JP2020148065A - Discharge device - Google Patents

Abstract

To provide a technique capable of suppressing a change in a wave-like flow shape due to remaining air.SOLUTION: A discharge device includes a device body 26 in an inside of which a discharge passage 30 is formed, in which the discharge passage 30 has a discharge hole 38 that is formed in a downstream side end part of the discharge passage 30 and can discharge from the discharge hole 38 a liquid flowing in from an upstream side radially as a wave-like flow; and on an upstream side of the discharge hole 38 in the device body 26, an air release passage 64 opened to an inside surface of the discharge passage 30 is formed. In a state in which the fluid is held in the discharge passage 30, the discharge device can evacuate the remaining air in the discharge passage 30 through the air release passage 64.SELECTED DRAWING: Figure 3

Description

The present invention relates to a discharge device capable of radially discharging a wavy liquid flow (hereinafter, also referred to as a wavy flow).

Conventionally, a discharge device capable of radially discharging a wavy flow has been proposed. Patent Document 1 describes a discharge device including a device body having a discharge path formed inside. The discharge path has a discharge hole formed at the downstream end thereof, and the liquid flowing from the upstream side can be radially discharged from the discharge hole as a wavy flow.

Japanese Patent Publication No. 2008-517762

As a result of conducting experimental studies, the present inventor has obtained the following new findings. This is because when the wavy flow is discharged from the discharge hole, if air remains in the discharge path on the upstream side of the discharge hole, the shape of the wavy flow changes due to the remaining air. It is a thing. The technique of Patent Document 1 was not devised from this point of view, and there was room for improvement.

One aspect of the present invention is made in view of such a problem, and one of the objects thereof is to provide a technique capable of suppressing a change in the shape of a wavy flow caused by residual air.

The first aspect of the present invention for solving the above-mentioned problems is a discharge device. This discharge device includes a device main body having a discharge path formed inside, and the discharge path has a discharge hole formed at the downstream end of the discharge path, and discharges the liquid flowing in from the upstream side. It can be discharged radially from the hole as a wavy flow, and an air bleeding flow path that opens to the inner surface of the discharge path is formed in the main body of the device on the upstream side of the discharge hole.

According to the first aspect, when the liquid flow is discharged from the discharge hole, the air remaining in the discharge path on the upstream side of the discharge hole can be exhausted to the outside through the air bleeding flow path. Along with this, the change in the shape of the wavy flow due to the residual air can be suppressed.

It is a block diagram of the discharge system of 1st Embodiment. It is a side sectional view of the discharge device of 1st Embodiment. FIG. 2 is a sectional view taken along the line AA of FIG. It is a figure which shows the wavy flow. FIG. 3 is a sectional view taken along line BB in FIG. It is explanatory drawing about the operation of the discharge device of 1st Embodiment. It is explanatory drawing about the 1st flow state of 1st Embodiment. It is explanatory drawing about the 2nd flow state of 1st Embodiment. It is another figure which shows a wavy flow. It is a partial enlarged view of FIG. It is a partial enlarged view of FIG. It is a side sectional view of the discharge device of 2nd Embodiment. It is sectional drawing of the discharge device of 3rd Embodiment. It is a figure which shows the state which the discharge device of 3rd Embodiment discharges a wavy flow. It is an enlarged view of a part of FIG.

Hereinafter, an example of the embodiment of the present invention will be described. The same components are designated by the same reference numerals, and duplicate description will be omitted. In each drawing, for convenience of explanation, some of the components are appropriately omitted, and the dimensions thereof are appropriately enlarged or reduced. The drawings shall be viewed according to the orientation of the symbols. The shapes referred to in the present specification include not only shapes that exactly match the shapes referred to, but also shapes that are deviated by an error such as a dimensional error or a manufacturing error.

See FIG. The discharge device 10 of this embodiment is used for the water supply equipment 12. The water supply facility 12 of the present embodiment is a bathroom facility. In addition to the discharge device 10, the water supply facility 12 includes a tank body 14 into which the liquid discharged from the discharge device 10 flows inward. The tank body 14 of the present embodiment is a bathtub. The discharge device 10 of the present embodiment discharges the wavy flow W1 (described later) in the tank body 14 so as to hit the user's body, particularly the neck and shoulders of the user in the sitting posture. As a result, the user can be given a relaxing effect.

The discharge device 10 of this embodiment is used in the discharge system 16. The discharge system 16 is provided in the middle of the storage tank 18 for storing the liquid W2, the liquid supply path 20 for supplying the liquid W2 from the storage tank 18 to the discharge path 30 (described later) of the discharge device 10, and the liquid supply path 20. 22 is provided, and a control device 24 for controlling the pump 22 is provided.

The storage tank 18 of the present embodiment is a tank body 14 that stores water as a liquid W2. The water in the tank body 14 is supplied to the discharge device 10 through the liquid supply path 20. The liquid supply path 20 is formed inside a plurality of flow path forming members such as pipes. The pump 22 supplies the liquid W2 to the discharge device 10 through the liquid supply path 20 by pumping the liquid W2 sucked from the storage tank 18. The control device 24 is a computer that combines hardware and software such as a CPU, ROM, and RAM. The control device 24 controls the operation of the discharge device 10 through the control of the operation of the pump 22.

See FIG. The discharge device 10 includes a device main body 26. Inside the apparatus main body 26, a relay flow path 28 in which the liquid W2 is supplied from the liquid supply path 20 and a discharge path 30 in which the liquid W2 is supplied from the liquid supply path 20 via the relay flow path 28 are formed. To. In the present embodiment, the liquid is supplied from the liquid supply path 20 to the relay flow path 28 from the lower side in the vertical direction, and the liquid is supplied upward from the relay flow path 28 to the discharge path 30.

The apparatus main body 26 of the present embodiment is fixed to a base 32 provided in the water supply facility 12. The discharge device 10 of the present embodiment is fixed to the base 32 using a fixing structure (not shown). The fixed structure is, for example, a screw structure, a claw and a claw holder, and the like. The base 32 of the present embodiment is composed of a flange portion of the tank body 14 provided at the peripheral edge of the upper surface opening of the tank body 14. The apparatus main body 26 of the present embodiment includes a first main body member 34 in which the discharge path 30 is formed inside, and a second main body member 36 integrated with the first main body member 34.

See FIGS. 3 and 4. The discharge path 30 has a discharge hole 38 formed at the downstream end of the discharge path 30. Although the details will be described later, the discharge path 30 can radially discharge the liquid W2 flowing from the upstream side as a wavy liquid flow (wavy flow W1). The term "wavy" as used herein means that the discharge hole 38 periodically undulates in the horizontal direction Y orthogonal to the center line direction X as the liquid flow W1 travels in the center line direction X along the center line CL1. Refers to the shape. This "wavy" includes not only a shape that satisfies the condition as a physically strict wave, but also a shape similar to that shape. Hereinafter, the undulating direction Y of the wavy shape formed by the wavy flow W1 is referred to as the vibration direction Y of the wavy flow W1. Further, the “radial” here means a shape that spreads in the vibration direction Y of the wavy flow W1 toward the traveling direction of the wavy flow W1. FIG. 4 shows a range S1 through which the wavy flow W1 passes.

Hereinafter, when the configuration relating to the discharge path 30 will be described, the center line direction X of the discharge hole 38 is also referred to as a front-rear direction X, and the vibration direction Y of the wavy flow W1 is also referred to as a left-right direction Y. Further, the direction orthogonal to the front-rear direction X and the left-right direction Y is referred to as a height direction Z (see FIG. 2). The traveling direction of the wavy flow W1 in the front-rear direction X is called the front side, and the opposite side is called the rear side.

The discharge path 30 includes an inlet flow path 40 in which the liquid W2 flows in from the upstream side, and a pair of intermediate flow paths 42L and 42R in which the liquid W2 flows in from the inlet flow path 40. Further, the discharge path 30 includes a confluence chamber 46 in which the liquids W2 flowing from each of the pair of intermediate flow paths 42L and 42R merge, and a discharge hole 38 for discharging the liquid W2 in the confluence chamber 46 to the outside.

See FIGS. 3 and 5. The discharge path 30 includes an inner upper surface 48 and an inner lower surface 50 facing in the vertical direction, and a pair of inner surface 52s facing each other in the left-right direction Y. The discharge path 30 has a rectangular shape in a cross section orthogonal to the front-rear direction X. In this cross section, the dimension between the pair of inner side surfaces 52 is referred to as the inner width dimension Wa of the discharge path 30, and the dimension between the inner upper surface 48 and the inner lower surface 50 is referred to as the height dimension Ha of the discharge path 30. The discharge passage 30 has a rectangular shape in which the height dimension Ha is smaller than the inner width dimension Wa in the inlet flow path 40 and the confluence chamber 46. The height dimension Ha of the discharge path 30 is the same as long as it includes at least the inlet flow path 40, the intermediate flow paths 42L and 42R, and the confluence chamber 46. In the present embodiment, the same applies to the range including the discharge hole 38.

The discharge path 30 has a symmetrical shape with the center line CL1 of the discharge hole 38 as the axis of symmetry when viewed from the height direction Z. Further, the discharge path 30 has a shape symmetrical with respect to the center line CL1 of the discharge hole 38 in the height direction Z when viewed from the front-rear direction X. These conditions are at least satisfied in the inlet flow path 40 of the discharge passage 30 and the confluence chamber 46. In the present embodiment, the intermediate flow paths 42L and 42R of the discharge path 30 and the discharge hole 38 are also filled. Here, "viewed from the height direction Z" is synonymous with viewing from the viewpoint of FIG. 3, and "viewed from the front-back direction X" is synonymous with viewing from the viewpoint of FIG.

The inlet flow path 40 is provided in the rear portion of the discharge path 30 in the front-rear direction X, and the confluence chamber 46 is provided in the front side of the inlet flow path 40 in the front-rear direction X. An inflow port 28a, which is an outlet of the relay flow path 28, is opened on the inner surface of the inlet flow path 40, and a liquid flows into the inlet flow path 40 from the inflow port 28a. The inflow port 28a of the present embodiment is open to the inner and lower surfaces 50 of the discharge path 30 in the inlet flow path 40.

A diffusion promoting portion 54 is provided in the inlet flow path 40. A plurality of diffusion promoting portions 54 of the present embodiment are provided at equal angular intervals so as to surround the inflow port 28a as a center when viewed from the height direction Z. The cross-sectional shape of the diffusion promoting portion 54 orthogonal to the height direction Z is a streamlined shape, and in the present embodiment, it is a circular shape. The diffusion promoting unit 54 promotes the diffusion of the liquid by colliding with the liquid flowing into the inlet flow path 40. As a result, it is possible to make the flow rate distribution of the liquid toward the front side in the front-rear direction X in the inlet flow path 40 uniform in the left-right direction Y.

The discharge path 30 is provided with a collision portion 56 in which the liquid W2 flowing in the front side (downstream side) in the front-rear direction X collides with the inlet flow path 40. The collision portion 56 of the present embodiment has a wall shape that separates the inlet flow path 40 and the confluence chamber 46 in the front-rear direction X.

The pair of intermediate flow paths 42L and 42R are provided on both sides in the left-right direction Y with respect to the collision portion 56 of the discharge path 30. The pair of intermediate flow paths 42L and 42R have a left intermediate flow path 42L (first intermediate flow path) provided on the left side (one side) in the left-right direction Y and a right side provided on the right side (the other side) in the left-right direction Y. An intermediate flow path 42R (second intermediate flow path) is included. The intermediate flow paths 42L and 42R are formed by a side surface 56a of the collision portion 56 in the left-right direction Y and an inner side surface 52 of the discharge path 30. The intermediate flow paths 42L and 42R of the present embodiment have a shape capable of injecting the liquid W2 flowing from the inlet flow path 40 into the confluence chamber 46. The central axis CL2 of the intermediate flow paths 42L and 42R of the present embodiment is provided so as to cross the center line CL1 of the discharge hole 38 in the left-right direction Y when viewed from the height direction Z.

The confluence chamber 46 of the present embodiment is provided with a pair of collision surfaces 58L and 58R on which jets of liquid injected from each of the pair of intermediate flow paths 42L and 42R collide. The collision surfaces 58L and 58R are provided on the downstream side surface 46a located on the downstream side (front side) of the confluence chamber 46. The pair of collision surfaces 58L and 58R have a right collision surface 58R (first collision surface) corresponding to the left intermediate flow path 42L and a left collision surface 58L (second collision surface) corresponding to the right intermediate flow path 42R. included. The collision surfaces 58L and 58R are provided on the side opposite to the intermediate flow paths 42L and 42R corresponding to the center line CL1 of the discharge hole 38 in the left-right direction Y when viewed from the height direction Z.

In the confluence chamber 46 of the present embodiment, a pair of jets of liquid W2 colliding with each of the pair of collision surfaces 58L and 58R are guided to be folded back to the opposite side (rear side) of the discharge hole 38 in the front-rear direction X. Guidance surfaces 62L and 62R are provided. The pair of guide surfaces 62L and 62R includes a right guide surface 62R corresponding to the right collision surface 58R and a left guidance surface 62L corresponding to the left collision surface 58L. The guide surfaces 62L and 62R are provided on each of the pair of inner side surfaces 52 in the confluence chamber 46.

The discharge hole 38 has an inlet 38a that opens to the downstream side surface 46a of the confluence chamber 46. The inner width dimension of the inlet 38a of the discharge hole 38 is set to be smaller than the inner width dimension of the flow path (merging chamber 46) on the upstream side on the way to the front side in the front-rear direction X. As a result, the discharge hole 38 can be discharged so as to inject the liquid W2 in the flow path on the upstream side thereof. The discharge hole 38 is formed so that the inner width dimension continuously expands toward the front side in the front-rear direction X. The inner width dimension here means a dimension along the left-right direction Y when viewed from the height direction Z. The discharge hole 38 has an outlet 38b that opens to the outer surface of the apparatus main body 26. The outlet 38b of the present embodiment opens to the front surface portion 26a of the apparatus main body 26.

The operation of the discharge device 10 described above will be described.

See FIG. The main liquid flow directions in the discharge path 30 are indicated by arrows. The liquid W2 flows into the inlet flow path 40 from the relay flow path 28 on the upstream side through the inflow port 28a. The liquid W2 that has flowed into the inlet flow path 40 flows toward the front side in the front-rear direction X while diffusing from the inflow location. In this process, the liquid W2 is stored in the inlet flow path 40. In the present embodiment, the inside of the inlet flow path 40 is filled with the liquid W2.

A part of the liquid W2 flowing forward in the inlet flow path 40 collides with the collision portion 56 to be separated in the left-right direction Y, and then forms a liquid flow Fa flowing into the pair of intermediate flow paths 42L and 42R. The liquid W2 in the inlet flow path 40 flows into the confluence chamber 46 via the pair of intermediate flow paths 42L and 42R. In this process, the liquid W2 is stored in the confluence chamber 46.

See FIGS. 7 and 8. Liquid jets FbL and FbR are injected into the confluence chamber 46 from the pair of intermediate flow paths 42L and 42R, respectively. In the present embodiment, the jets FbL and FbR injected from each of the pair of intermediate flow paths 42L and 42R collide in the confluence chamber 46. Hereinafter, the jet jet injected by the left intermediate flow path 42L is referred to as a left jet flow FbL, and the jet flow injected by the right intermediate flow path 42R is referred to as a right jet flow FbR.

One of these jets FbL and FbR is affected by fluctuations caused by the randomness of the fluid, and one of them becomes a dominant flow with stronger force than the other. For example, the example of FIG. 7 shows a first flow state in which the right jet FbR is a dominant flow with stronger force than the left jet FbL.

As shown in FIG. 7, this dominant right jet FbR tends to flow with momentum until it collides with the downstream side surface 46a (left collision surface 58L) of the confluence chamber 46. On the other hand, the left jet FbL is obstructed by colliding with the dominant right jet FbR (see range Sa), and has momentum until it collides with the downstream side surface 46a (right collision surface 58R) of the confluence chamber 46. It's hard to flow. The right jet FbR that collides with the downstream side surface 46a of the confluence chamber 46 forms a liquid flow Fc that is guided by its left guide surface 62L so as to fold back in the front-rear direction X, and merges with the left jet FbL (see range Sb). As a result, the momentum of the left jet FbL is amplified, and as shown in FIG. 8, the left jet FbL switches to the second flow state in which the left jet FbL has a stronger dominant flow than the right jet FbR.

The dominant left jet FbL tends to flow with momentum until it collides with the downstream side surface 46a (right side collision surface 58R) of the confluence chamber 46. On the other hand, the right jet FbR is obstructed by colliding with the dominant left jet FbL (see range Sc), and has momentum until it collides with the downstream side surface 46a (left collision surface 58L) of the confluence chamber 46. It's hard to flow. The left jet FbL that collides with the downstream side surface 46a of the merging chamber 46 forms a liquid flow Fd that is guided by its right guiding surface 62R so as to fold back in the front-rear direction X, and merges with the right jet FbR (see range Sd). As a result, the momentum of the right jet FbR is amplified, and as shown in FIG. 7, the right jet FbR switches to the first flow state in which the right jet FbR has a stronger dominant flow than the left jet FbL.

As a result of the above, the first flow state in which the right jet FbR becomes the dominant flow and the second flow state in which the left jet FbL becomes the dominant flow are affected by the fluctuation caused by the randomness of the fluid. It switches periodically. As shown in FIG. 7, when in the first flow state, a part of the dominant right jet FbR forms a liquid flow Fe that passes through the discharge hole 38 without colliding with the downstream side surface 46a of the confluence chamber 46. This liquid flow Fe has a velocity vector toward the front side in the front-rear direction X and toward the left side in the left-right direction Y. As shown in FIG. 8, when in the second flow state, a part of the dominant left jet FbL forms a liquid flow Ff that passes through the discharge hole 38 without colliding with the downstream side surface 46a of the confluence chamber 46. This liquid flow Ff has a velocity vector toward the front side in the front-rear direction X and toward the right side in the left-right direction Y.

By periodically switching between the first flow state and the second flow state, the directions of the velocity vectors of the liquid flows Fe and Ff passing through the discharge hole 38 in the left-right direction Y are periodically switched. In this process, the amount of the velocity vectors of the liquid flows Fe and Ff in the left-right direction Y increases and decreases periodically with the switching of the directions. As a result, the wavy liquid flow, that is, the above-mentioned wavy flow W1 is discharged from the discharge hole 38. The discharge path 30 causes the liquid flow to flow into the confluence chamber 46 from each of the pair of intermediate flow paths 42L and 42R, thereby swinging the traveling directions of the liquid flows Fe and Ff discharged from the discharge hole 38 in the left-right direction Y. It is movable, and the wavy flow W1 can be discharged by swinging its traveling direction.

In this way, the discharge path 30 can radially discharge the wavy flow from the discharge hole 38 by allowing the liquid W2 to flow into the confluence chamber 46 from the inlet flow path 40 via each of the pair of intermediate flow paths 42L and 42R. Is. A type in which the wavy flow W1 is discharged by utilizing a plurality of liquid flows (liquid flows) flowing into the confluence chamber 46 from the pair of intermediate flow paths 42L and 42R in this way is called a confluence type. In the present embodiment, as such a confluence type discharge path 30, a fluctuation type discharge path 30 utilizing the fluctuation of the fluid has been described. In addition to this, as the confluence type discharge path 30, there is a Karman vortex type discharge path 30 that utilizes a Karman vortex described later.

See FIGS. 4 and 9. FIG. 4 shows a state in which air A does not remain in the discharge path 30, and FIG. 9 shows a state in which air A remains in the discharge path 30 on the upstream side of the discharge hole 38. The present inventor has proceeded with an experimental study on a discharge device capable of discharging the wavy flow W1.

As a result, it was found that the air A is easily confined in the discharge path 30 by the liquid W2 that continues to flow toward the discharge hole 38 in the discharge path 30 on the upstream side of the discharge hole 38. .. In particular, in the confluence type discharge path 30, it was found that the air A tends to remain in the confluence chamber 46 due to the liquid W2 that continues to flow from the confluence chamber 46 into the discharge hole 38.

Further, it has been found that if the air A remains in the discharge path 30 on the upstream side of the discharge hole 38, the shape of the wavy flow W1 may change due to the remaining air A. Obtained. It was found that among the residual air A in the discharge path 30, the residual air A in the confluence chamber 46 has a great influence on this phenomenon. The cause of this is not clear, but it is presumed that the residual air A in the discharge path 30 has some influence on the flow of the liquid W2 in the discharge path 30. It was also found that this phenomenon becomes more likely to become apparent as the amount of residual air A in the discharge path 30 increases.

Further, in the fluctuation type or Karman vortex type discharge path 30, when the flow rate of the liquid W2 flowing into the discharge path 30 is small, the amplitude of the wavy flow W1 is significantly small due to the residual air A in the confluence chamber 46. In some cases, a linear liquid flow was discharged instead of a wavy one. Further, it was also found that in the fluctuation type or Karman vortex type discharge path 30, air A tends to remain in the air pool region 72 (described later) in the confluence chamber 46.

10 and 11 are referred to. The present inventor has proceeded with further experimental studies. As a result, on the upstream side of the discharge hole 38, an air bleeding flow path 64 that opens to the inner surface of the discharge path 30 is formed in the apparatus main body 26, and the residual air A in the discharge path 30 is passed to the outside through the air bleeding flow path 64. It was found that exhausting is effective. In FIG. 10, for convenience of explanation, the introduction port 64a of the air bleeding flow path 64, which will be described later, is shown in black.

Hereinafter, the details of the discharge device 10 made based on such knowledge will be further described. The air bleeding flow path 64 has an introduction port 64a that opens to the inner surface of the discharge path 30 on the upstream side of the discharge hole 38. The introduction port 64a of the present embodiment opens on the inner surface of the confluence chamber 46.

The air bleeding flow path 64 communicates between the space on the upstream side of the discharge hole 38 of the discharge path 30 and the open space 68 open to the atmosphere. In the present embodiment, the open space 68 is an external space outside the device main body 26. As a result, the residual air A in the discharge path 30 is pushed out by the liquid W2 stored in the discharge path 30, so that the residual air A in the discharge path 30 can be exhausted to the open space 68 through the air bleeding flow path 64.

The flow path cross section of the air bleeding flow path 64 is set to a size capable of obstructing the flow of the liquid W2 in the discharge path 30 while exhausting the residual air A in the discharge path 30. In order to satisfy this condition, the cross-sectional area of the air bleeding flow path 64 is set to be sufficiently smaller than the cross-sectional area of the discharge path 30 in the cross section orthogonal to the front-rear direction X. The flow path cross-sectional area of the air bleeding flow path 64 is, for example, 0.2 mm ² or more and 3.0 mm ² or less in size. If it is at least this lower limit, it can be easily realized from the level of processing technology at the time of filing. If it is not more than this upper limit value, even if a part of the liquid W2 in the discharge path 30 leaks to the outside from the air bleeding flow path 64, the amount of the leak can be suppressed and the appearance can be avoided.

(A) As a result, when the wavy flow W1 is discharged from the discharge hole 38, the air A remaining in the discharge path 30 on the upstream side of the discharge hole 38 can be exhausted to the outside through the air bleeding flow path 64. Along with this, the residual air A in the discharge path 30 can be reduced as compared with the case where the discharge path 30 does not have the air bleeding flow path 64, and the change in the shape of the wavy flow W1 due to the residual air A can be suppressed.

As another measure against the residual air A in the discharge path 30, it is conceivable to increase the flow rate of the liquid W2 flowing into the discharge path 30. As a result, the liquid W2 flowing into the discharge path 30 can easily entrain the residual air A in the discharge path 30, and the residual air A in the discharge path 30 can be easily reduced. However, the present inventor has found that when this measure is taken, there is a problem that the vibration period of the wavy flow W1 becomes excessively fast. When the discharge device 10 is used in the water supply facility 12, it is desired to give the user a feeling of relaxation by slowing the vibration cycle from the viewpoint of improving the appearance of the wavy flow W1. According to this embodiment, the flow rate of the liquid flowing into the discharge path 30 can be reduced while reducing the residual air A in the discharge path 30. Along with this, there is an advantage that the appearance can be improved by delaying the vibration cycle of the wavy flow W1. Further, when the wavy flow W1 discharged from the discharge device 10 is applied to the user's body and used, there is an advantage that a relaxed massage feeling can be given to the user by delaying the vibration cycle of the wavy flow W1.

The air bleeding flow path 64 of the present embodiment is open to the inner surface of the confluence chamber 46. Therefore, the residual air A in the confluence chamber 46, which has a large influence on the change in the shape of the wavy flow W1, can be reduced, and the change in the shape of the wavy flow W1 can be effectively suppressed.

In the case of the fluctuation type discharge path 30, it is preferable that the introduction port 64a of the air bleeding flow path 64 is open to the air pool region 72 described below. The direction along the central axis CL2 of the intermediate flow paths 42L and 42R is referred to as the axial direction Da. A region extending linearly from the intermediate flow paths 42L and 42R in the axial direction Da when viewed from the height direction Z is referred to as a liquid flow passage region 70. The liquid flow passage region 70 is a region where the liquid flow is expected to pass when the liquid flow (jet FbL, FbR) linearly flows into the confluence chamber 46 from the intermediate flow paths 42L and 42R. The intermediate flow paths 42L and 42R of the present embodiment have continuous inner width dimensions in a direction orthogonal to the axial direction Da of the intermediate flow paths 42L and 42R toward the confluence chamber 46 side when viewed from the height direction Z. Changes to. In this case, the region extending linearly in the axial direction Da of the intermediate flow paths 42L and 42R from the portion where the inner width dimension of the intermediate flow paths 42L and 42R is the narrowest is defined as the liquid flow passage region 70. In the fluctuation type discharge path 30, the pair of liquid flow passage regions 70 are provided so as to intersect in the confluence chamber 46 when viewed from the height direction Z.

On the opposite side (upstream side) of the discharge hole 38 with respect to the liquid flow passage region 70, air is formed in a region surrounded by the liquid flow passage regions 70 of each of the pair of intermediate flow paths 42L and 42R and the inner surface of the confluence chamber 46. It is called a pool area 72. In the present embodiment, the inner surface of the confluence chamber 46 forming the air pool region 72 is an upstream side surface 46b located on the upstream side (rear side) of the confluence chamber 46. The air accumulation region 72 is an region in which air A tends to remain in the process of being accumulated until the liquid W2 is filled in the confluence chamber 46. It is considered that this is because in the air pool region 72, the air A is difficult to escape to the discharge hole 38 side due to the liquid flow (jet FbL, FbR) flowing into the confluence chamber 46 from the pair of intermediate flow paths 42L and 42R. ..

The introduction port 64a is preferably opened in the air collecting region 72 in the confluence chamber 46. The introduction port 64a may be opened to the air pool region 72 at least in part. The introduction port 64a of the present embodiment is open only in the air pool region 72.

(B) As a result, it becomes easy to exhaust the residual air A from the air pool region 72 where the air A tends to remain in the fluctuation type discharge path 30 through the air bleeding flow path 64 to the outside. As a result, the amplitude of the wavy flow W1 can be effectively increased in the fluctuation type discharge path 30. Further, by reducing the flow rate of the liquid W2 flowing into the discharge path 30, the vibration cycle can be delayed while ensuring the amplitude of the wavy flow W1, and the appearance can be improved. These effects were obtained by experimental studies. In addition to this, the air A in the confluence chamber 46 can be exhausted at an early stage in the fluctuation type discharge path 30.

From the viewpoint of facilitating the exhaustion of the residual air A from the air pool region 72, the introduction port 64a is opened at a position overlapping the center line CL1 of the discharge hole 38 in the air pool region 72 when viewed from the height direction Z. It is preferable to have it. From another point of view, it is preferable that the introduction port 64a opens in the central portion of the confluence chamber 46 in the left-right direction Y in the air pool region 72. Further, it is preferable that the introduction port 64a is opened at a position away from the inner surface (upstream side surface 46b) of the confluence chamber 46 in the air pool region 72 when viewed from the height direction Z. This is because the liquid W2 is likely to be transmitted to the inner surface of the confluence chamber 46 in the air pool region 72, and the air A is unlikely to remain at a portion connected to the inner surface.

The introduction port 64a of the present embodiment opens to the inner upper surface 48 of the discharge path 30. More specifically, it opens to the inner upper surface 48 in the confluence chamber 46. As a result, the residual air A that floats upward in the discharge path 30 can easily enter the air bleeding flow path 64, and a large amount of the residual air A in the discharge path 30 can be easily exhausted to the outside.

The air bleeding flow path 64 has a discharge port 64b for discharging the air A taken in from the discharge path 30. When the discharge device 10 is in a state of discharging the wavy flow W1, a part of the liquid W2 in the discharge path 30 may leak from the discharge port 64b through the air bleeding flow path 64. If the liquid W2 leaking from the air bleeding flow path 64 is transmitted to a wide range outside the discharge device 10, the appearance is deteriorated.

As a countermeasure, the discharge port 64b of the present embodiment is opened at a position where the liquid W2 discharged from the discharge port 64b can be merged with the wavy flow W1. Specifically, the discharge port 64b of the present embodiment opens to the front surface portion 26a of the apparatus main body 26 above the discharge hole 38. As a result, the liquid W2 discharged from the discharge port 64b in the discharge hole 38 flows down in the direction B, so that the liquid W2 can be merged with the wavy flow W1. Along with this, it is possible to prevent the liquid W2 leaking from the discharge port 64b from being transmitted to a wide range outside the discharge device 10, and a good appearance can be obtained.

In order to obtain the same effect, the opening position of the discharge port 64b is not limited to this. For example, the discharge port 64b may be open to the inner surface of the discharge hole 38. In this case, in order to communicate the space upstream of the discharge hole 38 with the open space 68 by the air bleeding flow path 64, the discharge port 64b is formed at a position where the discharge hole 38 is not always blocked by the wavy flow W1. It suffices if it is open to the inner surface.

The air bleeding flow path 64 of the present embodiment has a first flow path portion 64c extending in the height direction Z from the introduction port 64a of the air bleeding flow path 64 and a second flow extending from the first flow path portion 64c in the front-rear direction X. It has a road portion 64d. The first flow path portion 64c is formed by a hole having a closed cross section formed in the first main body member 34. The second flow path portion 64d is composed of a groove portion having an open cross section formed in the first main body member 34 and a wall surface of the second main body member 36 that covers and closes the opening of the groove portion. As described above, the air bleeding flow path 64 may be configured by combining a plurality of main body members 34 and 36, or may be configured by a single main body member.

(Second Embodiment)
See FIG. The discharge device 10 of the present embodiment is different from the first embodiment in that it includes a closing member 74 that closes the air bleeding flow path 64. The closing member 74 of the present embodiment is arranged inside the air bleeding flow path 64, and closes the air bleeding flow path 64 inside the closing member 74. In addition to this, the air bleeding flow path 64 may be closed by being arranged outside the air bleeding flow path 64 and covering the air bleeding flow path 64.

The closing member 74 has permeability to the gas in the discharge path 30 and impermeable to the liquid W2 flowing into the discharge path 30. The closing member 74 of the present embodiment is configured by using a material satisfying such conditions. This material is, for example, a polyethylene non-woven fabric. As a result, it is possible to prevent the flow of the liquid W2 that tries to pass through the air bleeding flow path 64 from the discharge path 30 while allowing the flow of gas that tries to pass through the air bleeding flow path 64 from the discharge path 30.

With the above configuration, the liquid W in the discharge path 30 that is about to flow out from the air bleeding flow path 64 is blocked by the closing member 74 while discharging the residual air A in the discharge path 30 through the air bleeding flow path 64. Along with this, it is possible to suppress the occurrence of liquid leakage in which the liquid W2 in the discharge path 30 leaks to the outside from the air bleeding flow path 64. In particular, by suppressing the occurrence of liquid leakage outside the discharge device 10, it is possible to avoid a situation in which the liquid W2 is transmitted to a wide range, and a good appearance can be obtained.

(Third Embodiment)
In the present embodiment, the Karman vortex type discharge path 30 using the Karman vortex will be described as the confluence type discharge path 30.

See FIG. This figure is a cross-sectional view of the discharge device 10 of the third embodiment from the same viewpoint as in FIG. Similar to the first embodiment, the discharge path 30 includes an inlet flow path 40 in which the liquid W2 flows in from the upstream side, and a pair of intermediate flow paths 42L and 42R in which the liquid W2 flows in from the inlet flow path 40. Further, as in the first embodiment, the discharge path 30 discharges the merging chamber 46 into which the liquids W2 flowing from each of the pair of intermediate flow paths 42L and 42R merge and the liquid W2 in the merging chamber 46 to the outside. A hole 38 is provided. Although not shown, the discharge path 30 of the present embodiment also has a rectangular shape in a cross section orthogonal to the front-rear direction X. The discharge path 30 is provided with a collision portion 56 in which the liquid W2 flowing in the front side (downstream side) in the front-rear direction X collides with the inlet flow path 40.

The operation of the discharge device 10 described above will be described.

See FIG. The liquid W2 flows into the inlet flow path 40 from the relay flow path 28 through the inflow port 28a. The liquid W2 that has flowed into the inlet flow path 40 flows toward the front side in the front-rear direction X while diffusing from the inflow location. A part of the liquid W2 flowing forward in the inlet flow path 40 collides with the collision portion 56 to form a Karman vortex 100 that alternately passes through the pair of intermediate flow paths 42L and 42R. As a result, a pair of left and right vortex trains 102L and 102R composed of a plurality of Karman vortices 100 are formed in the confluence chamber 46.

The Karman vortex 100 grows in the confluence chamber 46 and collides with the downstream side surface 46a of the confluence chamber 46, and the collision forms a liquid flow passing through the discharge hole 38 while changing the flow direction. The Karman vortex 100 on the left side forms a liquid flow having a velocity vector toward the front side in the front-rear direction X and toward the right side in the left-right direction Y as a liquid flow passing through the discharge hole 38. The Karman vortex 100 on the right side forms a liquid flow having a velocity vector toward the front side in the front-rear direction X and toward the left side in the left-right direction Y as a liquid flow passing through the discharge hole 38.

In this way, the direction of the velocity vector in the left-right direction Y of the liquid flow formed by the Karman vortices 100 of each of the pair of vortex trains 102L and 102R is periodically switched. As a result, the wavy liquid flow, that is, the above-mentioned wavy flow W1 is discharged from the discharge hole 38. The discharge path 30 can swing the traveling direction of the liquid flow discharged from the discharge hole 38 in the left-right direction Y by allowing the liquid flow to flow into the confluence chamber 46 from each of the pair of intermediate flow paths 42L and 42R. There is, and the wavy flow W1 can be discharged by swinging the traveling direction.

See FIG. The apparatus main body 26 of the present embodiment also has an air bleeding flow path 64 that opens to the inner surface of the discharge path 30 on the upstream side of the discharge hole 38. In the case of the Karman vortex type discharge path 30, it is preferable that the introduction port 64a of the air bleeding flow path 64 is open to the air pool region 72 described below. Also in this embodiment, the air pool region 72 is defined by using the liquid flow passage region 70 described in the first embodiment. In the Karman vortex type discharge path 30, the pair of liquid flow passage regions 70 are provided so as not to intersect in the confluence chamber 46 when viewed from the height direction Z.

When viewed from the height direction Z, the region in the confluence chamber 46 is opposite to the discharge hole 38 in the X direction, and the liquid flow passage regions 70 and the confluence chamber 46 of the pair of intermediate flow paths 42L and 42R, respectively. The area surrounded by and is called an air pool area 72. The "region in the confluence chamber 46 opposite to the discharge hole 38 in the X direction" is a position Pa that bisects the dimension La of the confluence chamber 46 in the X direction on the center line CL1 of the discharge hole 38. Therefore, it means a region in the confluence chamber 46 opposite to the discharge hole 38 in the X direction. Similar to the first embodiment, the air accumulation region 72 is an region in which air A tends to remain in the process of being accumulated until the liquid W2 is filled in the confluence chamber 46.

The introduction port 64a of the air bleeding flow path 64 is preferably opened in the air collecting region 72 in the confluence chamber 46. As a result, the effect described in (B) above can be obtained also in the Karman vortex type discharge path 30. That is, in the Karman vortex type discharge path 30, the residual air A can be easily exhausted from the air pool region 72 where the air A tends to remain through the air bleeding flow path 64 to the outside. As a result, the amplitude of the wavy flow W1 can be effectively increased in the Karman vortex type discharge path 30. Further, in the Karman vortex type discharge path 30, the air A in the confluence chamber 46 can be exhausted at an early stage.

As described above, the discharge path 30 may be capable of radially discharging the liquid W2 flowing from the upstream side as a wavy flow W1 from the discharge hole 38. Further, the specific example of the discharge path 30 is not limited to the confluence type.

Other modifications of each component will be described.

Specific examples of the water supply equipment 12 are not particularly limited, and may be, for example, kitchen equipment, washroom equipment, toilet equipment, and the like. Specific examples of the tank body 14 of the water supply facility 12 are not particularly limited, and for example, a sink such as a kitchen sink or a hand wash sink may be used.

The storage tank 18 of the discharge system 16 is not limited to the tank body 14 of the water supply facility 12, and may be provided separately from the tank body 14, for example.

Specific examples of the discharge device 10 are not particularly limited, and for example, a shower device, a faucet device, or the like may be used. The liquid W2 discharged by the discharge device 10 is not limited to water, and may be, for example, a detergent liquid containing a detergent.

The opening position of the inflow port 28a in the discharge path 30 is not particularly limited. The inflow port 28a may be opened, for example, on the inner side surface 52 of the discharge path 30, or may be opened on the inner bottom surface of the discharge path 30 provided on the rearmost side in the front-rear direction X.

The air bleeding flow path 64 may be opened on the inner surface of the discharge path 30 on the upstream side of the discharge hole 38. As a result, although there is a difference to that extent, the change in the shape of the wavy flow due to the residual air A as described in (A) above can be suppressed. Further, in the case of the confluence type discharge device 10, even in the Karman vortex type discharge device 10, if the discharge path 30 is open to the inner surface of the confluence chamber 46, the change in the shape of the wavy flow W1 can be effectively suppressed. .. Further, the air bleeding flow path 64 may be opened to the inner lower surface 50 of the discharge path 30, or may be opened to the inner side surface 52 thereof.

The open space 68 may be open to the atmosphere, and specific examples thereof are not particularly limited. For example, the open space 68 may be another space inside the discharge device 10.

The embodiments and modifications of the present invention have been described in detail above. The above-described embodiments and modifications are merely specific examples for carrying out the present invention. The contents of the embodiments and modifications do not limit the technical scope of the present invention, and many design changes such as modification, addition, and deletion of components can be made without departing from the idea of the invention. In the above-described embodiment, the content that can be changed in design is emphasized by adding the notation "embodiment", but the design change is permitted even if the content does not have such a notation. The hatching attached to the cross section of the drawing does not limit the material of the object to which the hatching is attached.

In addition, any combination of the above components is also effective as an aspect of the present invention. For example, the structure of the air bleeding flow path 64 of the third embodiment and the closing member 74 of the second embodiment may be combined.

Generalization of the invention embodied by the above embodiments and modifications leads to the following technical ideas. Hereinafter, the aspects described in the problem to be solved by the invention will be described.

In the first aspect of the discharge device of the second aspect, the discharge path has an inlet flow path in which the liquid flows in from the upstream side, a pair of intermediate flow paths in which the liquid flows in from the inlet flow path, and the pair of intermediate channels. It has a confluence chamber where liquids flowing in from each of the flow paths merge, and a discharge hole for discharging the liquid in the confluence chamber to the outside, and the discharge path is the pair of intermediate flow paths from the inlet flow path. A wavy flow can be radially discharged from the discharge hole by flowing a liquid into the confluence chamber through each of the above, and the air bleeding flow path may be opened on the inner surface of the confluence chamber. According to this aspect, the residual air in the confluence chamber, which has a large influence on the change in the shape of the wavy flow, can be reduced, and the change in the shape of the wavy flow can be effectively suppressed.

In the second aspect, the discharge device of the third aspect is from the intermediate flow path to the intermediate flow path when viewed from a height direction orthogonal to the center line direction of the discharge hole and the wavy vibration direction formed by the wavy flow. When the region extending linearly in the axial direction of the above is defined as the liquid flow passage region, the liquid flow passage regions of each of the pair of intermediate flow paths are provided so as to intersect in the confluence chamber when viewed from the height direction. , A region surrounded by the liquid flow passage region of each of the pair of intermediate flow paths and the inner surface of the merging chamber on the side opposite to the discharge hole with respect to the liquid flow passage region when viewed from the height direction. The air bleeding flow path may be opened in the air pool area. According to this aspect, in the fluctuation type discharge path, the residual air can be easily exhausted from the air accumulation region through the air bleeding flow path to the outside, and the amplitude of the wavy flow can be effectively increased.

In the second aspect, the discharge device of the fourth aspect is from the intermediate flow path to the intermediate flow path when viewed from a height direction orthogonal to the center line direction of the discharge hole and the wavy vibration direction formed by the wavy flow. When the region extending linearly in the axial direction of the above is defined as the liquid flow passage region, the liquid flow passage regions of the pair of intermediate flow paths are provided so as not to intersect in the confluence chamber when viewed from the height direction. When viewed from the height direction, the discharge hole is a region opposite to the center line direction in the merging chamber, and the liquid flow passage region and the merging chamber of each of the pair of intermediate flow paths are located. When the region surrounded by the inner surface is defined as the air pool region, the air bleeding flow path may be opened in the air pool region. According to this aspect, in the Karman vortex type discharge path, the residual air can be easily exhausted from the air accumulation region through the air bleeding flow path to the outside, and the amplitude of the wavy flow can be effectively increased.

In the discharge device of the fifth aspect, in any one of the first to fourth aspects, the discharge path has an inner upper surface and an inner lower surface facing in the vertical direction, and the air bleeding flow path opens in the inner upper surface. You may. According to this aspect, the residual air floating upward in the discharge path is likely to enter the air bleeding flow path, and a large amount of the residual air in the discharge path is easily exhausted to the outside.

In the discharge device of the sixth aspect, in any one of the first to fifth aspects, the air bleeding flow path has a discharge port for discharging the air taken in from the discharge path, and the discharge port is the discharge port. The liquid discharged from the water may be opened at a position where it can be merged with the wavy flow. According to this aspect, it is possible to prevent the liquid leaking from the discharge port from being transmitted to a wide range outside the discharge device, and a good appearance can be obtained.

In any one of the first to sixth aspects, the discharge device of the seventh aspect includes a closing member that closes the air bleeding flow path, and the closing member has permeability to gas and to the liquid. It may be opaque. According to this aspect, it is possible to suppress the occurrence of liquid leakage in which the liquid in the discharge path leaks to the outside from the air bleeding flow path.

CL1 ... center line, W1 ... wavy flow, CL2 ... axis line, 10 ... discharge device, 26 ... device body, 30 ... discharge path, 38 ... discharge hole, 38a ... inlet, 38b ... outlet, 40 ... inlet flow path, 42L ... Intermediate flow path, 46 ... Confluence chamber, 48 ... Inner upper surface, 50 ... Inner lower surface, 64 ... Air bleeding flow path, 64b ... Discharge port, 70 ... Liquid flow passage area, 72 ... Air pool area, 74 ... Closing member.

Claims (7)

Equipped with a device body with a discharge path formed inside
The discharge path has a discharge hole formed at the downstream end of the discharge path, and the liquid flowing from the upstream side can be radially discharged as a wavy flow from the discharge hole.
A discharge device in which an air bleeding flow path that opens on the inner surface of the discharge path is formed in the device main body on the upstream side of the discharge hole. The discharge path is
The inlet flow path where the liquid flows in from the upstream side,
A pair of intermediate channels through which liquid flows from the inlet channel,
A confluence chamber where the liquids flowing in from each of the pair of intermediate channels merge,
It has the discharge hole for discharging the liquid in the confluence chamber to the outside,
The discharge path can radially discharge a wavy flow from the discharge hole by allowing a liquid to flow into the confluence chamber from the inlet flow path via each of the pair of intermediate flow paths.
The discharge device according to claim 1, wherein the air bleeding flow path opens to the inner surface of the confluence chamber. The liquid flow passes through a region linearly extending from the intermediate flow path in the axial direction of the intermediate flow path when viewed from a height direction orthogonal to the center line direction of the discharge hole and the vibration direction of the wavy shape formed by the wavy flow. When it is an area
The liquid flow passage regions of each of the pair of intermediate flow paths are provided so as to intersect in the confluence chamber when viewed from the height direction.
A region surrounded by the liquid flow passage region of each of the pair of intermediate flow paths and the inner surface of the confluence chamber on the side opposite to the discharge hole with respect to the liquid flow passage region when viewed from the height direction. When used as an air pool area
The discharge device according to claim 2, wherein the air bleeding flow path opens in the air pool region. The liquid flow passes through a region linearly extending from the intermediate flow path in the axial direction of the intermediate flow path when viewed from a height direction orthogonal to the center line direction of the discharge hole and the vibration direction of the wavy shape formed by the wavy flow. When it is an area
The liquid flow passage regions of each of the pair of intermediate flow paths are provided so as not to intersect in the confluence chamber when viewed from the height direction.
When viewed from the height direction, the discharge hole is a region opposite to the center line direction in the confluence chamber, and the liquid flow passage region of each of the pair of intermediate flow paths and the inner surface of the confluence chamber. When the area surrounded by is the air pool area,
The discharge device according to claim 2, wherein the air bleeding flow path opens in the air pool region. The discharge path has an inner upper surface and an inner lower surface that face each other in the vertical direction.
The discharge device according to any one of claims 1 to 4, wherein the air bleeding flow path opens on the inner upper surface. The air bleeding flow path has a discharge port for discharging air taken in from the discharge path.
The discharge device according to any one of claims 1 to 5, wherein the discharge port is opened at a position where the liquid discharged from the discharge port can be merged with the wavy flow. A closing member for closing the air bleeding flow path is provided.
The discharge device according to any one of claims 1 to 6, wherein the closing member is permeable to gas and impermeable to liquid.

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