JP2011021510A - Pump - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the fluid flowing backward out of an exhaust port into a pump chamber from remaining in the pump chamber or flowing into a suction port. <P>SOLUTION: The pump includes a casing 51 with a pump chamber 52 therein, a suction port 53a for introducing a fluid into the pump chamber 52, and exhaust ports 54a, 55a for discharging the fluid from the pump chamber 52; and an impeller disposed in the pump chamber 52 rotatably around the rotary shaft. Walls 59, 60 are provided at a position on an extension line from the exhaust ports 54a, 55a on the downstream side of the impeller in the pump chamber for preventing the backward flow of the fluid from the exhaust ports 54a, 55a to the suction port 53a. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a pump for conveying a fluid.

  Conventionally, as a pump for conveying a fluid, for example, as disclosed in Japanese Patent Application Laid-Open No. 2006-220034, a fluid is introduced into a pump chamber formed inside a casing via a suction port, and the pump chamber There is known a configuration in which a fluid is discharged through a discharge port by an impeller that rotates in the above.

The pump is provided with two discharge ports, and one of the discharge ports is provided with a switching valve capable of switching the opening and closing of the discharge port according to the fluid flow direction due to the rotation of the impeller. It has been. Therefore, the fluid in the pump chamber can be discharged from one of the two discharge ports by switching the rotation direction of the impeller and opening and closing the switching valve with respect to the discharge port.
JP 2006-220034 A

  By the way, in the above configuration, when the rotation of the impeller in the pump chamber is stopped after the fluid is discharged from the discharge port, the fluid discharged from the discharge port may flow backward into the pump chamber. That is, when the impeller is stopped, the fluid remaining in the discharge pipe connected to the discharge port may flow backward to the pump chamber through the discharge port and flow into the suction port side. In this case, for example, in the case of a dishwasher, the fluid may flow back to the inside of the washing room of the dishwasher and remain in the washing room.

  An object of the present invention is to provide a pump that can prevent fluid that has flowed back from a discharge port into the pump chamber from remaining in the pump chamber or flowing into the suction port.

  The pump of the present invention includes a casing having a pump chamber therein, a suction port for introducing fluid into the pump chamber, and a discharge port for discharging fluid from the pump chamber, and the pump chamber And an impeller disposed rotatably about the rotation axis, and at a position on the extension line of the discharge port on the downstream side in the fluid flow direction from the impeller in the pump chamber. It is assumed that a wall portion for preventing a back flow of fluid from the outlet to the suction port is provided.

  According to the above configuration, the wall that is provided downstream of the impeller in the fluid flow direction prevents the fluid that has flowed back from the discharge port into the pump chamber from flowing backward to the upstream side of the wall. Is done. That is, the wall portion can prevent the fluid from flowing back to the suction port side of the pump chamber. In addition, since the wall portion is located on the extension line of the discharge port, the flow of the fluid flowing back from the discharge port into the pump chamber can be received by the wall portion, and the back flow of the fluid is effectively prevented. Can be suppressed.

  According to the present invention, it is possible to prevent the fluid flowing backward from the discharge port into the pump chamber from flowing into the suction port and remaining in the pump chamber as it is or flowing into the suction port.

FIG. 1 is a diagram showing a schematic configuration of a dishwasher equipped with a pump according to an embodiment of the present invention. FIG. 2 is a perspective view showing the appearance of the pump according to the embodiment of the present invention. 3 is a cross-sectional view taken along line III-III in FIG. FIG. 4 is a perspective view showing the configuration of the pump casing in FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, its application, or its use.

-Overall configuration of the dishwasher-
FIG. 1 shows a schematic configuration of a dishwasher 1 equipped with a pump 20 according to the present embodiment. This dishwasher 1 sprays washing water from the washing nozzle 3 on the tableware D and the like in a state where the tableware D and the like are arranged in a washing chamber 2a formed inside the main body casing 2, whereby the tableware D It is configured to remove dirt adhering to the like. Specifically, the dishwasher 1 includes a box-shaped main body casing 2 in which a cleaning chamber 2a is formed, and a plurality of injection ports 3a, 3a,... Disposed in the cleaning chamber 2a. A cleaning nozzle 3, a rack 4 for holding tableware D and the like in the cleaning chamber 2a, a water tank 5 for storing water sprayed from the spray port 3a, and water in the water tank 5 for the cleaning nozzle And the pump 20 for supplying to the three injection ports 3a, 3a,.

  The main casing 2 is formed in a box shape having a cavity inside, and a door that can be opened and closed is provided on at least one surface, although not shown. The interior of the main casing 2 includes a cleaning chamber 2a for cleaning tableware D and the like, a machine chamber 2b in which a pump 20 for conveying water in the water tank 5 to the cleaning nozzle 3 or the drain pipe 6 is housed, It is divided into. In the cleaning chamber 2a, the cleaning nozzle 3 and the rack 4 are accommodated, and a drying fan 7 for drying the tableware after cleaning is disposed. In the machine room 2b, the pump 20 is housed, and a control unit 8 for controlling the operation of the dishwasher 1 is disposed.

  The cleaning nozzle 3 is formed in a substantially T shape so as to extend in the vertical direction in the main body casing 2. In the arm portion extending in the lateral direction of the cleaning nozzle 3, a plurality of injection ports 3a, 3a,... Opening downward are formed at regular intervals in the lateral direction. A portion extending in the vertical direction of the cleaning nozzle 3 is constituted by a supply pipe 3b for supplying water to the arm portion, and is connected to the discharge portion 55 of the pump 20 at the lower end portion. Thereby, the water discharged from the pump 20 is supplied to the arm portion of the cleaning nozzle 3 through the supply pipe 3b and is injected from the injection ports 3a, 3a,.

  The rack 4 can hold a plurality of tableware D and the like, and is formed of a net-like member so that the cleaning water flows down below the cleaning chamber 2a. The rack 4 is disposed on a table 11 provided so as to partition the inside of the main casing 2 into the cleaning chamber 2a and the machine chamber 2b. In addition, the rack 4 includes a holding portion (not shown) so that a plurality of tableware D can be held upright as shown in FIG.

  The water tank 5 is formed in a box shape whose upper surface is open, and is disposed on the bottom surface of the main casing 2. Around the opening portion of the water tank 5, an introduction wall 5a connected to the opening portion is formed so that the cleaning water sprayed from the spray port 3a of the cleaning nozzle 3 can be efficiently collected. The water tank 5 is connected to a water supply pipe 9 for supplying tap water. Furthermore, the water tank 5 is also connected to the other end of the introduction pipe 10 whose one end is connected to the suction portion 53 of the pump 20.

-Pump configuration-
The configuration of the pump 20 will be described in detail below with reference to FIGS.

  As shown in FIG. 2 and FIG. 3, the pump 20 supplies water to two discharge ports 54 a, by a motor unit 21 having a stator 23 and a rotor 30, and an impeller 33 that rotates integrally with the rotor 30. And a pump unit 50 configured to discharge to either one of 55a. That is, the pump 20 rotates the rotor 30 by the motor unit 21 to rotate the impeller 33 in the pump unit 50, so that the water in the water tank 5 of the dishwasher 1 enters the pump unit 50. It is configured to take in and discharge from the discharge ports 54a and 55a. The pump 20 is installed in the dishwasher 1 such that the motor unit 21 is located on the top side of the dishwasher 1 and the pump unit 50 is located on the bottom side of the dishwasher 1.

  The motor unit 21 includes a motor casing 22 attached to the upper side of the pump unit 50, and a rotor 30 accommodated in the motor casing 22. The motor casing 22 is formed by sealing a substantially cylindrical stator 23 and a circuit board 24 with a sealing resin 25. For this reason, the motor casing 22 as a whole is formed in a bottomed cylindrical shape in which the upper end side of the cylinder is closed.

  Further, the motor casing 22 is formed such that its inner periphery can fit a substantially cylindrical bulging portion 41 of a cover 40 that covers an opening portion of the pump portion 50 described later. The cover 40 includes the bulging portion 41 and a flat plate portion 43 that covers an opening portion of the pump casing 51 (casing). Therefore, the cover 40 partitions the space including the rotor 30 and the pump 50 and the motor casing 22 so that water in the pump unit 50 does not enter the motor casing 22. Further, the bulging portion 41 of the cover 40 is integrally formed with a protruding portion 42 that protrudes inward (downward in FIG. 3) along the rotation axis P of the rotor 30 described later on the inner surface of the protruding end portion. Has been. A hole 42a is formed in the center of the protruding portion 42 in the bottom view of the protruding end portion, and the upper end side of the fixed shaft 34 that rotatably supports the rotor 30 is fitted in the hole 42a. ing.

  The cover 40 has a flat plate portion 43 fixed to the pump casing 51 by screws 44. The motor casing 22 is also fixed to the cover 40 and the pump casing 51 by screws 44.

  The rotor 30 is formed in a substantially cylindrical shape as a whole by disposing a magnet 32 on the outer peripheral surface of a substantially cylindrical rotating member 31. The rotating member 31 is provided with an upper enlarged hole portion 31a on the upper side in the axial direction and having an inner diameter that is larger than the central portion in the axial direction and gradually expands toward the upper end side. Also on the side, a lower enlarged hole portion 31b whose inner diameter expands stepwise from the axial central portion is formed. In the rotor 30, the protruding portion 42 of the cover 40 is positioned in the upper enlarged hole portion 31a, and the tip portion of the support portion 58 of the pump unit 50 described later is positioned in the lower enlarged hole portion 31b. Further, the cover 40 is disposed in the bulging portion 41 of the cover 40.

  In addition, a substantially cylindrical bearing 37 that slides with respect to the fixed shaft 34 is disposed inside the central portion in the axial direction of the rotating member 31. Further, sliding plates that fit on the fixed shaft 34 and slide relative to the rotating member 31 and the bearing 37 are respectively provided on the bottom surfaces of the upper enlarged hole portion 31a and the lower enlarged hole portion 31b of the rotating member 31. 35 and 36 are provided. By providing the sliding plates 35 and 36, the rotating member 31 and the bearing 37 can be smoothly slid relative to the protruding portion 42 of the cover 40 and the support portion 58 of the pump portion 50. With the above configuration, the rotating member 31 can rotate with respect to the fixed shaft 31 and the cover 40.

  The rotating member 31 is configured to hold the magnet 32 at an axial position corresponding to the stator 23. That is, the rotating member 31 is formed with a flange portion 31c at a predetermined position in the axial direction so that the magnet 32 can be held at a position on the outer peripheral surface corresponding to the stator 23. Specifically, the flange 31a is formed to have a protruding width that is substantially flush with the outer peripheral surface of the magnet 32 in a state where the magnet 32 is disposed on the outer peripheral side of the rotating member 31. Yes.

  An impeller 33 that constitutes a part of the pump unit 50 is integrally formed with the rotating member 31 below the rotating member 31. The impeller 33 includes a plurality of blades 33a, 33a,... Arranged radially so as to surround the lower enlarged hole portion 31b of the rotating member 31. That is, a plurality of blades 33 a, 33 a,... Are integrally formed on the rotating member 31 on the lower surface of the rotating member 31.

  The pump unit 50 includes the impeller 33 and a pump casing 51 for housing the impeller 33. As shown in FIG. 4, the pump casing 51 has a substantially trapezoidal shape in a plan view and is formed in a box shape having an open upper surface. The impeller 33 is accommodated inside the pump casing 51. A pump chamber 52 is formed.

  The pump casing 51 is provided with a suction portion 53 having a suction port 53 a communicating with the pump chamber 52 and discharge portions 54 and 55 having two discharge ports 54 a and 55 a communicating with the pump chamber 52. ing. The suction portion 53 is provided at a position near the impeller 33 in the pump chamber 52 in the pump casing 51. One of the discharge parts 54 and 55 is provided on the opposite side of the pump casing 51 from the suction part 53. The other discharge portion 55 is located in the vicinity of the discharge portion 54 of the pump casing 51 at a position where the discharge port 55a forms an angle of approximately 90 degrees with respect to the communication portion of the discharge port 54a with the pump chamber 52. It is provided so as to communicate with the chamber 52.

  The suction port 53 a of the suction portion 53 communicates with a suction passage 57 formed in the side wall of the pump casing 51 and in a base portion 56 described later, and communicates with the pump chamber 52 through the suction passage 57. is doing. The suction part 53 is connected to the introduction pipe 10 shown in FIG. Thereby, the water in the water tank 5 is introduced into the pump chamber 52 in the pump casing 51 through the introduction pipe 10.

  A discharge port 54a of the discharge portion 54 communicates with a discharge passage 51a formed in a side wall of the pump casing 51, and communicates with the pump chamber 52 through the discharge passage 51a. Further, the discharge part 54 is connected to a drain pipe 6 for draining to the outside of the dishwasher 1. Thereby, it becomes possible to drain the water in the pump chamber 52 to the outside of the dishwasher 1 through the discharge part 54.

  A discharge port 55a of the discharge portion 55 communicates with a reflux passage 51b formed in a side wall of the pump casing 51, and communicates with the pump chamber 52 through the reflux passage 51b. The discharge part 55 is connected to a supply pipe 3 b for supplying water to the arm part of the cleaning nozzle 3. Thereby, the water in the pump chamber 52 can be supplied to the injection port 3a of the cleaning nozzle 3 through the discharge part 55.

  The pump chamber 52 includes a substantially cylindrical impeller accommodating portion 52a for accommodating the impeller 33, and two discharge hole ports 54a and 55a from the impeller accommodating portion 52a with respect to the impeller accommodating portion 52a. And a switching valve accommodating portion 52b (rotating space portion) connected via two passage portions 52c and 52d extending toward the front. A switching valve 65 described later is accommodated in the switching valve accommodating portion 52b. In the pump chamber 52, a substantially cylindrical base portion 56 having an outer diameter substantially the same as the outer diameter of the impeller 33 is provided integrally with the pump casing 51 so as to extend upward from the bottom surface of the pump chamber 52. Thus, the space above the base portion 56 constitutes the impeller accommodating portion 52a. Thereby, the impeller accommodating portion 52a is formed above the switching chamber accommodating portion 52b in the pump chamber 52. The two passage portions 52c and 52d are formed on inclined portions 59 and 60 described later that smoothly connect the impeller housing portion 52a and the switching valve housing portion 52b.

  As shown in FIG. 2, the base portion 56 is formed such that the upper surface 56b thereof is higher than the uppermost point 54b of the inlet-side opening edge when viewed from the outlet side of the discharge port 54a. Further, the base portion 56 is formed with an outer wall 56a facing the switching valve accommodating portion 52b and the passage portions 52c and 52d. As a result, as will be described later, even when water flows backward from the discharge port 54a into the pump chamber 52, the water flow can be blocked by the outer wall 56a of the base portion 56. This reverse flow of water is also blocked by the inclined portions 59 and 60. That is, the outer wall 56a and the inclined portions 59, 60 constitute a wall portion of the present invention.

  Further, the base portion 56 is formed with a suction passage 57 communicating with the suction port 53a of the suction portion 53 so as to open to an inner peripheral surface as an inner side wall thereof. Thereby, water can be introduced into the pump chamber 52 from the suction port 53 a of the suction part 53 through the suction passage 57. The suction passage 57 is formed such that the lowest point 53b of the opening edge on the side opening inward of the base portion 53a is higher than the bottom surface 56c inside the base portion 53a. Thereby, after flowing back into the pump chamber 52, it is possible to suppress the water flowing into the base portion 53 a from flowing into the suction passage 57.

  In addition, a columnar support portion 58 having an insertion hole 58a formed at the distal end portion is provided inside the base portion 56. The support portion 58 is provided so as to be concentric with the substantially cylindrical base portion 56, and the insertion hole 58a is formed to have a size such that the distal end portion of the fixed shaft 34 is inserted. ing. Thereby, the rotor 30 having the impeller 33 is rotatably supported by the support portion 58 from below.

  The switching valve accommodating portion 52b communicates with the discharge ports 54a and 55a of the discharge portions 54 and 55 through the discharge passage 51a and the circulation passage 51b. Further, a switching valve 65 for switching opening / closing of the discharge port 54a is accommodated in the switching valve accommodating portion 52b. This switching valve 65 is supported so as to be rotatable about a support shaft (not shown), and receives a pressing force acting on the discharge port 54a side by a spring (not shown) in the direction of water flow in the pump chamber 52. Accordingly, when either one of the discharge ports 54a and 55a is open, the other is closed. Since the configuration of the switching valve 65 is the same as that conventionally used for a dishwasher pump or the like, a detailed description thereof will be omitted. In addition, since the switching valve 65 as described above is rotatably disposed in the switching valve housing portion 52b, the switching valve housing portion 52b is formed in a substantially fan shape in plan view.

  Thus, since the switching valve accommodating portion 52b communicates with the discharge ports 54a and 55a, when the pump 20 stops driving, that is, when the rotation of the impeller 33 stops, the discharge ports 54a and 55a There is a possibility that the discharged water flows back into the switching valve accommodating portion 52b. That is, while the pump 20 is being driven, the switching valve 65 is pressed toward the discharge port 54a by the pressing force due to the water flow in the pump chamber 52 and the pressing force due to the spring. When is stopped, the pressing force due to the water flow in the pump chamber 52 disappears, and the discharge port 54a is opened when the force due to the reverse flow of the discharged water is greater than the pressing force of the spring. When the water that has flowed back into the switching valve accommodating portion 52b flows into the water tank 5 from the suction port 53a through the introduction pipe 10, water remains in the main body casing 2 of the dishwasher 1, which is also sanitary. It is also not aesthetically pleasing. In addition, it is not preferable for the same reason that water does not reach the water tank 5 but accumulates in the pump chamber 52.

  On the other hand, as described above, the suction passage 57 is formed in the substantially cylindrical base portion 56, and the suction passage 57 is opened on the inner wall of the base portion 56. It is possible to prevent water that has flowed back into the switching valve accommodating portion 52b from the discharge ports 54a and 55a from flowing into the suction passage 57. That is, since the outer wall 56a of the base portion 56 constitutes the wall portion of the switching valve housing portion 52b, the water flowing into the switching valve housing portion 52b from the discharge ports 54a and 55a It is blocked by the outer side wall 56a and is prevented from flowing into the suction passage 57 side. Thereby, after the drive of the pump 20 is stopped, water flows into the base portion 53a and remains in the pump chamber 52, or the water flows back into the main body casing 2 of the dishwasher 1 through the suction passage 57. Can be prevented.

  The switching valve accommodating portion 52b is connected to the impeller accommodating portion 52a through two passage portions 52c and 52d. These passage portions 52c and 52d are switched so as to draw an arc along the outer wall 56a of the substantially cylindrical base portion 56 from a position facing each other across the support portion 58 of the base portion 56 in plan view. It is formed by inclined portions 59 and 60 extending to the bottom surface of the valve accommodating portion 52b. That is, these inclined portions 59 and 60 are provided such that one inclined portion 59 extends toward the discharge passage 51a and the other inclined portion 60 extends toward the reflux passage 51b. It has been.

  The inclined portions 59 and 60 are provided so as to be adjacent to the inside of the side wall of the pump casing 51. Thereby, the inner side of the side wall of the pump casing 51 constitutes the side wall of the inclined portions 59 and 60. The inclined portions 59 and 60 are provided so as to smoothly connect the upper surface of the base portion 56 and the bottom surface of the switching valve accommodating portion 52b without causing a step.

  Thus, by providing the passage portions 52c and 52d formed by the inclined portions 59 and 60 between the impeller accommodating portion 52a and the switching valve accommodating portion 52b, the impeller will be described in detail later. The water discharged radially outward from the impeller 33 in the accommodating portion 52a flows in an annular shape around the impeller 33, and flows through the passage portions 52c and 52d into the switching valve accommodating portion 52b. It is transported smoothly. Moreover, as described above, one inclined portion 59 is provided so as to extend toward the discharge passage 51a that communicates with the discharge port 54a, and the other inclined portion 60 extends toward the reflux passage 51b that communicates with the discharge port 55a. By providing in this way, it becomes possible to open and close the switching valve 65 accommodated in the switching valve accommodating part 52b by the flow of water. In other words, when water flows in the direction of going down the inclined portion 59 in the passage portion 52c, the switching valve 65 receives the flow of water and rotates in a direction to close the discharge port 54a. On the other hand, when water flows in the direction of going down the inclined portion 60 in the passage portion 52d, the switching valve 65 rotates in a direction to open the discharge port 54a in response to the flow of water, and the discharge port 55a. Is closed. Thus, when water flows downward on the inclined portion 59, water flows from the discharge port 55a to the water supply pipe 9, while when water flows downward on the inclined portion 60, the water discharge pipe flows from the discharge port 54a to the drain pipe. Water flows to 6.

  Further, a partition wall 61 (guide portion) is provided at a portion surrounded by the inclined portion 60 extending toward the reflux passage 51b, the switching valve accommodating portion 52b, and the base portion 56. The partition wall 61 is formed in a columnar shape having a substantially pentagonal cross section. Thereby, the partition wall 61 constitutes a side wall of the passage portion 52d in which one of the side surfaces is formed on the inclined portion 60.

  Of the side surfaces of the partition wall 61, the side surface on the base portion 56 side is formed in a substantially arc shape in plan view so as to follow the outer periphery of the base portion 56. Accordingly, a wall is formed with respect to a part of the impeller accommodating portion 52a formed on the base portion 56, and water flows along the wall. Therefore, the impeller accommodating portion 52a has a blade. The pressure drop of the water in the impeller accommodating part 52a when the wheel 33 rotates can be locally suppressed. Therefore, the water discharged from the impeller 33 can be efficiently conveyed from the portion other than the partition wall 61 of the impeller housing portion 52a to the switching valve housing portion 52b.

  Of the side surfaces of the partition wall 61, the side surface on the switching valve housing portion 52b side is formed in a substantially arc shape in plan view so as to match the shape (fan shape in plan view) of the switching valve housing portion 52b. ing. Thereby, the rotation of the switching valve 65 in the switching valve accommodating portion 52b is not hindered by the partition wall 61.

-Driving action-
The operation of the dishwasher 1 having the above configuration will be described below.

  The dishwasher 1 performs the washing process, the rinsing process, and the drying process to wash and dry the tableware D set in the rack 4.

  First, as shown in FIG. 1, tableware D or the like is set on a rack 4 in the dishwasher 1, and a detergent is put into the water tank 5. When the operation of the dishwasher 1 is started, a predetermined amount of tap water is supplied into the water tank 5 through the water supply pipe 9, and the wash water is stored in the water tank 5. The washing water in the water tank 5 enters the suction passage 57 in the pump 20 of the dishwasher 1 through the introduction pipe 10.

  In the washing step, the impeller 33 of the pump 20 in the dishwasher 1 rotates in the forward rotation direction (the black arrow direction in FIGS. 3 and 4), and the washing water in the suction passage 57 is caused to flow by the impeller 33. It discharges to the impeller accommodating part 52a in the pump chamber 52. The discharged wash water flows around the impeller 33, flows through the passage 52c to the switching valve housing 52b, and flows into the water supply pipe 9 from the discharge port 55a. In FIG. 4, the flow of water is indicated by black arrows. At this time, the switching valve 45 accommodated in the switching valve accommodating portion 52b closes the discharge port 54a by the flow of the cleaning water, so that the cleaning water flows to the water suction pipe 9 through the discharge hole 55a.

  The washing water sent to the water supply pipe 9 is jetted downward from the jetting port 3a of the washing nozzle 3 to wash the tableware D and the like set in the rack 4. The washing water after washing the tableware D and the like is collected again in the water tank 5. And the water in this water tank 5 circulates in the dishwasher 1 with the pump 20 as above-mentioned.

  When the washing operation of the tableware D and the like in the washing step is completed, the impeller 33 of the pump 20 rotates in the reverse direction (the direction of the white arrow in FIGS. 3 and 4), and the washing recovered in the water tank 5 is performed. The sewage afterwards is discharged to the impeller accommodating part 52a in the pump chamber 52 by the impeller 33. The sewage discharged into the impeller accommodating portion 52a is discharged from the discharge port 54a to the drain pipe 6 through the passage portion 52d and the switching valve accommodating portion 52b while flowing around the impeller 33. At this time, the switching valve 65 accommodated in the switching valve accommodating portion 52b closes the drain port 55a and opens the discharge port 54a by the flow of the sewage. It flows to the drain pipe 6 through the discharge port 54a.

  The rinsing process performed after the cleaning process is the same as the above-described cleaning process except that it is not the cleaning water but the tap water not containing the detergent is used to wash away stains such as dishes and the detergent.

  When the cleaning process and the rinsing process as described above are completed, the drying process is started, and the drying fan 7 provided on the side wall of the cleaning chamber 2a of the main body casing 2 is operated to circulate hot air in the cleaning chamber 2a. To do. Thereby, drying of the tableware etc. set to the rack 4 in this washing room 2a is performed. In this drying process, the pump 20 is stopped.

  As described above, when the pump 20 is stopped after the sewage is discharged from the drain pipe 6 by the pump 20, the sewage in the drain pipe 6 flows back into the pump chamber 52 through the discharge port 54a, and the introduction pipe 10 There is a possibility that the water tank 5 will overflow. However, as described above, by providing the substantially cylindrical base portion 56 in the pump casing 51 of the pump 20 and opening the suction passage 57 on the inner wall thereof, the outer wall 56a of the base portion 56 and the above-described passage are provided. The inclined portions 59 and 60 constituting the portions 52c and 52d function as a wall portion that suppresses the backflow of sewage from the discharge port 54a. Therefore, it is possible to prevent the sewage flowing back into the pump chamber 52 from the drain pipe 6 through the discharge port 54a from flowing into the suction port 52a through the suction passage 57. Moreover, since the outer wall 56a of the base portion 56 is located on the extension line of the discharge port 54a, the wall portion effectively blocks sewage flowing backward from the discharge port 54a into the pump chamber 52. Can do.

  The reverse flow of water into the pump chamber 52 as described above also occurs when the pump 20 is stopped when the water is discharged from the discharge port 55a and circulated. Back flow of water from the discharge port 55a to the suction passage 57 can be prevented by the outer wall 56a and the inclined portions 59, 60 of the base portion 56.

-Effect of the embodiment-
As described above, in the present embodiment, in the pump 20 configured to introduce the water in the water tank 5 into the pump chamber 52 from the suction port 53a and discharge the water from the discharge ports 54a and 55a, Since the substantially cylindrical base portion 56 that extends upward from the bottom surface of the pump chamber 52 and is formed in the inner wall of the suction passage 57 that communicates with the suction port 53a is provided, the discharge ports 54a and 55a are provided. Thus, it is possible to prevent water that has flowed back into the switching valve accommodating portion 52 b from flowing into the suction passage 57.

  That is, when the impeller 33 of the pump 20 is stopped, water may flow backward from the discharge ports 54a and 55a into the switching valve accommodating portion 52b of the pump chamber 52, but the upper surface 56b of the base portion 56 is Since it is higher than the bottom surface of the switching valve accommodating portion 52b, it is possible to prevent water from flowing into the suction passage 57 that opens to the inside of the base portion 56 and the inner side wall of the base portion 56. In other words, the water that has flowed back into the switching valve accommodating portion 52b by the outer wall 56a and the inclined portions 59, 60 of the base portion 56 remains inside the base portion 56 or flows into the suction port 53a. Can be prevented.

  Furthermore, since the upper surface 56b of the base portion 56 is formed so as to be higher than the uppermost point 54b of the inlet side opening edge of the discharge port 54a when viewed from the outlet side of the discharge port 54a, the discharge port 54a. It is possible to effectively dam the water that flows backward from the water.

  In addition, since the inclined portions 59 and 60 are provided so as to connect the upper surface 56b of the base portion 56 and the bottom surface of the switching valve housing portion 52b, the switching valve housing portion 52b is located above the base portion 56. Is connected to the impeller accommodating portion 52a formed through the passage portions 52c and 52d. Thereby, the water discharged by the impeller 33 smoothly flows between the impeller accommodating portion 52a and the switching valve accommodating portion 52b. Therefore, water can be efficiently conveyed in the pump chamber 52, and the operation efficiency of the pump 20 can be improved.

  Moreover, two inclined portions 59 and 60 are formed on the base portion 56 so that water flows according to the rotation direction of the impeller 33, so that the impeller 33 is moved in the normal rotation direction and the reverse rotation direction. Even when it is rotated, the water discharged from the impeller 33 can be efficiently flowed to the switching valve accommodating portion 52b.

  Further, since the inclined portions 59 and 60 are provided so as to be adjacent to the inside of the side wall of the pump casing 51, the insides of the side walls of the passage portions 52c and 52d formed by the inclined portions 59 and 60 are provided. It functions as a side wall, and water can flow smoothly through the passage portions 52c and 52d.

  Furthermore, a partition that forms a side wall of the passage portion 52d and a side wall of the impeller housing portion 52a in a portion surrounded by the inclined portion 60, the switching valve housing portion 52b, and the base portion 56 that constitute the passage portion 52d. By providing the wall 61, the partition wall 61 allows water to flow more smoothly into the passage 52d. Moreover, since the pressure drop of the water in the impeller accommodating portion 52a can be partially suppressed by the side surface of the partition wall 61 on the base portion 56 side, compared with the case where the partition wall 61 is not provided. Thus, the discharge performance of the impeller 33 can be improved.

<< Other Embodiments >>
About the said embodiment, it is good also as following structures.

  In the said embodiment, although the two inclination parts 59 and 60 which connect the upper surface of the base part 56 and the bottom face of the switching valve accommodating part 52b are provided, not only this but the discharge performance of the pump 20 is requested | required ( In the dishwasher 1, when water is circulated), an inclined portion (in the present embodiment, an inclined portion 59) may be provided only on the side through which water passes. Further, due to the discharge performance of the pump 20 and the convenience of molding the pump casing 51, these inclined portions are omitted, and a step is formed between the upper surface 56b of the base portion 56a and the bottom surface of the switching valve accommodating portion 52b. You may do it.

  Moreover, in the said embodiment, although the partition wall 61 is provided between the inclination part 60 and the base part 56, it is not restricted to this, The partition wall 61 does not need to be provided.

  Moreover, in the said embodiment, although the substantially cylindrical base part 56 is provided in the pump chamber 52, it is not restricted to this, A wall is provided between the suction inlet 53a and the discharge outlets 54a and 55a, and this suction is provided. A wall portion is formed to prevent water flowing backward from the discharge ports 54a and 55a from flowing into the suction port 53a side, such as flowing water from the port 53a side to the discharge ports 54a and 55a via the impeller. Any configuration is possible as long as it is configured.

  Moreover, in the said embodiment, although the pump 20 is applied to the dishwasher 1, it is not restricted to this, If it is an apparatus which needs to convey fluids, such as water, the said pump 20 is provided to apparatuses other than the dishwasher 1. The following configuration may be applied.

DESCRIPTION OF SYMBOLS 1 Dishwasher 6 Drain pipe 20 Pump 33 Impeller 50 Pump part 51 Pump casing (casing)
52 Pump chamber 52b Switching valve accommodating part (rotating space part)
53a Suction port 54a, 55a Discharge port 56 Base part 56a Side wall (wall part)
56b Upper surface (upper part)
57 Suction passage 59, 60 Inclined part (wall part)
61 Partition wall (guide section)
65 Switching valve P Rotating shaft

Claims (8)

A casing having a pump chamber therein and having a suction port for introducing fluid into the pump chamber and a discharge port for discharging fluid from the pump chamber;
An impeller disposed rotatably about the rotation axis in the pump chamber,
A wall portion for preventing a back flow of fluid from the discharge port to the suction port is provided at a position on the extension line of the discharge port on the downstream side in the fluid flow direction from the impeller in the pump chamber. Pump being. The pump according to claim 1, wherein
The casing is arranged such that the rotation shaft of the impeller extends in the vertical direction, and the suction port and the discharge port are opened sideways.
A columnar base portion is provided on the bottom surface of the casing so as to rotatably support the impeller at the top, and has a suction passage for allowing fluid to flow from the suction port to the impeller. Being
The impeller is configured to flow a fluid flowing in the suction passage of the base portion and flowing into the impeller to the discharge port side,
The said wall part is a pump comprised by the side wall of the said base part. The pump according to claim 1 or 2,
The said wall part is a pump higher than the uppermost point of the inlet side opening edge of this discharge port seeing from the exit side of the said discharge port. The pump according to claim 2,
The pump in which the said wall part is provided with the inclination part which connects the upper part of this base part, and the bottom face in the said casing so that a fluid may flow toward the said discharge port from the upper part of the said base part. The pump according to claim 4,
The impeller is configured to be rotatable in the forward rotation direction and the reverse rotation direction,
The said inclination part is a pump provided in at least two places of the said wall part so that a fluid may flow toward the said discharge port from the upper part of the said base part according to the rotation direction of the said impeller. The pump according to claim 4 or 5,
The said inclination part is a pump provided so that it may adjoin to the inner side of the side wall of the said casing. The pump according to claim 6, wherein
A pump provided with a guide portion for flowing a fluid along the inclined portion on the casing inner side of the inclined portion. The pump according to any one of claims 1 to 7,
The switch further includes a switching valve that is rotatably arranged around the support shaft in the casing and is configured to open and close the discharge port by rotation.
The casing is formed with a rotation space for rotating the switching valve,
The said wall part is a pump which consists of a wall which divides the said rotation space part.

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