KR101456616B1 - Water supply unit for the branch off type water supply system - Google Patents

Abstract

The present invention relates to a water supply unit for a multi-branch-type water supply system. The present invention includes an inflow port (110) for water inflow; a branch port (120) for branching of the inflow water; and a discharge port (130) for discharge. The inflow port (110) and the branch port (120) form a U-shaped flow path (140) and communicate with each other on the same plane. The discharge port (130) is formed vertically downward from a middle point between the inflow port (110) and the branch port (120). The water flowing into the inflow port (110) smoothly flows along the flow path (140) to branch to the branch port (120). When the discharge port (130) is opened, a part of the water that flows in the flow path (140) is discharged through the discharge port (130). Accordingly, the water can be branched and discharged while smoothly flowing along the U-shaped flow path. When the present invention is applied to a multi-branch-type water supply system, water supply can be stable and smooth.

Description

[0001] The present invention relates to a water supply unit for a multi-stage branched water supply system,

The present invention relates to a water inlet, and more particularly, to a water outlet for a multi-stage branched water supply system, which is applied to a multi-stage branched water supply system and is capable of branching water supplied from the water supply into multi-stages.

Generally, a water supply system that supplies water supplied from a water supply or a boiler to a building, such as a bathroom, a veranda, and a sink, is essential. For this, piping is required. One of the most commonly used methods is a one-to-one method of supplying water to a desired point through a single distributor.

As shown in FIG. 1, the one-to-one system is a system in which water supplied from a water supply source is distributed to a sink, a washing machine, a bathtub, a washstand, a toilet, or the like as a final water supply destination directly connected to a distributor through a distributor. Therefore, a distributor is indispensable for such a system.

However, in the case of using the above-described distributor, since the distributor and each final water supply destination are connected directly to each other, there is a problem that the length of the pipe becomes long when the distance to the final water supply destination is long. This not only caused a rise in the cost of construction, but also interfered with other processes or interference with construction of other facilities. Furthermore, there was a problem in the strength of the building because a sufficient amount of concrete could not be poured at the point where the pipe was concentrated. Particularly, since the water pressure is lowered at distant points from the distributor to the final water supply destination, there is a problem that the water supply may not be performed smoothly when the water is used at a plurality of locations.

In order to solve the above-mentioned problems, there has been proposed a multi-stage branched water supply system capable of supplying multi-stage water. Patent Application No. 10-2012-0132185 entitled "Water Supply System ". As shown in FIG. 2, the multistage branched water supply system includes a plurality of water collectors 200a, 200b, and 200c connected in series to each other to supply water from the water supply unit M, The diameter of the pipe is sequentially decreased as the distance to the water supply destination is longer, so that the water pressure can be kept relatively constant.

In the multi-stage branched water supply system as described above, the water outlet is required to divide the water into multiple stages. However, in order to accomplish this, the conventional water collecting bulb has a structure in which the water is blown out at an angle close to a right angle after flowing vertically downward, so that the flow of water is not smooth and water can not be supplied smoothly, The noise is likely to occur.

It is an object of the present invention to provide a water inlet which is smoothly flowed in a water flow and is optimized to be branched and discharged in order to enable the multistage branched water supply system as described above to function smoothly.

The present invention proposes a water inlet having a U-shaped flow path to achieve the above object by allowing the flow of water to branch and discharge smoothly.

According to the water inlet according to the present invention, the water can be branched and discharged while flowing smoothly along the U-shaped flow path. Therefore, it is possible to implement a water supply system which can supply stable and smooth water by applying it to a multi-stage branched water supply system.

1 is an exemplary view showing an example of a conventional water supply system,
Fig. 2 is an example showing a multi-stage branched water supply system,
3 is an exemplary view of a water inlet according to the present invention,
4 is a horizontal sectional view showing the internal structure of the water inlet according to the present invention,
5 is a cross-sectional view showing the internal structure of the water inlet according to the present invention,
FIG. 6 is an exemplary view showing a flow of water when a discharge port is opened in a water inlet according to the present invention,
FIG. 7 is a cross-sectional view showing the flow of water when the discharge port is opened in the water inlet according to the present invention,
8 is an exemplary view showing a flow of water when a discharge port is closed in a water inlet according to the present invention,
Fig. 9 is an exemplary view showing the flow of water when the discharge port is closed in the water inlet according to the present invention in cross section. Fig.

In order to smoothly function the multistage branched water supply system according to the present invention, in order to obtain a water inlet which is smoothly flowed with water and is optimized to be branched and discharged,

The inlet and outlet being formed in a U-shaped flow passage communicating with each other on the same plane, and the outlet being connected to the inlet and outlet Wherein the water flowing into the inlet flows smoothly along the flow channel and branches into the branch port and a part of the water flowing in the flow channel is discharged to the outlet when the outlet is opened. We propose a water bulb for the system.

Hereinafter, the present invention will be described in detail with reference to FIGS. 3 to 9.

Fig. 5 is a cross-sectional view showing the internal structure of the water inlet according to the present invention, Fig. 6 is a cross-sectional view showing the internal structure of the water inlet according to the present invention, Fig. FIG. 7 is a cross-sectional view showing the flow of water when the discharge port is opened in the water inlet according to the present invention, and FIG. 8 is a cross-sectional view showing the flow of the water according to the present invention FIG. 9 is a cross-sectional view showing the flow of water when the discharge port is closed in the water inlet according to the present invention. FIG. 9 is a view showing the flow of water when the discharge port is closed.

As shown in the figure, the water inlet 100 according to the present invention includes an inlet 110 through which water flows, a water distributing mechanism 120 through which the water flows, and an outlet 130 through which water is discharged to the outside. Therefore, a part of the water supplied through the inlet 110 may be branched to another water supply source through the distributor 120, and a part of the water may be discharged to the outside through the discharge outlet 130. A faucet or a shower or the like is connected to the discharge port 130 to be discharged to the outside and used as domestic water.

The inlet (110) and the branch (120) form a U-shaped flow path (140). The flow paths 140 are formed to communicate with each other on the same plane. As shown in the drawing, a flow path 140 is formed in the water inlet 100 in a U shape in a horizontal direction. Accordingly, the water flowing into the inlet 110 can smoothly flow along the curved flow passage 140 and can be branched into the branching device 120. The branching device 120 includes the water inlet 100 installed at the adjacent watering destination, And the water is supplied to the adjacent water supply source.

The discharge port 130 is formed vertically downward at a midway point between the inlet 110 and the distributor 120. The outlet 130 is a passage through which a part of the water introduced into the inlet 110 is discharged to the outside through a faucet or the like. Accordingly, it is preferable that the valve 160 is formed to be selectively opened as required by the valve 160 so as to control the discharge of the water.

A partition wall 150 is formed in the flow passage 140 to selectively open and close the discharge port 130. The partition wall 150 is formed to cut off the inlet of the discharge port 130 from the water flowing in the flow passage 140 and is formed so as to protrude into the center of the flow passage 140 while ' do. At this time, a through hole 152 is formed in the partition 150. Whereby the flow path 140 and the discharge port 130 are communicated with each other through the through hole 152.

The through hole 152 is opened and closed by the valve 160. The valve 160 is provided separately and opens and closes the through hole 152 while advancing and retracting. When the through hole 152 is opened and the water flowing in the flow passage 140 flows into the discharge port 130 Or to close the through hole 152 as shown in FIGS. 8 and 9 to prevent the water from being discharged to the discharge port 130.

The through holes 152 are formed in the wall in the direction parallel to the flow of the flow passage in the partition wall 150. [ As the partition wall 150 surrounds the inlet of the discharge port 130 in a 'C' shape, a wall in a direction parallel to the flow of the water and a wall in a direction crossing the flow of the water are naturally formed. And a through hole 152 is formed in the wall of the body. Accordingly, when the through hole 152 is opened while flowing through the flow path 140, the water flows into the through hole 152 naturally and is discharged to the discharge port 130.

The water receiver 100 according to the present invention is provided with the decelerating portion 142 in the flow path 140. According to the present invention, the barrier ribs 150 are formed in a U shape as described above and protrude to the central portion of the flow path 140, so that the walls of the barrier ribs 150, which are formed in a direction intersecting the flow of the water, The deceleration portion 142 is naturally formed at the two corners of the flow path 140 forming the mold. In the decelerating portion 142 formed as described above, a part of the water impinges on a wall formed in a direction intersecting with the flow of the water, so that the two corners of the oil passage 140, i.e., A vortex is formed and the flow velocity is slowed down. Therefore, the flow rate of the water on both sides of the through hole 152 is reduced, and the amount of the water accommodated in the flow path 140 is maximized, and the time for the water to stay near the through hole 152 is increased. As a result, 142 serve to increase the amount of water flowing into the through hole 152 when the through hole 152 is opened.

The water inlet 100 according to the present invention is provided with the inlet 110, the outlet 120 and the outlet 130 as described above, and a part of the water introduced through the inlet 110 is supplied to the outlet 120 to the adjacent water receptacle 100, and at the same time, when the discharge port 130 is opened, part of the water is discharged to the discharge port.

The water receiver 100 according to the present invention is disposed for a plurality of water supply destinations by providing a plurality of water receiving openings 100 through the above-described structure, and the water distributing mechanism 120 of the water receiving opening 100 installed at one water supply destination And the water supply system is implemented by connecting the water supply port 100 to the inlet 110 of the adjacent water supply source. Accordingly, the water can be supplied to a plurality of water supply sources in a multistage manner, so that water can be supplied smoothly through the flow path 140 formed in a U-shape.

100: water inlet, 110: inlet,
120: minute mechanism, 130: outlet,
140: flow path, 142: deceleration portion,
150: partition wall, 152: through hole,
160: Valve.

Claims (4)

An inlet 110 through which the water flows, a water distributing mechanism 120 through which the introduced water flows, and an outlet 130 through which the water flows out,
The inlet 110 and the outlet 120 form a U-shaped flow passage 140 and communicate with each other on the same plane. The outlet 130 is located at a midpoint between the inlet 110 and the outlet 120 The water flowing into the inlet 110 flows vertically downward and flows smoothly along the oil passage 140 and branches to the oil distributor 120. When the outlet 130 is opened and part of the water flowing through the oil passage 140 flows Is discharged to the discharge port 130,
The passage 140 is formed with a partition wall 150 separating an inlet of the discharge port 130 from the water flowing in the passage 140. A through hole 152 is formed in the partition wall 150 to be opened and closed by a valve 160 The water can be selectively discharged,
The partition wall 150 has a U shape and protrudes toward the center of the flow path 140 to form a reduction portion 142 on both sides of the partition 150 to reduce the flow rate of the water flowing through the flow path 140, Wherein the through hole (152) is formed in a wall parallel to the flow of the flow path, and the reduction portion (142) is formed on both sides of the through hole (152). The method according to claim 1,
Wherein the deceleration section (142) is formed at a corner of the U-shaped flow path (140) to maximize a flow rate of the flow path (140) accommodated in the flow path (140). delete delete

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