JP6156777B2 - Water discharge device - Google Patents

Description

  The present invention relates to a water discharge device.

  2. Description of the Related Art Conventionally, in order to make water discharge more beautiful in a faucet device, there has been known one that rectifies the flow of discharged water by providing a rectifying member in a water discharge portion for discharging water. (For example, refer to Patent Document 1.)

  Conventionally, as such a rectification member, what employ | adopted the mesh-shaped rectification network described in patent document 1 is generally known. At this time, in order to more efficiently discharge the air remaining inside the water discharge port and eliminate the mixing of air, there has been proposed one in which a difference in water flow resistance of the rectifying member is provided. (Patent Document 2)

  All of the rectifying members that have been proposed so far are aimed at equalizing the flow of fluid at the water outlet. However, when the flow of fluid is uniform at the spout, the fluid near the outer circumference gradually decreases in speed due to resistance with air as the spout advances through the air, creating a flow velocity difference from the fluid in the inner circumference. As a result, the water discharge form is disturbed. In other words, there is a problem that the water discharge shape that is uniform in the vicinity of the water discharge port is disturbed in a place that has traveled a certain distance.

  In other words, the rectifying member that has been proposed so far may be sufficient when the water discharged from the water outlet is a very short distance, but for example when water is discharged from an overhead shower provided near the ceiling in the bathroom. In this case, the shape of the water discharge is disturbed until the user lands on the user's body or floor surface, and the water discharge cannot be made beautiful until the end.

JP 2001-20332 A JP 2010-77731 A Japanese Utility Model Publication No. 6-74667 Japanese Utility Model Publication 2-93370 Japanese Utility Model Publication No. 62-11495

  The present invention has been made in order to solve the above problems, and the problem of the present invention is that the water discharge can maintain the water discharge shape without causing water discharge cracking or air mixing over a long distance from the water discharge port. Is to provide a device.

In order to achieve the above object, claim 1 is a water discharge device for discharging a fluid, comprising a water discharge port for discharging the fluid, and a rectification unit provided upstream of the water discharge port, wherein the rectification unit Has a shielding part for blocking the flow of fluid and a water flow part provided around the shielding part in a cross section perpendicular to the fluid flow.
With this configuration, the fluid that has flowed into the rectifying unit once hits the shielding unit and stays on the upstream side of the shielding unit. The staying fluid flows so as to be pushed downstream through the water flow portion by the pressure from the upstream. At this time, the flow direction of the fluid is adjusted by the water passing portion and is uniformized in the entire fluid. The fluid that has passed through the water passing portion is divided into a component that goes straight to the water outlet and a component that moves to the central portion by the back surface of the shielding portion due to surface tension or the like. And it discharges from a single spout as an integral fluid again. At this time, the component moving to the center portion has a long moving distance, a broken flow, and the like, energy loss occurs, and the flow velocity decreases. On the other hand, there is almost no energy loss for the component that goes straight to the spout, and the flow velocity hardly changes. For this reason, the initial velocity of the fluid discharged from the discharge port at the water discharge port is higher at the flow velocity on the outer peripheral side with a large amount of components traveling straight ahead than the component moved to the central portion. After that, as the fluid travels through the air, the flow velocity on the outer peripheral side gradually decreases due to resistance with the air, but the flow velocity on the outer peripheral side is faster than the flow velocity on the central portion at the time of the spout. The water discharge shape can be maintained over a long distance from the water discharge port.
Moreover, by comprising in this way, it becomes possible to implement | achieve this invention easily by inserting a disk member inside a normal water flow pipe. Further, even when the water pipe is made of a highly durable metal member, the disk member can be made of another material having high workability such as resin.

In the present invention, it is preferable to further include a water conduit connected to the rectifying unit on the upstream side of the rectifying unit, and the inner diameter cross-sectional area of the water conduit is in the connection region with the rectifying unit. The inner diameter region of the water pipe overlaps with the shielding portion when viewed from the direction in which the fluid in the water pipe flows smaller than the area.
By comprising in this way, it becomes possible for the water supplied from the water flow pipe to hit a shielding part more reliably.

Preferably in this invention, it has a wall surface between the said shielding part and the said water flow part further.
By comprising in this way, in order for the water flow which hits the shielding part to reach a water flow part, it will be necessary to get over a wall surface, Therefore It becomes possible to retain water more reliably.

In the present invention, it is preferable that the rectification unit further includes at least one rectification member on the downstream side of the water flow unit.
With this configuration, even if the fluid supplied to the rectifying unit is a turbulent flow, it is possible to align the velocity vector by passing through the rectifying member and rectify the laminar flow.

In the present invention, it is preferably further installed near the ceiling of the bathroom.
By comprising in this way, it becomes possible to provide the water discharging apparatus which does not disturb the water discharging shape over a long distance from the ceiling of the bathroom to the floor.

  According to the present invention, there is an effect that the water discharge shape can be maintained over a long distance from the water discharge port.

It is a perspective view which shows the ceiling embedding shower in the Example of this invention. It is a schematic diagram which shows the bathroom in which the ceiling embedded shower in the Example of this invention was installed. It is sectional drawing which shows the ceiling embedded shower in the Example of this invention. It is sectional drawing which shows the rectification water discharge part vicinity in the Example of this invention. It is a disassembled perspective view of the rectification water discharge part vicinity in the Example of this invention. It is a schematic diagram which shows the flow of the water near the rectification water discharging part in the Example of this invention. It is sectional drawing which shows the rectification water discharge part vicinity in the modification of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. FIG. 1 is a perspective view of a ceiling-embedded shower 1 according to an embodiment of the present invention. Literally, the shower 1 embedded in the ceiling is embedded in the ceiling of the bathroom 3 as shown in FIG.

As shown in FIG. 1 and FIG. 3, the ceiling-embedded shower 1 includes a watering plate 11 exposed in the bathroom 3, and a rectifying and discharging part 5 is provided at the approximate center of the surface. The water spray plate 11 is provided with a water spray hole 13, a swing water discharge port 15, and an air suction port 17 in addition to the rectifying water discharge unit 5, and the water spray hole 13 is air mixed with air sucked from the air suction port 17. The mixed water discharge is configured such that massage water discharged by the swing nozzle (not shown) provided inside the swing water outlet 15 is discharged.
The water discharged from the rectifying water discharging unit 5 is a thick rectified water discharging and has a water discharging shape with the same diameter until it comes into contact with the floor surface 33 in the bathroom 3 as shown in FIG.

  The rectifying water discharge unit 5, the water spray hole 13 and the swing water discharge port 15 are respectively connected to different embedded pipes 31, 33 and 35. Each embedded pipe is configured to be selectively connected to a water supply source by an operation member 37 installed on the wall surface. The user can change each water discharge mode and perform water discharge from the ceiling-embedded shower 1 by operating the operation member 37. At this time, a water supply pipe 38 and a hot water supply pipe 39 are connected to the operation member 37, and the water discharge temperature can be adjusted by adjusting the mixing ratio according to the operation of the user. In changing the water discharge mode, stopping water, and adjusting the water discharge temperature, it is possible to use known structures and methods, respectively.

  An enlarged view of the vicinity of the rectifying and discharging unit 5 is shown in FIG. The rectifying water discharger 5 has a water discharge port 51 at the most downstream side, at a position exposed on the surface of the ceiling embedded shower 1. A water flow pipe 53 is provided on the upstream side, and water supply from the embedded pipe 31 can be introduced. The water outlet 51 preferably has a circular cross section, and most preferably a perfect circle.

  A disk member 7 is provided between the water conduit 53 and the water discharge port 51. The disk member 7 has a shielding portion 71 at the center portion and a plurality of water passage holes 73 around the shielding portion 71. The diameter of the downstream side of the water flow pipe 53 is increased, and a pressure chamber 55 is formed between the disk member 7 and the downstream side. At this time, the inner diameter cross-sectional area of the water flow pipe 53 is smaller than the area of the shielding part 71. Furthermore, the inner diameter region of the water conduit 53 is positioned so as to overlap the shielding portion 71 when viewed from the direction of the water flow along the tube axis of the water conduit 53. More preferably, when viewed from the above direction, the entire inner diameter region of the water flow pipe 53 is positioned so as to be accommodated in and overlapped with the shielding part 71, so that the fluid flowing from the water flow pipe 53 more reliably hits the shielding part 71. It can be retained once. In addition, a plurality of rectifying nets 91 including mesh nets are provided as rectifying members in the downstream portion of the disk member 7.

  FIG. 5 shows an exploded perspective view of the rectifying water discharge unit 5. The rectifying water discharge unit 5 is configured by attaching a water discharge port forming member 9 to the ceiling-embedded shower 1. At this time, the disk member 7 and the rectifying net 91 are held in a form sandwiched between the water discharge port forming member 9 and the water pipe 53. The water discharge port forming member 9 is provided with a flange portion 93 around it. A plurality of screw holes 95 are provided in the flange portion 93, and the flange portion 93 is attached by being screwed to the ceiling embedded shower 1 through the screw holes 95. The water discharge port forming member 9 may be fixed by screwing the outer periphery of the water discharge port forming member 9 by rotating the water discharge port forming member 9 itself, or by other methods such as snap fitting or adhesion. In the present embodiment, the rectifying unit in one aspect of the present invention is the shielding unit 71, the water passage hole 73 (the disk member 7 when these are formed in a common disk member), the pressure chamber 55, It is comprised by the spout formation member 9, More preferably, you may further provide the below-mentioned rectification | straightening member (In this embodiment, the rectification | straightening net | network 91).

  The flow of water in the rectifying and discharging unit 5 is schematically shown in FIG. The water supplied through the embedded pipe 13 first flows into the water pipe 53 (arrow A). The water that has flowed into the pressure chamber 55 from the water flow pipe 53 once stays in the pressure chamber 55 by colliding with the shielding portion 71 or colliding with the water flowing backward by colliding with the shielding portion 71 (arrow B). The inside of the pressure chamber 55 is in a state where water pressure rises. The water staying inside the pressure chamber 55 is pushed out by the flow from the upstream and flows out to the downstream side through the water passage hole 73 (arrow C). Thereafter, the water flowing out from the water passage 73 is divided into a flow (arrow C1) that goes straight to the water outlet 51 as it is and a flow (arrow C2) that moves in the center direction due to surface tension and negative pressure generated inside. At this time, the flow moving toward the center (arrow C2) has a longer distance to reach the spout 51 than the flow straight to the spout 51 (arrow C1), and pressure loss due to the flow being bent. For example, energy loss increases and speed reduction increases. That is, when the water reaches the water outlet 51, the flow (arrow D1) of the outer peripheral portion that has traveled straight to the water outlet 51 has a higher flow velocity than the flow (arrow D2) at the center, and the water outlet 51 In this case, the initial velocity of the fluid to be discharged is faster on the outer peripheral side than on the central portion thereof.

  Both the flow going straight to the water discharge port 51 (arrow C1) and the flow moving toward the center (arrow C2) pass through the plurality of rectifying networks 91 and reach the water discharge port 51. When the fluid passes through the rectifying network 91, the velocity vectors are aligned in the passing direction, and the fluid E discharged from the outlet 51 is discharged as a laminar flow. At this time, the rectification action increases as the number of rectification networks 91 is increased or the thickness of the rectification network 91 is increased, but these can be appropriately designed according to the upstream flow path, the assumed water supply amount, and the like. . Moreover, it replaced with the rectifying net | network 91, and the thing which employ | adopted the coil-shaped elastic body (refer patent document 3), the rectifying member (for example, refer patent document 4) which employ | adopted the vertical and horizontal partition wall, a belt | band | zone of brass or stainless steel, etc. You may utilize the rectification | straightening member (for example, refer patent document 5) using the elastic material which bent the board or processed resin. At this time, the direction in which water passes through the rectifying network 91 (rectifying member) is aligned with the direction in which water passes through the rectifying unit. This configuration is advantageous because speed vectors that are aligned to a certain extent when passing through the rectifying unit, particularly the water passage 73, can be further aligned. For example, when the passage direction of the water flow hole 73 and the passage direction of the rectifying network 91 are bent at a right angle, the water flow is disturbed again and the velocity vector is dispersed, which is considered to be inefficient. .

  The fluid E discharged from the water outlet 51 receives frictional resistance with air on the outer peripheral side. Thereby, the flow velocity on the outer peripheral side gradually decreases (arrow E1). On the other hand, the influence of the frictional resistance with air is extremely small in the flow velocity near the center, and the flow velocity in the vicinity of the water discharge port 51 is maintained (arrow E2). Due to this change in flow velocity, the flow velocity distribution in which the flow velocity on the outer peripheral side is faster than the flow velocity near the center in the vicinity of the water discharge port 51 changes uniformly as the distance from the water discharge port 51 increases. Compared to the case where the flow velocity on the outer circumference side is much slower than the flow velocity near the center and the water discharge shape starts to collapse, the flow velocity is uniform near the water discharge port, or compared to the case where the outer flow velocity is already low near the water discharge port, It is a very long distance. For this reason, it becomes possible to keep the water discharge shape beautiful over a long distance from the water outlet.

  Next, FIG. 7 shows a cross-sectional view of the vicinity of the rectifying water discharge unit 5 ′ in the modification of the present invention. In addition, the same code | symbol is attached | subjected about the part which is common in an Example, and description is abbreviate | omitted. Further, the rectifying and discharging unit 5 ′ is attached to the ceiling-embedded shower 1, similarly to the rectifying and discharging unit 5.

  The rectifying water discharge unit 5 ′ according to the modified example is different from the example in that the shielding unit 71 has a wall surface 75 around the shielding unit 71 and positioned between the water flow hole 73. By providing the wall surface 75 in this manner, it is necessary to get over the wall surface 75 before the water flow that has flowed into the pressure chamber 55 from the water flow pipe 53 and collided with the shielding portion 71 reaches the water flow hole 73. It is possible to stay in the pressure chamber 55. In addition, in the modification, the wall surface 75 is formed in such a way that the shielding part 71 is recessed, but the shielding part 71 and the water passage hole 73 are formed on the same plane as in the embodiment, and a convex part is provided therebetween. A wall surface 75 may be formed.

  The specific configuration of the present invention has been described above with reference to the drawings. However, the present invention is not limited to the above-described embodiments and modifications. Modifications can be made as appropriate without departing from the spirit of the present invention. For example, the water discharge device according to the present invention is not necessarily provided in an overhead shower, and can be applied to a hot and cold water mixing faucet used in a normal hand-washing machine. Moreover, a single water faucet may be sufficient and it can apply to various water discharging apparatuses, such as an automatic water faucet apparatus and a water purifier.

DESCRIPTION OF SYMBOLS 1 Ceiling embedded shower 11 Sprinkling plate 13 Sprinkling hole 15 Oscillating spout 17 Air inlet 3 Bathroom 31, 33, 35 Embedded pipe 37 Operation member 38 Water supply pipe 39 Hot water supply pipe 5 Rectification water discharge part 51 Water discharge port 53 Water flow pipe 55 Pressure chamber 7 Disk member 71 Shielding portion 73 Water passage hole 75 Wall surface 9 Water discharge port forming member 9
91 Rectifying network (rectifying member)
93 Flange 95 Screw hole

Claims (5)

A water discharge device for discharging fluid,
A spout for discharging the fluid;
A rectification unit provided upstream from the water outlet;
The rectification section in the flow cross-section perpendicular to the fluid possess a shielding part for blocking the flow of fluid, and a water passing portion provided on the periphery of the shield portion,
The shielding part and the water flow part are formed on a common disk member,
The water flow portion includes a plurality of openings formed around the shielding portion provided on the disk member.
Formed by the mouth, the inlet and the outlet of the opening have substantially the same size,
The water discharging device , wherein the fluid that has passed through the outlet of the opening is discharged from a single water outlet . On the upstream side of the rectification unit, further has a water conduit connected to the rectification unit,
The inner diameter cross-sectional area of the water pipe is smaller than the area of the shielding part in the connection region with the rectifying part,
2. The water discharge device according to claim 1 , wherein an inner diameter region of the water conduit overlaps with the shielding portion when viewed from a flow direction of the fluid in the water conduit. The water discharge device according to claim 1 , further comprising a wall surface between the shielding portion and the water flow portion. The water discharging apparatus according to any one of claims 1 to 3 , wherein the rectifying unit includes at least one rectifying member on the downstream side of the water flow unit. The water discharge device according to any one of claims 1 to 4 , wherein the water discharge device is installed near a ceiling of a bathroom.