JP6727540B2 - Spraying unit - Google Patents

Description

The present invention relates to a spray unit that sprays and discharges water.

It is known that spray water discharge is effective as a means for spraying a small amount of water over a wide area. (For example, Patent Document 1)

JP, 11-241381, A

However, in the case of spray water discharge, it is necessary to narrow down the spray port in order to make the spray water into a mist state, and the structure is such that the pressure in the flow path tends to increase before reaching the spray port. Furthermore, since the spray port is narrowed down, it may be easily blocked by a finger or the like. When blocked, the pressure increase in the flow channel becomes remarkable, and there is a risk that the connecting portion of the flow channel will come off and water will leak.

The present invention has been made in order to solve the above problems, and an object of the present invention is to suppress a significant pressure increase in the flow path due to the clogging of the spray port.

In order to achieve the above object, in the spray unit according to claim 1, an inflow port for receiving water supplied from the outside and a mist-like water discharge communicating with the inflow port and having an inner diameter smaller than that of the inflow port. In a spray unit including a spray port that performs the above, and a spray guide part that is in communication with the spray port and in which a restricting space that restricts the water discharge direction toward the downstream side is formed, inside the downstream end surface of the spray guide part. peripheral is formed larger than the inner circumference of the spray nozzle, wherein the spray guide portion have a deoccluding space communicating the inside and the outside of the regulating space provided on the downstream end face of the spray guide portion The injection port has a groove extending from the inner circumference of the spray guide section to the outer peripheral end of the spray guide section, the internal space of the groove serves as the blocking prevention space, and the spray guide section is a diffusion slope section. And a guide part communicating with the downstream end of the diffusion slope part and having an inner diameter larger than the downstream end of the diffusion slope part, wherein a tangent line at the downstream end of the diffusion slope part is a side surface of the guide part and the It is characterized in that it is configured so as not to intersect with the lateral end of the injection port .
Therefore, it is possible to suppress direct prevention of the spray port by the spray guide part, and even if the tip of the spray unit is pressed by the user's finger or the like during water discharge, water will escape from the inside of the blocking prevention space provided in the spray guide part to the outside. .. Therefore, the spray port inside the spray guide portion is hard to be blocked, and a remarkable pressure rise in the flow path does not occur, so that the connection portion of the apparatus main body can be prevented from coming off and water leakage can be prevented. Further, even if the tip of the spray unit is pressed with a finger or the like, water will escape to the outside from the internal space of the groove provided in the spray guide portion, so that a significant pressure increase in the flow path can be prevented.

Further, in the spray unit according to claim 2, the downstream end surface of the spray guide portion where the injection port and the groove are provided is inclined toward the upstream side as it goes in the circumferential direction. ..

Further, in the spray unit according to claim 3, a plurality of the grooves are provided at symmetrical positions so as to extend radially around the spray port.
Therefore, no matter which direction the tip of the spray unit is held by a finger or the like, it is easy to let the water escape to the outside, and it is easy to suppress a significant pressure increase in the flow path. Further, even when a part or all of the spray unit is configured to be removable, the directionality is lost and the spray unit is easy to assemble.

Further, in the spray unit according to claim 4, wherein the depth of the pre Kimizo, characterized in that the shallower than the depth of the guide portion.
Therefore, the blocking prevention space can be provided while maintaining the strength of the guide portion. Further, since the groove does not become excessively deep, dirt is unlikely to adhere, and even if it adheres, it is easy to remove. Furthermore, since the groove does not reach the bottom of the guide portion, even if water droplets remain at the tip of the spray port, it is possible to prevent the water droplet from being carried to the outer peripheral side through the groove due to the capillary phenomenon.

Further, in the spray unit according to the fifth aspect, the inner circumference of the guide portion is polygonal.
Therefore, it is possible to easily attach and detach by inserting a hexagon wrench or the like into the guide portion.

Further, in the spray unit according to the sixth aspect, there is a step between the guide portion and the downstream end of the diffusion sloped portion.
Therefore, even if a hexagon wrench or the like is inserted into the guide portion for attachment/detachment, the hexagon wrench does not come into contact with the diffusion inclined portion, and there is no risk of damaging the diffusion inclined portion. This makes it possible to prevent the diffusion slope from being damaged and disturbing the water discharge while facilitating attachment and detachment.

Further, in the spray unit according to claim 7, the shape of the downstream end surface of the spray guide portion is formed into a wave surface shape, and the shape of the downstream end surface is recessed from a protruding end protruding toward the downstream side. The space is the blocking prevention space.
Therefore, since the downstream end face of the spray unit has a wavy surface and an uneven surface, water escapes from the space recessed from the projecting end in the downstream direction to the outside, preventing a significant pressure increase in the flow path. You can
Further, since the downstream end surface of the spray unit is formed into a curved surface, it is possible to suppress the attachment of dirt.

According to the present invention, it is possible to suppress direct prevention of the spray opening by the spray guide portion, and even if the tip of the spray unit is pressed by the user's finger or the like during water discharge, water is provided inside the blockage prevention space provided in the spray guide portion. Since there is no leakage from the outside to the outside, there is no risk of the spray port inside the spray guide part being blocked, and there is no significant pressure rise in the flow path, so it is possible to prevent the connection part of the device body from leaking and water leakage. ..

It is a perspective view showing the vanity table provided with the spraying device which built in the spraying unit concerning the embodiment of the present invention. It is a front view of the spraying device concerning the embodiment of the present invention. It is a perspective view showing a spraying unit concerning an embodiment of the present invention. It is an AA sectional view of the spray unit in FIG. It is sectional drawing similar to FIG. 4 which showed the modification of the spray unit similarly to FIG.

Embodiments of the present invention will be described below with reference to the accompanying drawings. In order to facilitate understanding of the description, the same constituent elements in each drawing are denoted by the same reference numerals as much as possible, and redundant description will be omitted.

FIG. 1 is a perspective view showing a bathroom vanity provided with a spraying device incorporating a spraying unit according to an embodiment of the present invention.
As shown in FIG. 1, the vanity 1 includes a washbasin 10, a support 20, and a faucet system 30.

In this specification, the front side as viewed from the user is defined as "front", and the opposite direction is defined as "rear". Further, the direction perpendicular to the front-rear direction and the up-down direction is the left-right direction.

The washbasin 10 has a washbasin 11 formed in a concave shape that is recessed downward, and a drain 12 provided at the bottom of the washbasin 11. The drainage port 12 is connected to a drainage pipe (not shown), and causes the water discharged to the washbasin 11 to flow into the drainage pipe.

The support base 20 supports the washbasin 10 from below. In addition, the support base 20 also functions as a cabinet that can store articles.
The support base 20 may not have a storage function.
Further, the washbasin 10 may be directly attached to a wall surface of a washroom, for example. That is, the support base 20 is provided as needed and can be omitted.

The faucet system 30 includes a water discharge device 31 that discharges water toward the wash bowl 11 of the washbasin 10, a water faucet operating unit 32 that adjusts the flow rate and temperature of the water discharge device 31, and the wash bowl 11 of the washbasin 10. And a spraying device 33 that discharges the functional water toward.
The water discharged from the water discharger 31 is tap water (tap water).

The spraying device 33 has an operating unit 37 for operating the discharge water, and discharges the functional water according to the operation of the operating unit 37 by the user. The spray device 33 discharges water for a predetermined time (for example, 10 seconds) according to the operation of the operation unit 37, and automatically stops the water discharge according to the lapse of the predetermined time. Further, the spraying device 33 may discharge water by the first operation of the operation unit 37 and stop the water discharge by the second operation of the operation unit 37.

The ejection port 116 provided for discharging the functional water from the inside of the spray device 33 is arranged below the lower end of the water discharge device 31. As a result, it is possible to prevent the functional water discharged from the spray device 33 from splashing on the water discharge device 31. Therefore, it is possible to prevent the user from directly touching the functional water adhering to the water spouting device 31, or accidentally ingesting the functional water mixed in the water spouting from the water spouting device 31.

A water supply device 34 is connected to the spraying device 33 via electric wiring and a water-passing member. The water supply device 34 is provided inside the support base 20. Further, the water supply device 34 is connected to a water supply source and a power supply, receives water from the water supply source, and receives power from the power supply. By applying a voltage to the water supply device 34 by this power source, the water in the water supply device 34 can be electrolyzed. Hypochlorous acid water is obtained by electrolyzing the water of the water supply device 34, and the water supply device 34 supplies the spray device 33 with hypochlorous acid water, which is a functional water having a sterilizing function, through the water passage member. Supply.

When the user operates the operation unit 37 provided in the spray device 33, an operation signal is transmitted from the spray device 33 to the water supply device 34. Upon receiving the operation signal, the water supply device 34 generates functional water from the water supplied from the water supply source and sends the generated functional water to the spray device 33. Thereby, the functional water is discharged from the spraying device 33 in accordance with the operation of the operation unit 37 by the user. Further, the functional water may be automatically discharged from the spraying device 33 regardless of the operation of the operation unit 37 when a predetermined time elapses. Hereinafter, the water discharge performed according to the operation of the operation unit 37 will be referred to as “manual water discharge”, and the water discharge performed regularly regardless of the operation of the operation unit 37 will be referred to as “regular water discharge”.

In the vanity table 1, by discharging the functional water from the spraying device 33 to the vanity bowl 11, it is possible to suppress the growth of bacteria in the drainage port 12 and keep the basin 10 clean. Further, it is also possible to sterilize these by discharging functional water onto a toothbrush, a cup or the like.

<Structure of atomizer>
FIG. 2 is a front view of the spray device according to the embodiment of the present invention.
The spraying device 33 includes a casing 35 in which various members are housed, a spraying unit 36 which is housed in the casing 35 to form mist-like water discharge, and an operating portion 37 which is provided on the front surface of the casing 35. It is configured.

The casing 35 has a wedge shape formed so that the thickness in the front-rear direction becomes thinner as it goes upward from the bottom surface when viewed from the front. The casing 35 is hollow and has an internal space. A description of the internal space of the casing 35 is omitted.

The spray unit 36 is fixed to the bottom surface of the casing 35. The spray unit 36 has an injection port 116. The spray unit 36 is held by the casing 35 and discharges the functional water downward from the bottom surface. The spray unit 36 discharges the functional water supplied from the water supply device 34 from the injection port 116 to the wash bowl 11.

The operation unit 37 is provided above the ejection port 116. The operation unit 37 is provided on the front surface of the casing 35. As a result, the operation unit 37 faces forward, and the user can easily operate the operation unit 37.

<Structure of spray unit>
The structure of the spray unit will be described with reference to FIGS. 3 to 4.
FIG. 3 is a perspective view of the spray unit according to the embodiment of the present invention.

The spray unit 36 has a tubular portion 110 provided with an inflow port 111 at an upstream end and a spray port 112 at a downstream end, an upstream end communicating with a downstream end of the tubular part 110, and an injection port at a downstream end. 116, and a spray guide portion 120 that forms a regulation space S1 that regulates the water discharge direction toward the ejection port 116.

A male screw portion 113 is formed on the outer peripheral surface of the upstream portion of the tubular portion 110. Further, a substantially circular opening corresponding to the outer diameter of the tubular portion 110 of the spray unit 36 is provided on the bottom surface of the casing 35 shown in FIG. A female screw portion (not shown) corresponding to the male screw portion 113 of the spray unit 36 is formed on the substantially circular opening surface of the casing 35.

At the downstream end of the spray guide portion 120, a groove 121 extending from the injection port 116 that is the inner circumference of the spray guide portion 120 to the outer peripheral end is formed. Since the groove 121 extends to the side surface of the spray guide portion 120, even if the injection port 116 is closed, water is drained from the side surface to the outside through the internal space of the groove 121, which is the blocking prevention space S2. It is possible to prevent a remarkable increase in pressure.

The shape of the injection port 116 is a regular hexagon. The groove 121 is provided at three places and extends from the regular hexagonal side to the outer peripheral edge. These three grooves 121 are provided at symmetrical positions so as to extend radially around the spray port 112. Since the injection port 116 has a regular hexagonal shape, a hexagonal wrench or the like can be inserted and rotated, which facilitates attachment/detachment with a tool.
The shape of the injection port 116 may be various polygons, and a tool scale such as serration may be provided on the inner peripheral surface of the spray guide portion.

FIG. 4 is a cross-sectional view taken along the line AA of the spray unit in FIG.

The inner peripheral surface of the spray unit 36 is composed of a rectilinear flow supply channel 114, a swirl flow channel 115, a jet, and a spray guide section 120.

The rectilinear flow supply flow path 114 connects between the inflow port 111 and the spray port 112. The straight flow supply channel 114 extends linearly from the inflow port 111 toward the spray port 112. As a result, the rectilinear flow supply flow path 114 supplies a part of the functional water flowing from the inflow port 111 to the spray port 112 as a rectilinear flow.

The swirl flow supply passage 115 is provided in parallel with the straight flow supply passage 114, and connects the inflow port 111 and the spray port 112. The swirl flow supply flow path 115 extends from the inflow port 111 in parallel with the central axis CA, and is bent substantially vertically to be connected to the side of the rectilinear flow supply flow path 114. The swirl flow supply channel 115 supplies a part of the functional water flowing from the inflow port 111 to the spray port 112 as a swirl flow around the central axis CA.

The spray guide part 120 communicates with an inverted funnel-shaped diffusion slope part 122 whose diameter gradually increases toward the downstream side and a downstream end of the diffusion slope part, and has a larger inner diameter than the downstream end of the diffusion slope part. And a part 123.
By providing the guide portion 123 on the downstream end side of the diffusion inclined portion 122, it is possible to suppress contact from the outside with respect to the upstream side of the diffusion inclined portion 122 and prevent damage. This can prevent the spray water from being disturbed.

The spray guide portion 120 may gradually increase in diameter from the spray port 112 to the spray port 116. In this way, the target position for spraying the functional water from the injection port 116 can be adjusted by the way of expanding the diameter.

When the user starts spray water discharge, the functional water supplied from the water supply device 34 enters the spray unit 36 through the inflow port 111. Then, it passes through the straight flow supply channel 114 or the swirl flow channel 115 to reach the spray port 112. The spray port 112 has an inner diameter smaller than that of the inflow port 111, and narrows the flow path through which the functional water passes, so that the functional water is in a mist state. The functional water in the mist state is discharged from the injection port 116 to the outside of the spray unit 36 via the spray guide unit 120.
The inflow port 111 may receive tap water from a water pipe provided on the wall.

Here, the depth d of the groove 121 is configured to be shallower than the depth D of the guide portion 123. In other words, the groove 121 is formed by cutting out a part of the guide portion 123. With this configuration, the strength of the guide portion 123 can be secured as compared with the case where the groove 121 is formed with the same depth as the guide portion 123. Further, dirt is less likely to adhere to the groove 121, and even if dirt is attached, it is easy to remove. Further, when the residual water remaining near the downstream end of the diffusion sloping portion 122 is generated when the water is stopped, if the depth of the groove 121 is the same as that of the guide portion 123, the residual water is transported to the outer peripheral portion by the capillary phenomenon. However, by making the groove 121 shallower than the guide portion 123, this can be prevented.

The inner diameter of the guide portion 123 is preferably such that it does not interfere with the spread of the water sprayed from the diffusion sloped portion 122 (the range indicated by the chain double-dashed line in FIG. 4). As a result, contact between the water discharge and the guide portion does not occur, and there is no risk of affecting the water discharge.

Further, a step Δ is provided between the guide portion 123 and the downstream end of the diffusion slope portion 122. As a result, even when a tool such as a hexagon wrench is inserted into the guide portion 123, it is possible to prevent the tool from coming into contact with the diffusion inclined portion 122. For this reason, it is possible to prevent the diffusion sloped portion 122 from being damaged, and to prevent the spray water from being disturbed.

<Structural modification of spray unit>
A modified example of the spray unit according to the embodiment of the present invention will be described below.
FIG. 5 is a sectional view similar to FIG. 4, showing a modified example of the spraying unit, similar to FIG.
In the spray unit 36A in the modified example, the groove 121 is not provided in the downstream end surface of the guide portion 123, but the downstream end surface of the guide portion 123 is formed in a wavefront shape 123a in the circumferential direction. In other words, the downstream end surface of the guide portion 123 is formed so that the uneven surface is alternately repeated in the circumferential direction. Further, the wavefront shape 123a is formed on the uneven surface in the circumferential direction, but the shape of the surface does not change in the radial direction from the injection port 116 to the outer peripheral end of the guide portion 123, in other words, it is formed on the uneven surface. Not not.
As described above, the downstream end surface of the guide portion 123 is not flush with each other because the concave surface and the convex surface are formed in the circumferential direction.
That is, on the downstream end surface of the guide portion 123, a recessed space is formed between the downstream end portion 123b and the upstream end portion 123c to form the blocking prevention space S2.
Therefore, even if the downstream end of the spray guide portion 120 is closed, the water in the flow path escapes from the blockage prevention space S2 to the outside, so that a significant pressure increase in the flow path can be prevented.
Further, since the downstream end face has a wavefront shape and a curved surface, it is possible to suppress the attachment of dirt.

The embodiments of the present invention have been described above. However, the present invention is not limited to these descriptions. A person skilled in the art appropriately changes the design of the above-described embodiment is also included in the scope of the present invention as long as it has the features of the present invention. For example, the shape, size, material, arrangement, etc. of each element included in the faucet system 30 and the like are not limited to the exemplified ones but can be appropriately changed.
Further, each element included in each of the above-described embodiments can be combined as long as technically possible, and a combination of these is also included in the scope of the present invention as long as it includes the features of the present invention.

DESCRIPTION OF SYMBOLS 1... Vanity 10... Washbasin 11... Wash bowl 12... Drain 20... Support stand 30... Faucet system 31... Water discharge device 32... Faucet operation part 33... Spraying device 34... Water supply device 35... Casing 36, 36A ... Spraying unit 37... Operation part 110... Cylindrical part 111... Inflow port 112... Spraying port 113... Male screw part 114... Straight flow supply channel 115... Swirling flow channel 116... Injection port 120... Spraying guide part 121... Groove 122... Diffusion inclined part 123... Guide part 123a... Wavefront shape 123b... Downstream end 123c... Upstream end S1... Restricted space S2... Blockage prevention space
CA... central axis

Claims (7)

An inlet for receiving water supplied from the outside,
A spray port that communicates with the inflow port and sprays mist-like water having an inner diameter smaller than that of the inflow port,
In a spray unit including a spray guide portion that is in communication with the spray port and in which a regulation space that regulates the water discharge direction toward the downstream side is formed,
The inner circumference of the downstream end face of the spray guide portion is formed larger than the inner circumference of the spray port,
Wherein the spray guide portion have a deoccluding space communicating the inside and the outside of the regulating space,
The spray port provided on the downstream end face of the spray guide part has a groove extending from the inner circumference of the spray guide part to the outer peripheral end of the spray guide part, and the internal space of the groove serves as the blockage prevention space. And
The spray guide portion includes a diffusion slope portion and a guide portion that communicates with a downstream end of the diffusion slope portion and has an inner diameter larger than a downstream end of the diffusion slope portion,
The spray unit is configured such that a tangent line at a downstream end of the diffusion sloping portion does not intersect a side surface of the guide portion and a lateral end of the injection port . The spray unit according to claim 1, wherein the downstream end surface of the spray guide portion on which the injection port and the groove are provided is inclined toward the upstream side toward the circumferential direction. The spray unit according to claim 1 or 2, wherein a plurality of the grooves are provided at symmetrical positions so as to extend radially around the spray port. Spray unit according to prior depth Kimizo is, one to one of claims 1 to 3, wherein the shallower than the depth of the guide portion. The spray unit according to claim 4, wherein an inner circumference of the guide portion is polygonal. The spray unit according to claim 4 or 5, wherein there is a step between the guide part and a downstream end of the diffusion slope part. The shape of the downstream end surface of the spray guide portion is formed into a wavefront shape,
The spray unit according to claim 1, wherein, in the shape of the downstream end face, a space recessed from a projecting end projecting to the downstream side is the blocking prevention space.

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