JP7046513B2 - Dishwasher - Google Patents

Description

The present invention relates to a dishwasher for washing dishes by injecting washing water onto the dishes housed in the washing room.

Conventionally, a dishwasher that has a washing room for accommodating tableware and an arm nozzle that rotates while spraying washing water in the washing room is provided, and the sprayed washing water is applied to the tableware to wash the tableware. be.

In this type of dishwasher, there has been a demand for spraying washing water over a wide area in order to wash dishes evenly regardless of their placement position. Therefore, a dishwasher that arranges a rotating body nozzle equipped with a rotatable propeller-shaped blade at the washing water injection port provided in the arm nozzle and diffuses and sprays the washing water by the rotating body nozzle. It has been proposed (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 11-332810

By the way, in the dishwasher described in Patent Document 1, the rotating body nozzle is rotated by colliding the washing water ejected from the arm nozzle with the rotating body nozzle to wash the tableware. Therefore, in this dishwasher, the pressure of the washing water is reduced when the rotating body nozzle is rotated, so that the pressure of the washing water cannot be sufficiently secured when hitting the dishes, and the stains with strong adhesive force such as rice grains cannot be secured. There was a problem that the detergency was reduced.

The present invention has been made in view of the above points, and an object of the present invention is to provide a dishwasher capable of spraying washing water over a wide range and having sufficient washing performance even for stains having strong adhesive force. And.

In order to achieve the above object, the dishwasher of the present invention
A dishwasher provided with a washing chamber for accommodating tableware and an arm nozzle provided inside the washing chamber and ejecting washing water while rotating around a first axis extending in the vertical direction.
The arm nozzle supplies an annular rotating body nozzle that injects the washing water while rotating around a second axis extending in the vertical direction, and the washing water for washing the tableware to the rotating body nozzle. A supply port , a main flow path that guides the washing water supplied to the arm nozzle to the supply port, and a branch from the main flow path in a direction intersecting the extending direction of the main flow path, and a plurality of protrusions are formed on the side wall surface. It is provided with a passage-shaped sub-flow path formed and a power injection port for injecting the washing water supplied through the sub-flow path in order to apply a rotational force to the rotating body nozzle.
The rotating body nozzle is located above the cleaning injection port for injecting the cleaning water supplied from the supply port and the power injection port, and is ejected upward from the power injection port. It has a conversion unit that converts the pressure of the washing water into a rotational force, and an annular portion that is located inside the conversion unit in the radial direction of the rotating body nozzle.
The conversion unit is a plurality of blades extending in the radial direction and inclined to one side in the circumferential direction of the rotating body nozzle.
The plurality of blades include a first blade and a second blade arranged on one side in the circumferential direction of the first blade at a distance from the first blade. ,
The radial center end of the first blade and the radial center end of the second blade are connected via an outer peripheral surface of the annular portion.
The outer peripheral surface of the annular portion is a surface extending in the second axis direction, and the width of the outer peripheral surface of the annular portion in the second axis direction is the width of the plurality of blades in the second axis direction. Corresponding width,
The power injection port is located at a position overlapping the first blade and the second blade in the radial direction.
The opening diameter of the power injection port is the distance from the edge of the first blade on the one-sided side in the circumferential direction to the edge of the second blade on the other side in the circumferential direction. It is characterized in that it is larger than the distance in the central portion of the region where the plurality of blades overlap with the power injection port in the radial direction.

As described above, in the dishwasher of the present invention, since the arm nozzle is provided with the rotating body nozzle, the washing water can be sprayed over a wide range inside the washing chamber. A rotational force is applied to the rotating body nozzle by the cleaning water ejected from the power injection port provided independently of the supply port for supplying the cleaning water for cleaning. As a result, the pressure of the washing water for washing is not reduced because the rotating body nozzle is rotated.

Therefore, according to the dishwasher of the present invention, the pressure of the washing water for washing can be sufficiently secured even though the structure is provided with the rotating body nozzle, so that the washing water can be sprayed over a wide range. Sufficient cleaning performance can be achieved even for dirt with strong adhesive force.
Further, with this configuration, the washing water ejected from the power injection port surely collides with the blade regardless of the position of the blade, so that the rotating body nozzle can stably obtain the rotational force. .. Thereby, stable cleaning performance can be obtained.
Further, with this configuration, the flow velocity of the washing water flowing through the sub-flow path is reduced according to the shape of the sub-flow path, and the momentum of the washing water jetted from the power injection port (and by extension, the rotation of the rotating body nozzle). Speed) is also reduced. That is, the rotation speed of the rotating body nozzle can be easily adjusted to a desired rotation speed only by adjusting the length and shape of the sub-flow path. As a result, the desired cleaning performance can be easily set by adjusting the amount of cleaning water that collides with the same portion of the tableware.

Further, in the dishwasher of the present invention,
The rotating body nozzle has an annular recess extending in the circumferential direction around the second axis on the surface on the supply port side and communicating with the cleaning injection port.
It is preferable that the supply port is arranged at a position facing any portion of the recess.

With this configuration, the cleaning water supplied from the supply port is guided to the cleaning injection port through the recess, no matter how much the rotating body nozzle is rotated. As a result, it is possible to inject the cleaning water for stable cleaning (that is, obtain stable cleaning performance) as compared with the configuration in which the cleaning water is directly supplied from the supply port to the cleaning injection port.

Further, in the dishwasher of the present invention,
It is preferable that the cleaning injection port is arranged outside the conversion portion in the radial direction.

With this configuration, the movable radius of the cleaning injection port can be increased without changing the size of the rotating body nozzle. That is, the washing water can be sprayed over a wide range without changing the size of the rotating body nozzle.

Further , in the dishwasher of the present invention,
The arm nozzle includes a plurality of supply ports and a disk-shaped installation member that supports the rotating body nozzle.
It is preferable that the plurality of supply ports are arranged at equal intervals in the circumferential direction of the installation member about the second axis.
When a plurality of supply ports are arranged, if the arrangement position is biased, the pressure applied to the rotating body nozzle by the washing water ejected from the supply port is also biased depending on the position, and the rotating body nozzle becomes the same. There is a risk that the posture will be tilted with respect to the second axis, which is the axis of rotation. Then, in such a posture, there is a possibility that the rotating body nozzle comes into contact with the rotating body nozzle and a member (for example, an arm nozzle) supporting the rotating body nozzle, and it becomes difficult for the rotating body nozzle to rotate smoothly.
Therefore, when a plurality of supply ports are arranged, if they are arranged at equal intervals in the circumferential direction with the second axis as the center, the pressure applied to the rotating body nozzle by the washing water jetted from the supply ports is applied. Is constant regardless of the position, so that the inclination of the rotating body nozzle with respect to the second axis is suppressed, and the rotating body nozzle can be smoothly rotated. Thereby, stable cleaning performance can be obtained.

Explanatory drawing which shows typically the structure of the dishwasher which concerns on embodiment. The plan view of the arm nozzle of the dishwasher of FIG. The plan view of the rotating body nozzle of the arm nozzle of FIG. 2 and the installation member. Bottom view of the rotating body nozzle of the arm nozzle and the installation member of FIG. FIG. 2 is a cross-sectional view taken along the line AA of the arm nozzle of FIG. The bottom view of the rotating body nozzle of the arm nozzle of FIG. 2 is an explanatory view showing an enlarged main part of a rotating body nozzle and an installation member of the arm nozzle of FIG. 2, FIG. 7A is a plan view, and FIG. 7B is a sectional view taken along line BB of FIG. 7A.

Hereinafter, the dishwasher 1 according to the embodiment will be described with reference to the drawings. The arrow shown in FIG. 3 indicates the direction of the rotating body of the rotating body nozzle. Further, the arrows shown in FIGS. 4 and 5 indicate the direction in which the washing water flows.

The dishwasher 1 of the present embodiment described below is a built-in dishwasher installed in a system kitchen, but the dishwasher of the present invention is limited to such a configuration. Instead, it may be a front-open dishwasher that is used independently.

As shown in FIG. 1, the dishwasher 1 has a front drawer type structure in which a washing tank 2 (washing room) accommodating tableware W is housed in an outer case 3.

The cleaning tank 2 has a box shape with an open upper portion, and a door panel 4 is provided on the front surface of the cleaning tank 2.

Inside the outer case 3, there is a water supply pipe 5 for supplying water to the washing tank 2, a drain hose 6 for draining the washing tank 2, and a drying fan 7 for blowing air for drying inside the washing tank 2. A control unit 8 for controlling the operation of the cleaning tank 2 is provided.

Inside the washing tank 2, an upper tableware basket 9 and a lower tableware basket 10 for holding the tableware W are provided, and washing water is poured toward the tableware W held in the upper tableware basket 9 and the lower tableware basket 10. A cleaning nozzle 11 for spraying and a heater 12 for heating the cleaning water are provided.

At the bottom of the washing tank 2, a storage portion 13 for temporarily storing washing water during washing is formed. The storage portion 13 is covered with a leftover food filter 14 to prevent the leftover food from entering.

A circulation pump 15 is connected to the storage unit 13. The circulation pump 15 includes an impeller 16 and a motor 17 that rotationally drives the impeller 16. In the circulation pump 15, at the time of cleaning, the cleaning water of the storage unit 13 is sent out toward the cleaning nozzle 11 by rotating the impeller 16 in the normal direction and circulated, and the cleaning water of the storage unit 13 is reversed at the end of cleaning. Is sent toward the drain hose 6 and drained.

The cleaning nozzle 11 sprays cleaning water toward the tableware W while rotating around the first axis a1 extending in the vertical direction, and is composed of a pair of arm nozzles 18 extending in the lateral direction from the central portion. There is.

The arm nozzle 18 is configured as a hollow member, and the space inside the arm nozzle 18 is a main flow path 18a through which the washing water supplied by the impeller 16 flows (see FIG. 5). An installation member 19 is attached to one of the arm nozzles 18, and a rotating body nozzle 20 that is rotatable about a second axis a2 extending in the vertical direction is provided via the installation member 19.

As shown in FIG. 2, the arm nozzle 18 is provided with a plurality of first injection ports 18b for injecting the supplied washing water. In the washing nozzle 11, the tableware W is washed with the washing water sprayed from the plurality of first injection ports 18b provided in the arm nozzle 18 and the rotating body nozzle 20.

The washing water jetted from a part of the first injection port 18b of the arm nozzle 18 is used not only for washing the tableware W but also for obtaining a propulsive force for rotating the washing nozzle 11.

Here, with reference to FIGS. 3 to 7, the configuration of the rotating body nozzle 20 and the installation member 19 that supports the rotating body nozzle 20 will be described in detail.

As shown in FIG. 3, the rotating body nozzle 20 includes an annular first annular portion 20a (see FIG. 6), a second annular portion 20b provided concentrically with the first annular portion 20a, and a first annular portion 20a. A plurality of blades 20c (converting portions) extending radially from the first annular portion 20a are provided between the surface and the second annular portion 20b.

As shown in the plan view of FIG. 3 and the bottom view of FIG. 4, the installation member 19 is provided concentrically with the disk portion 19a and the disk portion 19a that cover the first annular portion 20a and the blade 20c of the rotating body nozzle 20. An annular frame body portion 19b extending along the outer edge of the second annular portion 20b of the rotating body nozzle 20, and a plurality of bridge portions 19c extending radially from the disk portion 19a between the disk portion 19a and the frame body portion 19b. have.

As shown in the cross-sectional view of FIG. 5, an opening 20a1 is formed at the center of the first annular portion 20a of the rotating body nozzle 20. Further, a through hole 19a1 is provided in the center of the disk portion 19a of the installation member 19, and a tubular portion 19a2 extends upward from the peripheral edge portion of the through hole 19a1.

A tubular portion 19a2 of the installation member 19 is inserted through the opening 20a1 of the rotating body nozzle 20. As a result, the rotating body nozzle 20 is rotatable about the second axis a2 with respect to the installation member 19.

Further, the rotating body nozzle 20 and the installation member 19 are fixed in relative positions in the second axis a2 direction by the shaft member 21 inserted through the opening 20a1, the cylindrical portion 19a2, and the through hole 19a1. There is.

Here, a mechanism for injecting washing water to wash the tableware W through the rotating body nozzle 20 will be described.

As shown in FIGS. 5 and 6, a circle extending in the circumferential direction about the second axis a2 on the back surface (the surface on the installation member 19 side) of the second annular portion 20b of the rotating body nozzle 20. An annular recess 20d is formed. The space inside the recess 20d and the space above the rotating body nozzle 20 are communicated with each other via the second injection port 20e (cleaning injection port).

As shown in FIGS. 4 and 5, a plurality of supply ports 19d are formed in the installation member 19 by the outer edge of the disk portion 19a, the inner edge of the frame body portion 19b, and the bridge portion 19c. The supply ports 19d are all arranged so as to face the recess 20d of the rotating body nozzle 20. Therefore, the space inside the recess 20d and the space below the installation member 19 (the main flow path 18a formed inside the arm nozzle 18) are communicated with each other via the supply port 19d.

That is, a part of the washing water flowing through the main flow path 18a is guided to the recess 20d of the rotating body nozzle 20 through the supply port 19d of the installation member 19, and then the tableware W is washed from the second injection port 20e. Is sprayed for.

At this time, the rotating body nozzle 20 rotates about the second axis line a2, and the arm nozzle 18 on which the rotating body nozzle 20 is installed rotates about the first axis line a1 (see FIG. 2). The washing water from the 2 injection port 20e is sprayed over a wide area inside the washing tank 2.

In the dishwasher 1, dishes are served from the main flow path 18a to the second injection port 20e via the recess 20d of the rotating body nozzle 20 and the supply port 19d of the installation member 19 provided so as to face the recess 20d. It guides the washing water for washing W.

As a result, the washing water from the main flow path 18a is guided to the second injection port 20e no matter how much the rotating body nozzle 20 is rotated. As a result, as compared with the configuration in which the cleaning water is directly guided from the supply port 19d to the second injection port 20e, the cleaning water for stable cleaning can be injected from the second injection port 20e.

However, the dishwasher of the present invention is not limited to such a configuration. For example, when a plurality of second injection ports 20e are provided, the recess 20d may be omitted. Further, the concave portion 20d does not necessarily have to be an annular shape, and may be an annular shape so that at least a part of the supply port 19d can face each other no matter how much the rotating body nozzle 20 is rotated. For example, it may be a polygonal ring.

By the way, in order to improve the cleaning performance, it is preferable that the amount of cleaning water is large, so that the amount of cleaning water supplied to the rotating body nozzle 20 that injects the cleaning water is also preferable. Therefore, the dishwasher 1 is provided with a plurality of supply ports 19d for supplying washing water for washing to the rotating body nozzle 20.

However, when a plurality of supply ports 19d are arranged, if the arrangement positions are biased, the pressure applied to the rotating body nozzle 20 by the washing water jetted from the supply ports 19d is also biased depending on the position, and the rotation The body nozzle 20 may be in an inclined posture with respect to the second axis a2, which is the axis of rotation thereof.

Then, in such a posture, the rotating body nozzle 20 comes into contact with the rotating body nozzle 20 and the members supporting the rotating body nozzle 20 (specifically, the tubular portion 19a2 and the shaft member 21 of the installation member 19) and the like, and the rotating body nozzle There is a risk that the 20 will not rotate smoothly.

Therefore, as shown in FIG. 4, in the dishwasher 1, a plurality of supply ports 19d are arranged at equal intervals in the circumferential direction with the second axis line a2 as the center. As a result, the pressure applied to the rotating body nozzle 20 by the washing water jetted from the supply port 19d becomes constant regardless of the position, so that the inclination of the rotating body nozzle 20 with respect to the second axis a2 is suppressed, and the rotating body nozzle 20 is suppressed. Can be rotated smoothly.

It should be noted that a plurality of supply ports 19d do not necessarily have to be arranged, and only one may be arranged when the amount of washing water is sufficient, such as when the supply port 19d is sufficiently large. Further, when the inclination of the posture of the rotating body nozzle 20 does not matter so much, such as when the friction coefficient of the material used for forming the rotating body nozzle 20 and the installation member 19 is low, the supply port 19d is arranged unevenly. May be.

Next, a mechanism for applying a rotational force to the rotating body nozzle 20 will be described.

As shown in FIG. 4, a third injection port for injecting washing water for applying a rotational force to the rotating body nozzle 20 at a position facing the blade 20c of the rotating body nozzle 20 on the disk portion 19a of the installation member 19. 19a3 (power injection port) is formed.

As shown in FIG. 5, the third injection port 19a3 has a space below the disk portion 19a (that is, a main flow path 18a formed inside the arm nozzle 18) and a space above the disk portion 19a (that is, a blade). It communicates with the space in which 20c exists), and injects the washing water supplied from the main flow path 18a through the groove portion 19a4 described later.

As shown in FIGS. 7A and 7B, the distance between the plurality of blades 20c is formed to be narrower than the diameter of the third injection port 19a3. Specifically, the distance d between the blades 20c is formed to be smaller than the opening diameter D of the third injection port 19a3. As a result, the washing water ejected from the third injection port 19a3 surely collides with the blade 20c regardless of the position of the blade 20c.

The pressure applied to the blade 20c when the washing water ejected from the third injection port 19a3 collides with the blade 20c is converted into a rotational force for rotating the rotating body nozzle 20 by the blade 20c.

Specifically, as shown in FIG. 7B, the side surface portion 20c1 of the blade 20c is inclined to one side in the circumferential direction with respect to the second axis a2, and the lower surface portion 20c2 thereof is circumferentially oriented with respect to the side surface portion 20c1. Since it is formed as a plate material further inclined to one side, the pressure of the washing water sprayed on the side surface portion 20c1 and the lower surface portion 20c2 is the moving force of the blade 20c in the circumferential direction (that is, the rotating body nozzle 20). It is converted to rotational force).

Here, in the dishwasher 1, the third injection port 19a3 for injecting the washing water to give the rotating body nozzle 20 a rotational force is independent of the supply port 19d for supplying the washing water for washing. It is provided, and the supply route of wash water to them is also different. Therefore, the pressure of the washing water jetted from the supply port 19d is not reduced by injecting the washing water from the third injection port 19a3 in order to rotate the rotating body nozzle 20.

Therefore, according to the dishwasher 1, even though the rotating body nozzle 20 is provided, the pressure of the washing water for washing can be sufficiently secured, so that the washing water can be sprayed over a wide range. Sufficient cleaning performance can be achieved even for strong stains.

Since the dishwasher 1 employs a blade 20c as a conversion unit that converts the pressure of the washing water into a rotational force, the washing water sprayed on the blade 20c collides with the blade 20c and then upward. It will be diffused into the space (that is, the space where the tableware W exists). As a result, the washing water sprayed from the third injection port 19a3 is used not only to apply a rotational force to the rotating body nozzle 20 but also to wash the tableware W.

By the way, as shown in FIG. 5, the thickness of the disk portion 19a of the installation member 19 is such that it is adjacent to the bottom surface of the main flow path 18a in a state of being attached to the arm nozzle 18. Further, as shown in FIG. 4, a groove portion 19a4 (secondary flow path) through which washing water can flow from the main flow path 18a is formed on the back surface of the disk portion 19a.

The third injection port 19a3 for injecting the washing water toward the blade 20c is formed in the innermost portion of the groove portion 19a4. On the other hand, the entrance portion of the groove portion 19a4 is formed on the peripheral surface portion of the disk portion 19a (that is, the groove portion 19a4 branches in a direction intersecting the extending direction of the main flow path 18a of the arm nozzle 18). Further, the groove portion 19a4 is curved and extended so as to bypass the second axis line a2. Further, a plurality of protruding portions are formed on the side wall surface of the groove portion 19a4.

With these configurations, the flow velocity of the washing water flowing from the main flow path 18a into the groove portion 19a4 is lower than the flow velocity of the washing water flowing through the main flow path 18a, depending on the length and shape of the groove portion 19a4. That is, the speed of the washing water supplied to the third injection port 19a3 via the groove portion 19a4 is also reduced.

In the dishwasher 1, the speed of the washing water jetted from the third injection port 19a3 (and by extension, the rotation speed of the rotating body nozzle 20) is adjusted to a desired speed by adjusting the length and shape of the groove portion 19a4. is doing. As a result, the cleaning performance is adjusted by adjusting the amount of washing water that is obtained and collided with the same part of the tableware W.

The length and shape of the sub-flow path of the dishwasher of the present invention are not limited to the above-mentioned groove 19a4 configuration, and may be appropriately changed according to the required rotation speed of the rotating body nozzle. It's okay.

For example, the groove portion 19a4 may be extended linearly without bypassing the second axis line a2. Further, it is not necessary to provide a protruding portion on the side wall portion of the groove portion 19a4. Further, the groove portion 19a4 may be omitted, and the disk portion 19a may be formed thinly so that the washing water flowing through the main flow path 18a is directly guided to the third injection port 19a3. Further, a through hole may be formed in the disk portion 19a, and the through hole may be used as a secondary flow path instead of the groove portion 19a4.

Although the illustrated embodiment has been described above, the present invention is not limited to such an embodiment.

For example, in the above embodiment, the installation member 19 and the arm nozzle 18 are configured as separate members. However, the present invention is not limited to such a configuration, and the installation member 19 may be integrally configured as a part of the arm nozzle 18. For example, the frame body portion 19b of the installation member 19 may be continuously provided on the arm nozzle 18.

Further, in the above embodiment, the blade 20c is used as the conversion unit. However, the conversion unit of the present invention is not limited to the blade as described above, and may be any one that can convert the pressure of the washing water injected from the power injection port into the rotational force. For example, the peripheral surface of the rotating body nozzle may be provided with an unevenness or groove inclined with respect to the axis line which is the center of rotation thereof, and cleaning water may be sprayed onto the unevenness or groove to obtain a rotational force. good.

Further, in the above embodiment, the second annular portion 20b located on the radial outer side of the blade 20c, which is the conversion portion, is provided with the second injection port 20e, which is a cleaning injection port. This is to increase the movable radius of the cleaning injection port without changing the size of the rotating body nozzle 20. That is, the washing water is sprayed over a wide range without changing the size of the rotating body nozzle 20.

However, the present invention is not limited to such a configuration, and the conversion unit and the cleaning injection port may be located concentrically, and the cleaning injection port is located inside the conversion unit in the radial direction. You may do it. When the conversion unit is positioned on the outer side in the radial direction, the rotating body nozzle can be rotated with a small amount of water.

Further, in the above embodiment, by forming the distance d between the plurality of blades 20c smaller than the opening diameter D of the third injection port 19a3 (power injection port), the blades 20c can be positioned at any position. The cleaning water ejected from the third injection port 19a3 is configured to surely collide with the blade 20c. This is to stabilize the rotation of the rotating body nozzle 20.

However, the present invention is not limited to such a configuration. For example, when the rotating body nozzle itself has an eccentric shape and the rotation is started according to the rotation of the arm nozzle, the distance between the blades is formed larger than the opening diameter of the power injection port. You may.

1 ... Dishwasher, 2 ... Washing tank (washing room), 3 ... Exterior case, 4 ... Door panel, 5 ... Water supply pipe, 6 ... Drain hose, 7 ... Drying fan, 8 ... Control unit, 9 ... Upper tableware basket 10, ... lower tableware basket, 11 ... washing nozzle, 12 ... heater, 13 ... reservoir, 14 ... leftover filter, 15 ... circulation pump, 16 ... impeller, 17 ... motor, 18 ... arm nozzle, 18a ... main flow path, 18b ... 1st injection port, 19 ... installation member, 19a ... disk part, 19a1 ... through hole, 19a2 ... tubular part, 19a3 ... third injection port (power injection port), 19a4 ... groove part (secondary flow path), 19b ... Frame body part, 19c ... Bridge part, 19d ... Supply port, 20 ... Rotating body nozzle, 20a ... First annular part, 20a1 ... Opening, 20b ... Second annular part, 20c ... Blade (conversion part), 20c1 ... Side surface portion, 20c2 ... Bottom surface portion, 20d ... Recessed portion, 20e ... Second injection port (cleaning injection port), 21 ... Shaft member, a1 ... First axis line, a2 ... Second axis line, W ... Tableware.

Claims (4)

A dishwasher provided with a washing chamber for accommodating tableware and an arm nozzle provided inside the washing chamber and ejecting washing water while rotating around a first axis extending in the vertical direction.
The arm nozzle supplies an annular rotating body nozzle that injects the washing water while rotating around a second axis extending in the vertical direction, and the washing water for washing the tableware to the rotating body nozzle. A supply port , a main flow path that guides the washing water supplied to the arm nozzle to the supply port, and a branch from the main flow path in a direction intersecting the extending direction of the main flow path, and a plurality of protrusions are formed on the side wall surface. It is provided with a passage-shaped sub-flow path formed and a power injection port for injecting the washing water supplied through the sub-flow path in order to apply a rotational force to the rotating body nozzle.
The rotating body nozzle is located above the cleaning injection port for injecting the cleaning water supplied from the supply port and the power injection port, and is ejected upward from the power injection port. It has a conversion unit that converts the pressure of the washing water into a rotational force, and an annular portion that is located inside the conversion unit in the radial direction of the rotating body nozzle.
The conversion unit is a plurality of blades extending in the radial direction and inclined to one side in the circumferential direction of the rotating body nozzle.
The plurality of blades include a first blade and a second blade arranged on one side in the circumferential direction of the first blade at a distance from the first blade. ,
The radial center end of the first blade and the radial center end of the second blade are connected via an outer peripheral surface of the annular portion.
The outer peripheral surface of the annular portion is a surface extending in the second axis direction, and the width of the outer peripheral surface of the annular portion in the second axis direction is the width of the plurality of blades in the second axis direction. Corresponding width,
The power injection port is located at a position overlapping the first blade and the second blade in the radial direction.
The opening diameter of the power injection port is the distance from the edge of the first blade on the one-sided side in the circumferential direction to the edge of the second blade on the other side in the circumferential direction. A dishwasher characterized in that it is larger than the distance in the central portion of the region where the plurality of blades overlap with the power injection port in the radial direction. In the dishwasher according to claim 1,
The rotating body nozzle has an annular recess extending in the circumferential direction around the second axis on the surface on the supply port side and communicating with the cleaning injection port.
A dishwasher characterized in that the supply port is arranged at a position facing any portion of the recess. In the dishwasher according to claim 1 or 2.
The dishwasher is characterized in that the cleaning injection port is arranged outside the conversion unit in the radial direction. In the dishwasher according to any one of claims 1 to 3 .
The arm nozzle includes a plurality of supply ports and a disk-shaped installation member that supports the rotating body nozzle.
A dishwasher characterized in that the plurality of supply ports are arranged at equal intervals in the circumferential direction of the installation member about the second axis.

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