap 126 is not formed. Since the vertical ribs 121c, 121c,... And the horizontal ribs 121d, 121e, 121f can prevent the cleaning water from escaping from the gap 126, the injection ports 121b, 121b, 121b of the upper nozzle 121 The injection force from the injection ports 22d and 22e of the lower nozzle 22 can be ensured.

When the tableware 19 is arranged without covering the tower nozzle portion 123 of the rotating nozzle, since there is no tableware to be cleaned above the tower nozzle portion 123, the tableware 19 is formed in the tower nozzle portion 123. It is not necessary to inject cleaning water upward from the injection port. On the other hand, when the tableware 19 is placed over the tower nozzle portion 123 of the rotary nozzle, the tableware 19 is formed in the tower nozzle portion 123 to wash the tableware over the tower nozzle portion 123. It is necessary to spray the cleaning water upward from the injection port.
In the dishwasher of the present embodiment, an injection port 22d is formed in the upper part of the lower nozzle 22 so as to straddle the cylindrical portion 22a and the upper end surface portion 22b. If the tableware 19 is not covered above the tower nozzle portion 23, the upper nozzle 121 is pushed up by the water pressure of the washing water until the flange portion 121 a comes into contact with the back surface of the upper end surface portion 22 b of the lower nozzle 22. At this time, since the wash water is prevented from being jetted upward from the jet port 22d by the flange portion 121a, the wash water is jetted only in the horizontal direction from the jet port 22d. According to this configuration, when there is no tableware to be cleaned above the tower nozzle portion 23, the cleaning water is not jetted upward from the jet port 22d, so there is no wasteful jetting of washing water, and the washing water for that amount. In addition, since the jetting is performed in the horizontal direction from the jetting port 22d and the other jetting ports 121b, 121b,..., 22e, the tableware 19 arranged around the rotating nozzle can be washed well.
On the other hand, when the tableware 19 is covered above the tower nozzle portion 23, even if the upper nozzle 121 is pushed up by the water pressure of the washing water, the upper nozzle 121 comes into contact with the tableware 19 at the upper end, and the flange It is not pushed up until the part 121a contacts the back surface of the upper end surface part 22b of the lower nozzle 22. At this time, since the flange portion 121a does not prevent the cleaning water from being jetted upward from the jet port 22d, the wash water is jetted upward from the jet port 22d. According to this configuration, when the tableware is covered above the tower nozzle portion 23, the cleaning water is jetted upward from the injection port 22d, so that the tableware covered by the tower nozzle portion 23 is washed well. can do. In addition, the cleaning water is jetted from the upper side in the horizontal direction from the jet port 22d, and is jetted in the horizontal direction from the other jet ports 121b, 121b,. The tableware 19 can be cleaned well.

If there is no tableware covered by the tower nozzle part, it is not necessary to spray the washing water above the tower nozzle part, and it is better to direct the washing water amount in the direction that contributes to washing. If there is tableware covered in the tower nozzle part, it is necessary to wash by spraying washing water above the tower nozzle part.
In the dishwasher according to the present invention, a washing water injection port is formed on the upper end surface of the lower nozzle, and this injection port is formed at the lower end of the upper nozzle when the upper nozzle of the tower nozzle portion is pushed up to the highest position. When the upper nozzle of the tower nozzle part is not pushed up to the highest position and is pushed up only halfway, it is blocked by the flange part at the lower end of the upper nozzle. .
According to this configuration, when there is no tableware above the tower nozzle part, the upper nozzle is pushed up to the highest position, and the flange part of the upper nozzle closes the injection port on the upper end surface of the lower nozzle, so that the washing water is jetted upward. To be suppressed. On the other hand, when the tableware is covered over the tower nozzle, the upper end of the upper nozzle contacts the tableware, the upper nozzle is pushed up only halfway, and the upper nozzle flange is the upper surface of the lower nozzle. Since the injection port is not blocked, cleaning water is injected upward. From this, when there is no tableware covered in the tower nozzle part, since the washing water is not jetted upward from the jet port on the upper end surface of the lower nozzle, the wasteful jet is suppressed and the direction to contribute to washing is reduced. Can be directed to the amount of washing water. Only when there is tableware covered in the tower nozzle part, the wash water is sprayed upward from the injection port on the upper end surface of the lower nozzle, so that the tableware covered in the tower nozzle part can be washed well. it can.

  The tower nozzle portion 23 of the first embodiment and the tower nozzle portion 123 of the second embodiment have no tableware 19 covering the tower nozzle portions 23, 123, and the upper nozzles 21, 121 are pushed up to the top. During the cleaning operation, the upper ends of the upper nozzles 21 and 121 rotate with the rotation of the rotary nozzle. The turning effect of the upper nozzles 21 and 121 tends to be enhanced. Therefore, as shown in FIG. 12, by making the shoulder portions of the flange portions 21a and 121a more rounded, the upper nozzles 21 and 121 can be turned more smoothly and the durability of the tower nozzle portions 23 and 123 is increased. be able to.

  Both the upper nozzle 21 of the first embodiment and the upper nozzle 121 of the second embodiment are slightly tapered. However, the upper nozzle of the present invention may be cylindrical. In the case of the cylindrical shape, no gaps 26 and 126 are formed between the side surfaces of the upper nozzles 21 and 121 and the holes 22c of the lower nozzle 22 regardless of the positions where the upper nozzles 21 and 121 are pushed up. . Therefore, even when the tableware 19 has been covered above the tower nozzle portions 23 and 123, the wash water sent into the tower nozzle portions 23 and 123 will escape from the gaps 26 and 126. Therefore, it is possible to secure the injection force from the injection ports 22d and 22e of the lower nozzle 22 and to clean the tableware 19 covered above the tower nozzle portions 23 and 123 satisfactorily. There is no need to form the vertical ribs 121c, 121c,... And the horizontal ribs 121d, 121e, 121f as in the second embodiment.

  The lower nozzle 22 of the first embodiment and the lower nozzle 22 of the second embodiment are members common to the two embodiments, and as an injection port for injecting cleaning water upward from the upper end surface portion 22b, FIG. 22d is formed. The shape and number of the injection ports for injecting the cleaning water upward from the upper end surface portion 22b of the lower nozzle 22 are not limited to this, and for example, those shown in FIGS. 13 to 16 may be used. The injection port 22p shown in FIG. 13 is formed so as to straddle the cylindrical portion 22a and the upper end surface portion 22b, and is further coupled to the hole 22c of the lower nozzle 22. The injection port 22q shown in FIG. 14 does not straddle the cylinder part 22a, but is formed in the upper end surface part 22b. The injection port 22r shown in FIG. 15 does not straddle the cylindrical portion 22a, is formed in the upper end surface portion 22b, and is further coupled to the hole 22c of the lower nozzle 22. As described above, as long as the injection port is opened in the upper end surface portion 22b, the injection port may or may not straddle the cylindrical portion 22a and may or may not be coupled to the hole 22c. Further, although the number of the injection ports 22r shown in FIG. 15 is four, the number of the injection ports may be any number as long as the injection force of the cleaning water can be maintained. Further, the shape of the injection port is not limited to a substantially rectangular shape such as the injection port 22r, but may be a semicircular shape such as the injection port 22s shown in FIG. 16, or other shapes. May be.

  In the tower nozzle portion 123 of the second embodiment, vertical ribs 121c, 121c,... Are formed on the side surface of the upper nozzle 121, and a gap 126 formed between the side surface of the upper nozzle 121 and the hole 22c of the lower nozzle 22 is formed. Are closed by the vertical ribs 121c, 121c,... At this time, the gap 126 functions as an ejection port for ejecting the washing water vigorously. That is, an injection port is formed in a part of the hole 22c of the lower nozzle 22, and the same action as the injection port 22r of FIG. 15 and the injection port 22s of FIG. 16 is obtained.

Specific examples of the present invention have been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.
In addition, the technical elements described in the present specification or drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology illustrated in the present specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.

The perspective view of the dishwasher which concerns on 1st Example. The perspective view in the state where the washing tub was pulled out from the main part of the dishwasher concerning a 1st example. The typical side view of the dishwasher which concerns on 1st Example. The perspective view of the lower stage nozzle which concerns on 1st Example. The top view of the lower stage nozzle which concerns on 1st Example. The perspective view of the upper stage nozzle which concerns on 1st Example. The longitudinal section of the tower nozzle part concerning the 1st example (at the time of extension). The longitudinal section of the tower nozzle part concerning the 1st example (at the time of non-extension). The perspective view of the upper stage nozzle which concerns on 2nd Example. The longitudinal cross-sectional view (at the time of expansion | extension) of the tower nozzle part which concerns on 2nd Example. The longitudinal section of the tower nozzle part concerning the 2nd example (at the time of non-extension). The longitudinal cross-sectional view of the modification of an upper stage nozzle. The top view (1) of the modification of a lower stage nozzle. The top view (2) of the modification of a lower stage nozzle. The top view (3) of the modification of a lower stage nozzle. The top view (4) of the modification of a lower stage nozzle.

Explanation of symbols

10: Tableware washing machine 14: Washing tank 19: Tableware 20: Rotating nozzle 21: Upper nozzle, 21a: Flange portion, 21b: Injection port 22: Lower nozzle, 22a: Tube portion, 22b: Upper end surface portion, 22c: Hole, 22d : Jet port, 22e: jet port, 22p: jet port, 22q: jet port, 22r: jet port, 22s: jet port 23: tower nozzle part 24: horizontal nozzle part 25: jet hole 26: gap 27: pump 121: Upper nozzle, 121a: flange portion, 121b: injection port, 121c: vertical rib, 121d: horizontal rib, 121e: horizontal rib, 121f: horizontal rib 123: tower nozzle portion

Claims (2)

A dishwasher that sprays wash water on the tableware,
A washing tank for storing tableware;
Within the cleaning tank has been placed, along with and a tower nozzle, a nozzle for injecting the cleaning water,
It has a cleaning pump that sends cleaning water to the nozzle,
The tower nozzle includes a lower nozzle and an upper nozzle that is arranged inside the lower nozzle and rises due to the water pressure of the washing water sent from the washing pump,
The lower nozzle has, on its upper end surface, an opening through which the upper end nozzle enters and exits, and an injection port through which cleaning water is injected upward,
The upper nozzle has a flange having a larger diameter than the opening at its lower end,
Closing the injection port the flange and the upper nozzle rises comes into contact with the upper end surface of the lower nozzle,
When the upper nozzle is lowered from the uppermost position, the flange is separated from the upper end surface of the lower nozzle and the injection port is opened . The tower nozzle is rotatably arranged in the cleaning tank,
The shoulder of the flange is chamfered;
2. The dishwasher according to claim 1, wherein when the upper nozzle rises, the upper end of the upper nozzle turns as the nozzle rotates.

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