KR20140116291A - Fluid flow adjusting device of bidet - Google Patents

Abstract

Provided is a fluid flow adjusting apparatus of a hot-water washer. The hot-water washer includes: a fluid storage tank including semi-circular grooves in a housing, a first connector and a second connector linked to the grooves from both side units of the grooves, and a rotating shaft which protrudes to the inside of the groove from side walls of the grooves; and rotating wings including two or more fans rotating in the grooves of the fluid storage tank.

Description

[0001] FLUID FLOW ADJUSTING DEVICE OF BIDET [0002]

Embodiments of the present invention relate to a hot water scrubber, and more particularly, to a fluid flow regulator that receives cold water from a water supply valve in a hot water scrubber.

Generally, a hot water washer is located on the left side of a toilet in a guest house or a general household, and is widely used as a left side facility. The hot water washer is configured to spray hot water to the user's anus and / or its surroundings through the bidet nozzle device after user's use to remove the dirty-related dirt from the user's body.

In this case, the hot water scrubber sequentially flows the cold water from the water conduction to the water supply valve, the fluid flow guide device, and the instantaneous hot water device to form cold water into hot water using the instantaneous hot water device. The fluid flow guide device is a structure that can not control the flow of cold water between the water supply valve and the instantaneous hot water device. For example, the fluid flow guide may limit the fluid flow path in only one direction or be a hose.

Therefore, when the hot water washer does not receive the cold water from the water supply valve in the abnormal operation, the fluid flow guide device does not have the fluid backflow preventing means, so that the cold water and / It does not block backflow. Accordingly, the instantaneous hot water device can not wrap the heating element in the hot water, thereby overheating the heating element or transmitting the overheating temperature of the heating element to the surrounding elements to deteriorate the electrical characteristics of the surrounding elements.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a fluid flow regulator suitable for preventing the reverse flow of cold water and / or hot water from an instantaneous hot water device to a water supply valve in the event that cold water is not supplied from a water supply valve in abnormal operation of a hot water scrubber, .

Other problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned here will be fully understood by those skilled in the art from the following description.

An apparatus for regulating fluid flow in a hot water scrubber in accordance with embodiments of the present invention is provided. The fluid flow control device includes a groove formed in the semi-circular housing along the semicircular shape, a groove communicating with the groove at a lower portion of the groove and extending from opposite sides of the groove in different directions And a rotation shaft protruding from the side wall of the groove toward the inside of the groove. A rotating blade including at least two fans positioned inside the groove of the fluid reservoir and rotating about the rotational axis; A fluid guiding tube located around the fluid reservoir and communicating with the first connector; And a fluid position sensing part communicating with the groove through the second connection hole in fluid storage contact with the fluid.

The rotary vane has a recess in one of the at least two fans.

Wherein the fluid position sensing unit includes a magnetic sensor on the second connector, the rotary vane includes a reactive magnetic body on the other of the at least two fans, and the magnetic sensor is configured to sense the magnetic force of the reactive magnetic body do.

The fluid reservoir further includes a stationary magnetic body on top of the groove, and the stationary magnetic body and the reactive magnetic body are configured to generate a repulsive force with respect to each other.

Since the fluid flow regulating device of the hot water scrubber according to the embodiments of the present invention is located between the water supply valve and the instantaneous hot water device,

When the cold water is not supplied from the water supply valve due to an abnormal operation of the hot water scrubber, the fluid flow regulating device interrupts the fluid flow path by using the inner rotating blades to return cold water and / or hot water from the instantaneous hot water device to the water supply valve Can be prevented.

The fluid flow regulating device prevents the reverse flow of cold water and / or hot water from the instantaneous hot water device to the water supply valve due to an abnormal operation of the hot water scrubber, so that it is possible to prevent overheating of the heating element in the instantaneous hot water device and / Deterioration of the electrical characteristics of the elements can be prevented.

The fluid flow regulating device prevents deterioration of the electrical characteristics of the surrounding components affected by the temperature of the heating element and / or the heating element, thereby not only normal operation of the hot water scrubber but also abnormal operation of the hot water scrubber, I can feel it.

Since the fluid flow regulating device keeps the use experience of the hot water scrubber constant not only in the normal operation of the hot water scrubber but also in abnormal operation, the user can induce a refreshment in the toilet.

1 is a perspective view showing a fluid sensing means and a control unit in a hot water scrubber according to embodiments of the present invention.
2 is a side view showing the fluid flow control device in the fluid sensing means of FIG.
3 and 4 are schematic views for explaining the operation of the fluid sensing means and the control unit of FIG.

First, a fluid flow regulating apparatus for a hot water scrubber according to embodiments of the present invention will be described in detail with reference to FIGS.

1 is a perspective view showing a fluid sensing means and a control unit in a hot water scrubber according to embodiments of the present invention.

Referring to FIG. 1, a hot water scrubber 110 according to an embodiment of the present invention includes a fluid sensing means 90 and a control unit 100. The fluid sensing means 90 and the controller 100 will be described first in terms of functions. The fluid sensing means 90 includes a fluid flow control device 70 and an instantaneous hot water device 80. The fluid flow regulating device 70 receives cold water from a water supply valve (not shown in the figure) of the hot water washer 110 and transfers the cold water to the instantaneous hot water device 80.

The fluid flow regulating device 70 prevents reverse flow of hot water from the instantaneous hot water device 80 to the water supply valve. The instantaneous hot water supply device 80 receives cold water from the fluid flow control device 70 and heats the cold water to form hot water. The controller 100 electrically controls the fluid flow control device 70 and the instantaneous hot water device 80.

That is, the controller 100 receives electric signals from the fluid flow regulator 70 to check the temperature and the position of the cold water in the fluid flow regulator 70, and controls the reverse flow of the hot water through the fluid flow regulator 70 Check the prevention status. In addition, the controller 100 controls the temperature of the heating element of the instantaneous hot water device 80 by checking the temperature and position of the cold water in the fluid flow control device 70.

The fluid sensing means 90 and the control unit 100 are sequentially positioned along one direction in the hot water washer 110. The fluid sensing means 90 and the control unit 100 are structured in the following manner. The fluid sensing means (90) includes a fluid flow control device (70) and an instantaneous hot water device (80). The fluid flow control device 70 and the instantaneous hot water device 80 are sequentially positioned toward the controller 100.

The fluid flow control device 70 includes a fluid temperature sensing part 20, a fluid induction pipe 30, a fluid reservoir 40, and a fluid position sensing part 60. The fluid temperature sensing unit 20, the fluid induction pipe 30, the fluid reservoir 40, and the fluid position sensing unit 60 communicate with each other. The fluid temperature sensing unit 20 includes an intake temperature sensor 26. The fluid position sensing unit 60 includes a magnetic sensor 66.

The fluid flow regulating device 70 is described in more detail in FIGS. The fluid flow regulating device (70) is detachably connected to the instantaneous hot water device (80). The instantaneous hot water supply device 80 includes a heater body 81, a heater inlet 82, a heating element 84, an outflow temperature sensor 86 and a heater outlet 88. The heater inlet 82 of the instantaneous hot water device 80 is configured to communicate with the fluid position sensing portion 60 of the fluid flow regulating device 70 although not shown in the figure.

The heater inlet 82 and the fluid position sensing portion 60 may communicate with each other through direct contact or through a connection structure. The instantaneous hot water device 80 will be described in more detail in FIG. The control unit 100 electrically controls the fluid flow regulating device 70 and the instantaneous hot water device 80 using the input water temperature sensor 26, the magnetic sensor 66 and the water outflow temperature sensor 86.

2 is a side view showing the fluid flow control device in the fluid sensing means of FIG.

Referring to Figure 2, a fluid flow conditioning device 70 in accordance with embodiments of the present invention includes a fluid reservoir 40 and a rotating vane 50. The fluid reservoir 40 includes a first connection hole 41, a groove 42, a second connection hole 43, and a rotation shaft 46 in a semicircular housing. The first connection port 41 communicates with the groove 42 in the lower part of the groove 42 and extends in a predetermined direction from one side of the groove 42. The groove 42 is formed along the semicircular shape of the housing.

The second connection port 43 communicates with the groove 42 at a lower portion of the groove 42 and extends from the other side of the groove 42 toward a direction opposite to the extending direction of the first connection port 41. The rotary shaft 46 projects from the side wall of the groove 42 toward the inside of the groove 42. The fluid reservoir 40 further includes a stationary magnetic body 49B on the top of the groove 42. [ The stationary magnetic body 49B has N poles 49A and S poles 49B having different polarities.

The N pole 49A of the stationary magnetic body 49B is positioned to face the upper sidewall 44 of the groove 42. [ The S pole 49B of the stationary magnetic body 49B is positioned toward the opposite side of the N pole 49A. The rotary vane 50 includes at least two fans 51, 53 positioned inside the groove 42 of the fluid reservoir 40 and rotating about a rotary axis 46 and at least two fans 51, And the concave portion 52 is formed in one of the first and second projections 51a and 51b. The rotary vane 50 opens and closes the first connection port 41 using one of the at least two fans 51 and 53.

The rotary vanes 50 include reactive magnets 54 in the other one of the at least two fans 51, 53. The reactive magnetic body 54 has an N pole 54A and an S pole 54B having different polarities. The N pole 54A of the reacting magnetic body 54 is positioned to face the upper sidewall 44 of the groove 42. The S pole 54B of the reactive magnet 54 is positioned to face the bottom of the groove 42.

Therefore, the reactive magnetic body 54 is configured to generate a repulsive force with respect to the stationary magnetic body 49. The fluid flow control device 70 further includes a fluid temperature sensing part 20, a fluid induction pipe 30, and a fluid position sensing part 60. The fluid temperature sensing part 20 is in contact with the fluid reservoir 40 and communicates with the groove 42 through the first connection port 41. The fluid temperature sensing unit 20 includes a temperature sensor support pipe 21 and a separation membrane 23 and an inlet temperature sensor 26 inside the temperature sensor support pipe 21.

The separation membrane 23 divides the inside of the temperature sensor support tube 21 into an outer tube 28 and an inner tube 29 in sequence toward the fluid reservoir 40. The incoming temperature sensor 26 extends through the outer tube 28 and into the inner tube 29 through the separation membrane 23. The temperature sensor support pipe 21 communicates with the fluid induction pipe 30 and the first connection pipe 41 through the inner pipe 29. The fluid induction pipe 30 includes a water inlet 35 branched from the fluid temperature sensing unit 20 and communicating with the fluid temperature sensing unit 30.

The fluid position sensing part (60) includes an outlet (64) therein. The fluid position sensing unit 60 is in contact with the fluid reservoir 40 and communicates with the groove 42 through the second connection port 43. The fluid position sensing unit 60 includes a magnetic sensor 66 on the second connector 43. The magnetic sensor 66 is configured to sense the magnetic force of the reactive magnetic body 54.

3 and 4 are schematic views for explaining the operation of the fluid sensing means and the control unit of FIG.

Referring to FIG. 3, in normal operation of the hot water scrubber 110 of FIG. 1, the hot water scrubber 110 may supply cold water of a water conductivity to the fluid flow regulator 70 through a water supply valve. In this case, the water cold water can reach the fluid inlet 30 of the fluid flow regulating device 70 along the first flow line A1. The fluid guide pipe (30) is capable of flowing water cold water along the inner inlet (35).

The cold water can reach the fluid reservoir 40 via the inner tube 29 of the fluid temperature sensing unit 20 through the inlet 35 of the fluid induction tube 30. The cold water may contact the intake temperature sensor 26 at the inner pipe 29 of the fluid temperature sensing part 20. [ The intake temperature sensor 26 measures the temperature of the cold water on the second flow line A2 and can transmit the electric signal corresponding to the temperature value to the controller 100 of FIG.

The control unit 100 may heat the heating element 84 of the instantaneous hot water apparatus 80 of FIG. 4 by adding a predetermined temperature value to the temperature value of the inlet water temperature sensor 26 through the internal program. Subsequently, the fluid reservoir 40 can receive cold water through the first connection port 41. Before the cold water reaches the groove 42 from the fluid reservoir 40 via the first connection 41, the rotary vane 50 of the fluid reservoir 40 is connected to at least one of the at least two fans 51, The first connector 41 can be shielded by using one of the first connector 51 and the second connector 51.

That is to say, the rotary vanes 50 are provided with one of the at least two fans 51, 53 by using their own weight and the repulsive force F between the fixed magnetic body 49 and the reactive magnetic body 54, 42). The N pole 49A of the stationary magnetic body 49 and the N pole 54A of the reactive magnetic body 54 can generate the repulsive force F. [ Accordingly, the rotary vane 50 may have a dotted line trace 50A in the groove 42. [

At the same time, since the other one of the at least two fans 51 and 53 is sensed by the magnetic sensor 66, the controller 100 controls the inside of the groove 42 using the mask sensor 66 You can monitor the absence of cold water flow. Next, the cold water can reach the groove 42 via the first connection hole 41. [ The cold water can push one of the at least two fans 51A of the dotted line trace 50A using the concave portion 52A.

The rotary vane 50 may be rotated about the rotary shaft 46 to have a rotation direction R along the edge of the groove 42. [ The rotary vane 50 may be in contact with the upper sidewall 44 of the groove 42. The cold water can flow along the third flow line A3. That is, the cold water passes through the groove 42 in the fluid reservoir 40 and can reach the fluid position sensing unit 60 via the second connection port 43. The fluid position sensing unit 60 can flow cold water through the inner outlet 64.

On the other hand, in the abnormal operation of the hot water washer 110, when the water supply valve does not supply the cold water to the fluid flow regulating device 70, the rotary vane 50 has its own weight, It is possible to rotate in the direction opposite to the rotation direction R through the repulsive force F between the magnetic bodies 54 and the pressure difference between the inlet 35 and the outlet 64. [ One of the at least two fans (51, 53) may be rotated to the bottom of the groove (42).

Through this, the rotary vane 50 has a dotted line trace 50A at the bottom of the groove 42. [ The dotted line trace 50A shields the first connection port 41 through one of the at least two fans 51A to prevent reverse flow of cold water and / or hot water from the instantaneous hot water device 80 of FIG. 4 to the water supply valve .

4, the cold water may reach the heater inlet 82 of the instantaneous hot water device 80 via the outlet 64 of the fluid position sensing unit 60 along the fourth flow line A4 . The cold water may contact the heating element 84 through the heater inlet 82 in the instantaneous hot water device 80 along the fifth flow line A5. The heating element 84 heats the cold water to form cold water as hot water.

The cold water can be contacted to the outflow temperature sensor 86 in the instantaneous hot water device 80 on the fifth flow line A5. The outflow temperature sensor 86 measures the temperature of hot water and can transmit the temperature value to the controller 100 through an electric signal. The control unit 100 can adjust the heating temperature of the heating element 84 to be constant by comparing the temperature value of the outflow temperature sensor 86 with the set temperature value.

The hot water can reach the heater outlet 88 through the outflow temperature sensor 86. [ Thereafter, the hot water flows along the sixth flow line A6 and can be transferred to the flow control valve of the hot water washer 110 and / or the cleaning nozzle (not shown in the figure).

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

20; A fluid temperature sensing unit 21; Temperature sensor support tube
23; Separation membrane, 26; Input temperature sensor
28; Outer tube, 29; Inner tube
30; Fluid guide tube, 35; Inlet
40; Fluid reservoir, 41, 43; Connector
42; Groove, 44; Upper side wall
46; Rotation axis, 49, 54; Magnetic body
50; Rotating blades, 60; The fluid-
64; Outlet, 66; Magnetic sensor
70; Fluid flow regulator 80; geyser,
90; Fluid sensing means, 100; The control unit
110; Hot water washer

Claims (4)

A semicircular groove formed in the semicircular housing, a first connector communicating with the groove at a lower portion of the groove and extending from opposite sides of the groove in different directions, And a rotation shaft projecting from the side wall of the groove toward the inside of the groove.
A rotating blade including at least two fans positioned inside the groove of the fluid reservoir and rotating about the rotational axis;
A fluid guiding tube located around the fluid reservoir and communicating with the first connector; And
And a fluid position sensing unit communicating with the groove through the second connection hole in fluid reservoir contact. The method according to claim 1,
Wherein the rotary vane has a recess in one of the at least two fans. The method according to claim 1,
Wherein the fluid position sensing unit includes a magnetic sensor on the second connector,
The rotating blades comprising a reactive magnet for the remaining one of the at least two fans, and
Wherein the magnetic sensor is configured to sense the magnetic force of the reactive magnetic body. The method of claim 3,
Wherein the fluid reservoir further comprises a stationary magnetic body on top of the groove and the stationary magnetic body and the reactive magnetic body are configured to generate a repulsive force with respect to each other.

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