KR200310494Y1 - A One-Body Type Water Seperating Device - Google Patents

Abstract

The present invention relates to an integrated water distribution device, and more particularly, to install a bobbin in which a coil is wound in a coil housing, to form a fixed magnetic pole generating magnetic force on the inner surface of the bobbin, and to contact the fixed magnetic pole with the valve housing. Hydraulic pressure applied to the rotating control plate which is inserted and installed in the center of the valve housing, which fixes the permanent magnet, which is a rotor means that can be rotated by a certain angle unit by magnetic force, on the support shaft and rotates with respect to the distribution plate by the rotation of the permanent magnet. It is a very useful and effective design to improve the operating performance and reduce the production cost of the product by simply configuring the step motor integrally because it operates the rotation control plate with a small torque by lowering.

Description

A One-Body Type Water Seperating Device}

The present invention relates to a device for distributing and supplying water, and in particular, to install a bobbin in which a coil is wound in a coil housing, to form a fixed magnetic pole to generate a magnetic force on the inner surface of the bobbin, and to contact the fixed magnetic valve The housing is inserted and installed in the center of the valve housing, and a permanent magnet, which is a rotor means that can be rotated by a certain angle unit by magnetic force, is fixed to the support shaft and applied to a rotating control plate that rotates with respect to the distribution plate by rotation of the permanent magnet. It is related to an integrated water distribution device used for a bidet to reduce the water pressure to operate the rotation control plate with a small torque to improve the operation performance by reducing the production of the product by simply configuring the step motor integrally.

In general, the bidet is operated by people who use the water to clean the anus instead of using toilet paper after toileting, so that hemorrhoids or related diseases do not occur. When pressed, it refers to the anal cleansing mechanism to clean the user's anus using water discharged from the anal cleansing mouth.

In order to use the bidet, there is a distribution means for supplying and dispensing water. The water flowing from the inlet is properly distributed and discharged to a plurality of discharge ports to supply the user's anus or to wash the bidet. There is a need to reverse the direction of the water.

As such, a "bidet flow path switching device (hereinafter, referred to as a water distribution device)" has been proposed in the related art Utility Model Application No. 20001-32745, which will be described.

1 is a perspective view of a conventional bidet water distribution device, Figure 2 is a cross-sectional view of a conventional bidet water distribution device, Figure 3 is a view showing a rotating body in a conventional water distribution device, Figure 4 (a) ( b) is a plan view and a bottom view of a conventional bidet water distribution device.

In the configuration of the conventional water distribution apparatus for bidet, the rotating shaft of the step motor 100 is coupled to the lower side, the discharge groove 235 is formed in the disc-shaped support plate 230 carried by the spring 220 is rotated A rotating body 200 to be made; It is assembled in close contact with the upper surface of the control plate 230 and form a circle from one side while forming a left-right symmetry on the vertical axis, gradually wider, and a pair of main holes 310 penetrating upward on the other end is formed, the main A distribution plate 300 having a circular auxiliary hole 320 penetrating up and down on a vertical axis on the opposite side where the hole is formed; Comprising the housing 400 is provided with a water supply port 410 is provided on one side and the discharge port 420 to be supplied separately from the water discharged from the main hole 310 and the auxiliary hole 320 do.

In addition, the control plate 230 is inserted into the rotating body 200 is moved up and down.

The rotating body 200 is divided into a shaft 210, a spring 220, and a control plate 230, and a rotation shaft of the step motor is provided at a lower side of the shaft 210.

In addition, a protrusion pillar 211 to which the adjustment plate 230 is fastened is formed from the center of the flange surface 212, and the lower end of the spring is positioned on the flange surface 212. The other end of the spring 220 is to contact the lower surface of the control plate 230 to generate a force to press upward.

The bottom of the protruding pillar 211 is provided with another protruding stopper 213, so that when the adjusting plate 230 is coupled, the adjusting plate 230 can be rotated integrally with the shaft 210. To this end, a stopper groove 236a is formed on the lower surface of the control plate 230 for this purpose.

In addition, the adjustment plate 230 coupled to the protrusion pillar 211 is forcibly press-fitted and restrained so that a predetermined displacement occurs up and down. For this purpose, the protrusion 214 for fastening is provided at the upper end of the protrusion pillar 211. .

The control plate 230 is a flat plate-like member, the center portion of the lower side is provided with a cylindrical hollow shaft 236, the stopper groove 236 is formed in the discharge groove which is wedge-shaped recessed in one place of the plate portion 235 is formed.

However, as described above, the conventional water distribution device, the flow rate gradually widening toward the main hole 310 and the auxiliary hole 320 and the main hole 310 formed to move the water in the distribution plate 300 Since the adjusting groove 315 and the like are formed over a substantially wider area than the total area of the distribution plate 300, water is discharged into the discharge groove 235 of the adjusting plate 230 so that the control plate 230 is blocked relatively wide. Since the hydraulic pressure is applied to the area, the control plate 230 must be driven using a separate step motor 100 having a large driving force with a gear therein to rotate the control plate 230.

In addition, the step motor 100 for driving the control plate 230 is fastened to the housing by using the fastening means, and the configuration is complicated, the product has the disadvantage of increasing the manufacturing cost.

The present invention has been devised in view of the above, and installs a bobbin in which a coil is wound in a coil housing, forms a fixed magnetic pole generating magnetic force on the inner side of the bobbin, and inserts and installs a valve housing so as to contact the fixed magnetic pole. In addition, a permanent magnet, which is a rotor means that can be rotated by a certain angle unit by a magnetic force, is fixed to the support shaft at the central portion of the valve housing to reduce the water pressure applied to the rotation control plate that rotates with respect to the distribution plate by the rotation of the permanent magnet. In order to operate the rotation control plate with a small torque, the purpose is to simply configure the step motor as an integrated unit to improve the operation performance and reduce the production cost of the product.

1 is a perspective view of a conventional bidet water distribution device,

2 is a cross-sectional view of a conventional bidet water distribution device,

3 is a view showing a rotating body in a conventional water distribution device,

Figure 4 (a) (b) is a plan view and a bottom view of a conventional water distribution device for bidet,

5 is an exploded perspective view of the integrated water distribution device according to the present invention,

6 is a view showing the assembled state of FIG.

Figure 7 is an exploded perspective view shown in a state rotated 180 °,

8 is an assembled state cross-sectional view of the integrated water distribution device according to the present invention,

9 is a perspective view of a distribution plate according to the present invention,

10 is a maximum flow rate distribution state diagram of the first distribution port of the distribution plate according to the present invention,

11 is a flow rate reduction state diagram of the first distribution port of the distribution plate according to the present invention,

12 is a flow rate reduction state diagram of the second distribution port of the distribution plate according to the present invention,

13 is a maximum flow rate distribution state diagram of the second distribution port of the distribution plate according to the present invention,

14 is a third distribution opening state of the distribution plate according to the present invention.

* Description of the symbols for the main parts of the drawings *

A: stator means B: rotor means

C: rotation distribution means 2: coil housing

6: bobbin 8: coil

12: fixed stimulation 20: guide groove

22: hook hook 24: O-ring installation portion

30: O-ring 40: permanent magnet

42: rotor support 46: settle groove

48: first rotating projection 50: second rotating projection

52: spring 54: support shaft

60: rotating plate 62: locking groove

64: shaft ball 66: water regulator

70: distribution plate 72: first distribution port

74; Second distribution port 76: Third distribution port

80: housing cover 82: locking jaw

86: first discharge outlet 88: second discharge outlet

90: third discharge outlet 94: stopper projection

The purpose of this is to provide a water distribution device, in which a valve housing forming an inlet for introducing water is inserted into a fitting groove of a coil housing, and forms a bobbin in which a coil is wound inside the coil housing, thereby providing electricity from the wiring. A stator means for receiving electromagnetic power and generating an electromagnetic force; A rotor means rotatably inserted into the stator means, the rotor means being rotated by a permanent magnet receiving electromagnetic force of the stator means; Rotation distribution means for adjusting and dispensing a desired amount of water in a required direction to the first, second, and third distribution ports of the distribution plate in contact with the rotation control plate rotating by the rotation of the rotor means; The first, second and third discharge ports are connected to the first, second, and third discharge ports of the distribution plate, which is the rotation distribution means, to discharge water, and the locking projections of the coil housing are bent at a plurality of fixed jaws. It is achieved by providing an integrated water distribution device composed of a housing cover which is fixed to block the upper portion.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the present invention.

First, Figure 5 is an exploded perspective view of the integrated water distribution device according to the present invention, Figure 6 is a view showing the assembled state of Figure 5, Figure 7 is an exploded perspective view shown in a state rotated 180 °, Figure 8 Is a cross-sectional view of an assembled state of the integrated water distribution apparatus according to the present invention, Figure 9 is a perspective view of the distribution plate according to the present invention, Figure 10 is a maximum flow rate distribution state diagram of the first distribution port of the distribution plate according to the present invention, Figure 11 is a flow rate reduction state diagram of the first distribution port of the distribution plate according to the present invention, Figure 12 is a flow rate reduction state diagram of the second distribution port of the distribution plate according to the present invention, Figure 13 Figure 2 is a maximum flow distribution state diagram of the two distribution ports, Figure 14 is a third distribution opening state diagram of the distribution plate according to the present invention.

In the constitution of the present invention, in the apparatus for distributing water, a valve housing (16) forming an inlet (28) into which water is introduced is inserted into the fitting groove (10) of the coil housing (2), and the coil housing A stator means (A) for forming the bobbin (6) in which the coil (8) is wound inside (2) and receiving electricity from the wiring (5) to generate electromagnetic force; A rotor means (B) rotatably inserted into the stator means (A), the rotor being rotated by a permanent magnet (40) subjected to electromagnetic force of the stator means (A); The first, second and third distribution ports 72, 74, 76 of the distribution plate 70 in contact with the rotating control plate 60 rotated by the rotation of the rotor means (B) in the desired direction Rotational distribution means (C) for controlling and dispensing the quantity of water; The first, second and third discharge ports 86 and 88 at the first, second and third distribution ports 72, 74 and 74 of the distribution plate 70 which is the rotation distribution means C. 90 is connected to discharge the water, the locking projection 14 of the coil housing 2 is bent to a plurality of fixing jaw (84) is composed of a housing cover 80 for blocking the upper portion.

The stator means (A) includes: a stator pole 12 protruding in a projection shape on an inner surface of the bobbin 6 to form a polarity; A magnetic pole fixing jaw (16) formed on an outer circumferential surface of the valve housing (16) to fit the stator pole (12); A guide groove 20 recessed to guide the locking protrusion 14 of the coil housing 2 at an upper edge of the valve housing 16; A catching hook 22 formed to be caught by a catching jaw 82 of the housing cover 80; It is installed in the O-ring installation portion 24 of the valve housing 16 is composed of an O-ring 30 in close contact with the bottom surface of the housing cover 80 to seal.

Then, the rotor means (B) is inserted into the space portion formed in the central portion of the permanent magnet 40, the support shaft 54 is inserted into the insertion hole 44 formed in the center permanent magnet 40 Rotor support 42 for supporting the rotation of the, and to form an isolated space portion to move the water; A spring 52 which is settled in the settling groove 46 of the rotor support 42 to elastically press the rotation control plate 60 to the distribution plate 70 so as to be in contact; A first rotating protrusion 48 on the inner wall surface of the central portion of the rotor support 42; It consists of a second rotary projection 50 protruding in the direction of the permanent magnet from the upper edge of the rotor support (42).

In addition, the rotation distribution means (C) is caught by the first rotation protrusion 48 of the rotor support 42, the shaft hole 64 is inserted into the support shaft 54 to rotate the rotation control plate (60) The locking groove 62 is formed in the side portion of the side, and the shaft hole 64 is formed in a crescent shape with the same diameter to form a water control hole 66 for moving the water introduced into the inlet 28. First and second distribution ports on the distribution plate 70 so as to be symmetrical with respect to the shaft groove 48 into which the support shaft 54 is inserted in the central portion so as to have the same shape corresponding to the water control hole 66. (72) and 74, and a circular third distribution port 76 having a size is formed on the opposite side of the first and second distribution ports 72 and 74.

And, the O-ring fixing groove 92 formed to be recessed so that the O-ring 30 is placed on the bottom surface of the housing cover 80; A stopper which stops the rotation of the rotor support 42 by being caught by the second rotating protrusion 50 of the rotor support 42 in contact with the third discharge port 90 inwardly of the O-ring fixing groove 92. The protrusion 94 is comprised.

When the second rotary protrusion 50 of the rotor support 42 is caught by the stopper protrusion 94, the water control hole 66 of the rotation control plate 60 and the first plate of the distribution plate 70 are provided. It is preferable that the second distribution ports 72 and 74 be opened to the maximum.

The first, second, and third discharge ports 72, 74, and 76 of the distribution plate 70 gradually expand the flow path toward the lower jing cover 80 from the rotation control plate 60. It is constructed.

Therefore, the first, second and third discharge ports 72, 74 and 76 of the distribution plate 70 are small, so that the area in contact with the rotation control plate 70 can be made small, as well as the rotation control plate ( Since the diameter of 70 is made small, it is possible to rotate the rotation control plate 70 with respect to the distribution plate 70 even at a small rotation torque.

Hereinafter, on the basis of the accompanying drawings to look at the action and effect of the present invention in detail.

First, looking at the assembly state of the integrated water distribution device according to the present invention, by inserting the valve housing 16 into the fitting groove 10 of the coil housing 2, the magnetic pole fixing jaw 18 is a fixed magnetic pole ( 12) inserted and fitted.

Then, the permanent magnet 40, which is the rotor means B, is inserted into the installation groove 26 of the valve housing 16 so as to be placed therein, and the spring 52 in the settle groove portion 46 of the rotor support 42. ) And the support shaft 54 is inserted into the insertion hole 44 of the rotor support 42 to be fixed.

Then, the support shaft 54 is inserted through the shaft hole 64 of the rotation control plate 60, which is the rotation distribution means C, and inserted into the shaft groove 78 of the distribution plate 70, and the housing cover 80 ) Is coupled to the coil housing 2 while the locking projection 14 is bent to the fixing jaw 84 of the housing cover 80 and at the same time, the locking hook 22 of the valve housing 16 is hooked. Walk to

The O-ring installation portion 24 of the valve housing 16 and the O-ring fixing groove 92 of the housing cover 80 are sealed to prevent leakage of water while the O-ring 30 is installed.

When the current is supplied through the wiring 5 in this assembled state, the current is supplied to the coil 8 wound in the bobbin 6, generates an electromagnetic force through the stator pole 12, and the rotor means ( A rotating magnetic force is applied to the permanent magnet 40, which is B), so that the permanent magnet 40 rotates by a desired angle.

Meanwhile, as shown in FIG. 10, the first rotating protrusion 48 of the rotor support 42 caught by the locking groove 62 of the rotation control plate 60 by driving the permanent magnet 40 using electromagnetic force. 2) the second discharge port 88 of the housing cover 80 by rotating the water control hole 66 of the rotation control plate 60 to the second distribution port 74 of the distribution plate 70 to accurately position To ensure maximum flow rate.

At this time, the rotation of the second rotating protrusion 50 of the rotor support 42 is blocked while the stopper protrusion 94 formed on the bottom of the housing cover 80 is caught on the bottom.

That is, the water is introduced through the inlet 28 of the valve housing 16 is moved between the partition wall between the rotor support 42, which is the rotor means (B) to adjust the water control hole 66 of the rotation control plate 60 The water is discharged through the second distribution port 74 of the distribution plate 70 through the.

The permanent magnet 40 is submerged in water but there is no problem in generating a magnetic force.

As shown in FIG. 11, the first rotating protrusion 48 of the rotor support 42 caught by the locking groove 62 of the rotation control plate 60 by driving the permanent magnet 40 using electromagnetic force. To rotate the water control hole 66 of the rotation control plate 60 to the second distribution port 74 of the distribution plate 70 so as to shift the position so as to displace the second discharge port 88 of the housing cover 80. To adjust the flow rate.

At this time, by adjusting the rotation angle of the permanent magnet 40 to a desired step, it is possible to arbitrarily adjust the flow rate discharged by adjusting the angle that the water control hole 66 and the second distribution port 74 is shifted from each other. .

Meanwhile, as shown in FIG. 12, the first rotating protrusion 48 of the rotor support 42 caught by the locking groove 62 of the rotation control plate 60 by driving the permanent magnet 40 using electromagnetic force. To rotate the water control hole 66 of the rotation control plate 60 to the first distribution port 72 of the distribution plate 70 so as to shift the position so that the first discharge port 86 of the housing cover 80 is shifted. To ensure maximum flow rate.

At this time, by adjusting the rotation angle of the permanent magnet 40 to a desired step, it is possible to arbitrarily adjust the discharge flow rate by adjusting the angle that the water control hole 66 and the first distribution port 72 is shifted from each other. .

And, as shown in Figure 13, the first rotating projection 48 of the rotor support 42 caught in the locking groove 62 of the rotation control plate 60 by driving the permanent magnet 40 using the electromagnetic force Rotate the water control hole 66 of the rotation control plate 60 to the first distribution port 72 of the distribution plate 70 to accurately position the first discharge port 86 of the housing cover 80 Ensure maximum flow rate is discharged.

At this time, the second rotation protrusion 50 of the rotor support 42 is locked to the bottom surface of the stopper protrusion 94 formed on the bottom surface of the housing cover 80, the rotation is blocked.

And, as shown in Figure 14, by using the electromagnetic force to drive the permanent magnet 40 to rotate the first rotating projection 48 of the rotor support member 42 caught in the locking groove 62 of the rotation control plate 60 Rotate to rotate the water control hole 66 of the rotation control plate 60 to the third distribution port 74 of the distribution plate 70 to adjust the position, the flow rate to the third discharge port 88 of the housing cover 80 To be discharged.

At this time, since the third distribution port 74 of the distribution plate 70 is small in size, it is to be used when the flow rate supplied is small.

The water dispensing device can be applied to all water supply mechanisms to adjust the flow rate of water as well as a bidet that is commonly used.

Therefore, as described above, when using the integrated water distribution apparatus according to the present invention, the bobbin wound in the coil housing is installed, and a fixed magnetic pole generating magnetic force on the inner side of the bobbin, the contacting the fixed magnetic pole The valve housing is inserted and installed as far as possible, and the rotation control plate which rotates with respect to the distribution plate by rotating the permanent magnet by fixing the permanent magnet, which is a rotor means that can be rotated by a certain angle unit by a magnetic force, in the central part of the valve housing is supported by the support shaft. It is a very useful and effective design to improve the operating performance and reduce the production cost of the product by simply configuring the step motor as an integral type by operating the rotation control plate with a small torque by lowering the pressure applied to the product.

Claims (7)

In the device for dispensing water, A valve housing 16 forming an inlet 28 through which water is introduced is inserted into the fitting groove 10 of the coil housing 2, and a bobbin in which the coil 8 is wound inside the coil housing 2. A stator means (A) which forms (6) and receives electricity from the wiring (5) to generate electromagnetic force; A rotor means (B) rotatably inserted into the stator means (A), the rotor being rotated by a permanent magnet (40) subjected to electromagnetic force of the stator means (A); Necessary direction through the first, second and third distribution ports 72, 74, 76 of the distribution plate 70 in contact with the rotation control plate 60 rotated by the rotation of the rotor means (B) Rotation distribution means (C) for controlling and dispensing the desired amount of water; The first, second and third discharge ports 86 and 88 at the first, second and third distribution ports 72, 74 and 74 of the distribution plate 70 which is the rotation distribution means C. 90 is connected to discharge the water, and the engaging projection 14 of the coil housing 2 is bent to a plurality of fixing jaw (84) is fixed to block the upper portion is characterized in that consisting of a housing cover 80 Integral water distribution device. 2. The stator means (A) according to claim 1, further comprising: a stator pole (12) protruding in a projection shape on the inner surface of the bobbin (6) to form a polarity; A magnetic pole fixing jaw (16) formed on an outer circumferential surface of the valve housing (16) to fit the stator pole (12); A guide groove 20 recessed to guide the locking protrusion 14 of the coil housing 2 at an upper edge of the valve housing 16; A catching hook 22 formed to be caught by a catching jaw 82 of the housing cover 80; Integral water distribution device, characterized in that consisting of the O-ring (30) is installed on the O-ring installation portion 24 of the valve housing 16 is in close contact with the bottom surface of the housing cover (80). According to claim 1, The rotor means (B) is inserted into the space portion formed in the central portion of the permanent magnet 40, the support shaft 54 is inserted into the insertion hole 44 formed in the center permanently A rotor support 42 for supporting the rotation of the magnet 40 and forming an isolated space portion for moving water; A spring 52 which is settled in the settling groove 46 of the rotor support 42 to elastically press the rotation control plate 60 to the distribution plate 70 so as to be in contact; A first rotating protrusion 48 on the inner wall surface of the central portion of the rotor support 42; Integral water distribution device, characterized in that consisting of a second rotary projection (50) protruding in the permanent magnet direction from the upper edge of the rotor support (42). 4. The rotation distribution means (C) according to claim 1 or 3, wherein the rotation distribution means (C) is caught by the first rotating projection (48) of the rotor support (42) and the shaft hole (64) is inserted into the support shaft (54). Water to form a locking groove 62 in the side portion of the rotation control plate 60 to rotate, and formed in the crescent shape with the same diameter in the shaft hole 64 to move the water introduced into the inlet (28) The distribution plate 70 forms an adjustment hole 66 and is symmetrically formed with respect to the shaft groove 48 into which the support shaft 54 is inserted into the central portion so as to have the same shape corresponding to the water control hole 66. The first and second distribution ports 72 and 74 are formed in the first and second distribution ports 72 and 74 on the opposite side of the first and second distribution ports. Integral water distribution device. According to claim 1 or 3, O-ring fixing groove (92) formed to be recessed so that the O-ring (30) is placed on the bottom surface of the housing cover (80); A stopper which stops the rotation of the rotor support 42 by being caught by the second rotation protrusion 50 of the rotor support 42 in contact with the third discharge port 90 inwardly of the O-ring fixing groove 92. Integral water distribution device, characterized in that consisting of a projection (94). The water control hole (66) of the rotation control plate (60) and the distribution plate (70) when the stopper protrusion (94) is caught by the second rotary protrusion (50) of the rotor support (42). Integrated water distribution device, characterized in that the first and second distribution ports (72) (74) of the maximum open state. The method of claim 4, wherein the first, second, third distribution ports 72, 74, 76 of the distribution plate 70 gradually move from the rotation control plate 60 to the housing cover 80. Integral water distribution device, characterized in that the flow path is expanded.