KR101560166B1 - Cock valve for water purifier - Google Patents

Abstract

The present invention relates to a cock valve for a water purifier.

The cockpit valve for a water purifier according to an embodiment of the present invention includes a fluid inlet 200 having a plurality of fluid inflow passages 210 connected to a plurality of different fluid supply sources; A flow changing part 300 having a plurality of flow changing paths 310 communicating with the plurality of fluid inflow paths 210; And a plurality of fluid outflow paths (410) are provided and are rotatable with respect to the fluid flow changing part (300), and one of the plurality of fluid change paths (310) and the plurality of fluid outflow paths A fluid outlet (400) through which one communicates; And each of the plurality of fluid outflow paths (410) is connected to one of the plurality of flow modifying paths (310) communicating with the rotating direction of the fluid outflow part (400) May be provided at any position on a virtual arc that may be formed in the fluid outlet 400 with a distance from the center of the fluid outlet 400 as a radius.

Water Purifier, Cock Valve

Description

{COCK VALVE FOR WATER PURIFIER}

The present invention relates to a cock valve for a water purifier.

The water purifier is a device that filters the raw water through various filter members and make it into purified water to supply to the user. In this case, a purified water tank for storing the purified water is provided, and a cock tank is connected to the purified water tank by a connection pipe or the like. Therefore, the purified water, which is filtered by the various filter elements of the water purifier and stored in the purified water tank, is supplied to the user through the cock valve. In the conventional water purifier, only one cock valve is provided so that the purified water can be supplied to the user. In recent years, however, a water heater or a cooler is provided to supply water to the user as well as purified water or cold water. In addition, an ionizer is provided in the water purifier to supply the user with ionized water. Therefore, the water purifier must be equipped with a number of cockc valves, such as water, warm water, cold water or ionized water, which can be supplied to the user. However, if the plurality of cockc valves are separately provided in the water purifier as described above, there is a problem that the volume of the water purifier becomes large. Further, there is a problem that it is also difficult to install a plurality of cockcarts in the water purifier. In order to solve this problem, a single cock-valve can supply a plurality of different fluids to the user. In this case, however, a plurality of different fluids flow out through one outflow path, There is a problem that the furnace is contaminated. Further, in the case of ionized water, there is a problem that the outflow path can be corroded. Further, there is a problem in that the user is supplied with the respective fluids mixed with the other fluids left in the outflow path without being supplied separately.

The present invention is realized by recognizing at least any one of the requirements or problems occurring in the conventional cock pump for a water purifier.

It is an object of the present invention to allow a plurality of different fluids to flow out through separate outflow passages by using one water purifier cock valve.

Another object of the present invention is to allow only one fluid out of a plurality of fluids to flow out according to the rotational position of the cock-valve.

Another object of the present invention is to be able to detect the rotational position of a cock valve through which a fluid flows out.

Another object of the present invention is to detect a rotational position of a cock valve through which a fluid flows out to display it to a user or to open an opening / closing valve provided in an outflow passage through which fluid flows.

A water purifier cock valve related to one embodiment for realizing at least one of the above problems may include the following features.

The present invention basically is based on the fact that a plurality of different fluids flow out through separate outflow passages so that only one fluid of a plurality of different fluids can flow out according to the rotational position of the cock-valve.

A cock pump for a water purifier according to one embodiment of the present invention includes a fluid inlet having a plurality of fluid inlets connected to a plurality of different fluid sources; A flow changing part having a plurality of flow changing paths communicating with a plurality of fluid inflow paths; And a fluid outlet, which is provided with a plurality of fluid outflow paths and is rotatable with respect to the flow changing part and in which one of the plurality of fluid change paths and one of the plurality of fluid outflow paths communicate with each other in accordance with the rotational position; And each of the plurality of fluid outflow paths may be formed in the fluid outflow portion with a radius from a center of one of the plurality of flow modifying paths communicating with the rotating direction of the fluid outflow portion, And can be provided at any one position on a virtual arc.

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The plurality of flow changing paths may be arranged in a line in a virtual line passing through the center of the flow changing portion.

A plurality of flow changing grooves may be formed in the flow changing portion so that each of the plurality of fluid inflow paths and the plurality of flow changing paths can communicate with each other.

The cockpit valve for a water purifier according to an embodiment of the present invention includes a plurality of fluid inflow passages which are located on the fluid inflow portion side and have a plurality of inflow pipe through holes, cover; And a second cover having a plurality of outflow pipe protecting tubes disposed on the fluid outflow portion side and each having a lever to protect a plurality of outflow pipes respectively included in the plurality of fluid outflow paths; As shown in FIG.

In this case, the first cover or the second cover may be provided with a position sensor capable of detecting the rotational position of the second cover.

The first cover may be provided with a plurality of rotation position detection grooves and the second cover may be provided with a rotation position detection stopper which can be positioned in each of the plurality of rotation position detection grooves in accordance with the rotation position of the second cover .

Meanwhile, a first sealing member may be inserted between the fluid inlet and the flow changing portion.

A second sealing member may be inserted between the flow changing portion and the fluid outlet portion.

As described above, according to the present invention, it is possible to allow a plurality of different fluids to flow out through separate outflow passages by using one water purifier cock valve.

In addition, according to the present invention, only one fluid out of a plurality of fluids can be discharged according to the rotational position of the cock-valve.

According to the present invention, it is possible to detect the rotational position of the cock valve through which the fluid flows out.

In addition, according to the present invention, the rotation position of the cock valve through which the fluid flows out can be detected and displayed to the user, or the opening / closing valve provided in the outflow passage through which the fluid flows out can be opened.

In order to facilitate understanding of the features of the present invention as described above, a water purifier cock valve related to an embodiment of the present invention will be described in detail.

Hereinafter, exemplary embodiments will be described based on embodiments best suited for understanding the technical characteristics of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, It is to be understood that the present invention may be implemented as illustrated embodiments. Accordingly, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. In order to facilitate understanding of the embodiments to be described below, in the reference numerals shown in the accompanying drawings, among the constituent elements which perform the same function in each embodiment, the related constituent elements are indicated by the same or an extension line number.

Embodiments related to the present invention are basically different from each other in that a plurality of different fluids flow out through separate outflow passages so that only one fluid of a plurality of different fluids can flow out according to the rotational position of the cock valve .

1, the water purifier cock-valve 100 according to the present invention includes a fluid inlet portion 200 configured to allow a plurality of different fluids to flow therethrough, and a fluid inlet portion 200 communicating with the fluid inlet portion 200 A flow modifying portion 300 in which a plurality of different fluid flows are changed and a flow modifying portion 300 communicating with the flow modifying portion 300 and rotatable with respect to the flow modifying portion 300, And a fluid outlet portion 400 configured to discharge only the fluid.

As shown in FIGS. 1 and 4, the fluid inlet 200 may be provided with a plurality of fluid inflow passages 210 connected to a plurality of different fluid supply sources. In this embodiment, the fluid inlet portion 200 is provided with three fluid inlet passages 210. However, the number of fluid inflow passages 210 provided in the fluid inflow portion 200 is not limited to the present embodiment, but may be three or less or three or more. The fluid source connected to the fluid inflow path 210 may be, for example, a purified water tank or a warm water tank or a cold water tank provided in the water purifier. Further, when the water purifier includes the ionizer, the ion water tank may be included in the fluid source. The fluid inflow path 210 may include a plurality of inflow holes 211 formed in the fluid inflow part 200 and a plurality of inflow pipes 212 communicating with the plurality of inflow holes 211, have. Each of the plurality of fluid supply sources may be connected to the plurality of inflow pipes 212 through a connection pipe (not shown) or the like. Therefore, the fluid stored in the purified water tank, the cold water tank, or the ionized water tank as described above flows into the inflow pipe 212 of the fluid inflow portion 200 through the connection pipe or the like and then flows into the inflow hole 211 To the flow changing portion 300, which will be described later. The fluid inflow path 210 shown here is merely an example, and any configuration is possible as long as the fluid inflow path 210 is configured to be able to flow into the flow change part 300 from the fluid supply source.

The fluid inlet portion 200 may be formed with an insertion groove 220 and the fluid change portion 300 and the fluid outlet portion 400 to be described later may be inserted into the insertion groove 220. Also, as shown in the drawing, at least one hook 221 may be formed in the fluid inlet 200, so that when the fluid changing portion 300 and the fluid outlet 400 are inserted into the insertion groove 220 It can be prevented from being released to the outside. One or more fitting protrusions 222 may be formed in the fluid inlet portion 200 to fit into the fitting groove 330 that may be formed in the flow changing portion 300, Is inserted into the insertion groove 220 and is not rotated. In addition, the fluid inlet portion 200 may have a fixing protrusion 230 formed with a hole. The fixing protrusion 230 may be inserted into the protrusion insertion groove 530 formed in the first cover 500 described later. The protrusion insertion groove 530 may be formed with a hole corresponding to the hole formed in the fixing protrusion 230 as shown in FIG. Therefore, the fluid inlet 200 can be fixed to the first cover 500 by inserting bolts or the like into the holes formed in the projection insertion grooves 530 and the holes formed in the fixing projections 230. Meanwhile, at least one fitting protrusion 240 may be formed in the fluid inlet portion 200 as shown in FIG. The fitting protrusion 240 is inserted into the fitting groove 541 formed in the fluid inlet insertion groove 540 when the fluid inlet 200 is inserted into the fluid inlet insertion groove 540 formed in the first cover 500, As shown in Fig. Therefore, when the fluid inflow portion 200 is inserted into the fluid inflow portion insertion groove 540, the fluid inflow portion 200 can be prevented from rotating.

As shown in FIGS. 1 and 6, the flow modifying unit 300 may be provided with a plurality of flow modifying passages 310 communicating with a plurality of fluid inflow passages 210 of the fluid inflow unit 200, respectively. In this embodiment, the flow changing path 310 may be provided in a line in an imaginary line passing through the center of the flow changing part 300. In this case, as shown in the figure, a plurality of flow changing grooves 311 are formed in the flow changing part 300 so that each of the plurality of fluid inflow paths 210 and the corresponding plurality of flow changing paths 310 can communicate with each other . In this embodiment, the flow changing groove 311 is formed around the center flow changing path 310 and the lowermost flow changing path 310 among the three flow changing paths 310 as shown in the figure. This is to allow each of the plurality of fluids to flow into each of the flow changing paths 310 arranged in a line in the flow changing portion 300. On the other hand, the uppermost flow path 310 is connected to the fluid inflow path 210 without passing through the flow changing groove 311. Each of the plurality of fluids supplied from the fluid supply source and passing through the inflow hole 211 through the inflow pipe 212 of the fluid inflow section 200 is directly connected to the flow change path 310 Or may flow along the flow changing groove 311 and flow into the flow changing passage 310. In this case, However, the position of the flow changing passage 310 in the flow changing portion 300 is not limited to the present embodiment, but may be changed depending on the rotational position of the fluid outflow portion 400, which will be described later, Any position can be used as long as it can communicate with one of the passages 410.

A first sealing member 700 may be inserted between the fluid inlet portion 200 and the flow changing portion 300 as shown in FIG. For this purpose, as shown in FIGS. 1 and 6, a first sealing member inserting groove 320 may be formed in the flow changing portion 300 to allow the first sealing member 700 to be inserted therein. As the first sealing member 700 is inserted into the first sealing member insertion groove 320 and the first sealing member 700 is positioned between the fluid inlet portion 200 and the flow changing portion 300, So that the sealing between the flow regulating portion 200 and the flow regulating portion 300 can be further strengthened. The flow changing portion 300 may also be formed with one or more fitting grooves 330 into which one or more fitting protrusions 222, which can be formed in the fluid inlet portion 200, are fitted.

As shown in FIGS. 1 and 8, the fluid outlet 400 may include a plurality of fluid outflow passages 410. The fluid outlet portion 400 may also be configured to be rotatable relative to the flow changing portion 300. The fluid outlet portion 400 may be inserted into the insertion groove 220 of the fluid inlet portion 200 together with the flow changing portion 300 as described above. Meanwhile, one or more fitting grooves 330 may be formed in the flow changing portion 300. The insertion groove 220 may have at least one fitting protrusion 222 inserted into the fitting groove 330. Therefore, when the flow changing part 300 is inserted into the insertion groove 220, the insertion protrusion 222 is inserted into the insertion groove 330 formed therein, and therefore, the flow changing part 300 can not be rotated. One or more hook portions 221 may be formed in the fluid inlet portion 200 so that when the flow changing portion 300 and the fluid outlet portion 400 are inserted into the insertion groove 220, 300 and the fluid outlet 400 may not be released to the outside. Accordingly, the fluid outlet portion 400 is inserted into the insertion groove 220 of the fluid inlet portion 200 and is not allowed to rotate, as described above, without being detached by the hook portion 221, (Not shown).

One of the plurality of flow changing paths 310 provided in the flow changing portion 300 and one of the plurality of fluid outflow paths 410 are connected to the fluid outlet portion 400 according to the rotational position of the fluid outlet portion 400, Lt; / RTI > To this end, as shown in this embodiment, each of the plurality of fluid outflow passages 410 is connected to one of the plurality of flow modifying passages 310 communicating with the fluid outflow portion 400 according to the rotational position of the fluid outflow portion 400 May be provided at a position on a virtual arc that may be formed in the fluid outlet 400 with a distance from the center of the fluid outlet 400 as a radius. When each of the plurality of fluid outflow passages 410 is provided in the fluid outflow portion 400 as described below, the fluid outflow portion 400 is rotated by a predetermined angle, So that one of the passages 410 can communicate with each other. At this time, the remaining flow changing path 310 and the fluid outflow path 410 are staggered from each other, so that they can not communicate with each other. Accordingly, only one of the plurality of fluids flows out to the outside through one of the plurality of fluid outflow paths 410. The fluid outflow path 410 may include a plurality of outflow holes 411 formed in the fluid outflow portion 400 and an outflow pipe 412 communicated with each of the plurality of outflow holes 411 as illustrated. Accordingly, the fluid that has flowed into one of the plurality of flow modifying paths 310 in the flow modifying path 310 is guided to the outflow hole 310 communicating with the flow modifying path 310 by a predetermined angle of rotation of the fluid outlet portion 400 411 and then flows out to the outside through an outlet pipe 412 communicated with the outlet pipe 412. [ However, the configuration of the fluid outflow path 410 is not limited to the present embodiment, but may be configured to communicate with one of the plurality of flow modification paths 310 by rotation of the fluid outflow portion 400, Anything is possible as long as one fluid can flow out.

The fluid outlet 400 may be provided with one or more holes 430 formed therein as shown in FIG. The hole formed in the fixing portion 430 may correspond to the hole of the fixing protrusion 630 which may be provided in the second cover 600 described later. Therefore, the fluid outlet portion 400 can be fixed to the second cover 600 by inserting a bolt or the like into the hole formed in the fixing portion 430 and the hole formed in the fixing projection 630 and tightening. Further, as described later, the second cover 600 may be provided with a lever 610. Therefore, the user can hold the lever 610 and rotate the second cover 600. [ As a result, a rotational force acts on the fluid outlet portion 400 that can be fixed to the second cover 600, so that the flow change is inserted into the insertion groove 220 together with the fluid outlet portion 400, Thereby enabling to rotate with respect to the portion 300. However, the structure in which the fluid outlet portion 400 is rotated by the fluid outlet portion 400 so that the fluid outlet portion 400 can rotate with respect to the fluid outlet portion 300 is not limited to the structure as in the present embodiment, 400 may be rotated with respect to the flow changing part 300, any structure may be employed as long as it applies a rotational force to the fluid outflow part 400. A second sealing member 800 may be inserted between the flow changing portion 300 and the fluid outlet portion 400 as shown in FIG. For this purpose, as shown in FIGS. 1 and 8, a second sealing member inserting groove 420 may be formed in the fluid outlet 400 to allow the second sealing member 800 to be inserted therein. The second sealing member 800 is inserted into the second sealing member insertion groove 420 and the second sealing member 800 is positioned between the flow changing portion 300 and the fluid outlet portion 400, The sealing between the fluid outlet portion 300 and the fluid outlet portion 400 can be further strengthened.

1, the water purifier cock valve 100 according to the present invention includes a first cover 500 located on the fluid inlet portion 200 side and a second cover portion 500 located on the fluid outlet portion 400 side 600).

1 and 3, the first cover 500 includes a plurality of inflow pipe passing holes 510 through which a plurality of inflow pipes 212 respectively included in the plurality of fluid inflow paths 210 pass, . Accordingly, each of the plurality of fluid supply sources may be connected to the plurality of inflow pipes 212 through a connection pipe or the like. Further, the first cover 500 may be formed with a guide hole 520 as shown in FIG. In this case, the shape of the guide hole 520 may be a part of an arc as shown in the figure. One or more guide protrusions 640, which may be included in the second cover 600 described later, may be inserted into the guide hole 520, so that the rotation of the second cover 600, that is, And can guide the rotation of the unit 400 when it rotates. As shown in the figure, the first cover 500 may be formed with a projection insertion groove 530 having a hole. Therefore, as described above, the fixing protrusion 230 formed in the fluid inlet portion 200 is inserted therein, and a bolt or the like is inserted into the hole formed in the projection insertion groove 530 and the hole formed in the fixing projection 230 By tightening, the fluid inlet portion 200 can be fixed to the first cover 500. The first cover 500 may have a fluid inlet insertion groove 540 through which the fluid inlet 200 can be inserted. Also, at least one fitting groove 541 may be formed in the fluid inlet insertion groove 540. The fluid inlet 200 is inserted into the fluid inlet insert groove 540 so that at least one fit protrusion 240 formed in the fluid inlet 200 is inserted into the fluid inlet insert groove 540, May be inserted into at least one fitting groove (541) formed in the fluid inlet (200) to prevent the fluid inlet (200) from rotating.

The first cover 500 may be formed with a through-hole 550 as shown in FIG. The wires to be connected to the circuit board 660 provided in the second cover 600, which will be described later, can be passed through the wire passing holes 550. The first cover 500 may be formed with a magnet insertion groove 560 as shown in FIG. The magnet inserted into the magnet insertion groove 560 interacts with a position sensor 670 to be described below which may be provided on the circuit board 660 to prevent the second cover 600, 400, for example. The first fitting protrusion 570 may be formed on the outer circumferential end of the first cover 500 so as to correspond to the second fitting protrusion 650 formed on the second cover 600, . Whereby the first cover 500 can be fitted to the second cover 600. The first cover 500 may be formed with a plurality of rotation position detecting grooves 580 according to respective rotational positions at which the fluid flows out. By the action of the rotation position detecting stopper 680 that can be provided to the rotation position detecting groove 580 and the second cover 600 to be described later, the second cover 600, that is, The user can know the rotational position at which the fluid of the fluid outlet 400 flows out through sound or the like.

As shown in FIGS. 1 and 9, the second cover 600 may be provided with a lever 610. Thus, the user may apply a rotational force to the fluid outlet 400, which may be secured to the second cover 600, i.e., the second cover 600, using the lever 610 to change the fluid outlet 400 to a flow change As shown in Fig. A plurality of outflow pipe protective pipes 620 may be formed on the second cover 600 to protect the plurality of outflow pipes 412 included in the plurality of fluid outflow paths 410, respectively. Each of the plurality of outflow pipes 412 may be inserted into and protected by a plurality of outflow pipe protection pipes 620 as shown in FIG. At least one fixing protrusion 630 may be formed in the second cover 600 as shown in FIG. A hole may be formed in the fixing protrusion 630 and a hole formed in the fixing protrusion 630 may correspond to a hole formed in the fixing portion 430 of the fluid outlet portion 400 as described above. Therefore, the fluid outlet portion 400 can be fixed to the second cover 600 by inserting a bolt or the like into the hole formed in the fixing portion 430 and the hole formed in the fixing projection 630 and tightening. The second cover 600 may be provided with one or more guide protrusions 640 as shown in FIG. The guide protrusion 640 may be inserted into the guide hole 520 formed in the first cover 500 and guide the guide protrusion 640 when the user rotates the second cover 600 using the lever 610. The second fitting protrusion 650 may be formed on the outer circumferential end of the second cover 600 so as to correspond to the first fitting protrusion 570 formed on the first cover 500 as shown in FIG. The first cover 500 and the second cover 600 are fitted to each other so that the first cover 500 and the second cover 600 are fitted to each other, The cover 600 can be fitted.

The second cover 600 may be provided with a circuit board 660 as shown in FIG. The circuit board 660 may be provided with a position sensor 670 to detect the rotational position of the second cover 600. The position sensor 670 may be included in the second cover 600 as in the present embodiment, but may be provided in the first cover 500 as well. In the present embodiment, the position sensor 670 uses a hall sensor for detecting the rotational position using a Hall effect. However, the position sensor 670 may be any as long as it can detect the rotational position of the second cover 600, that is, the fluid outlet portion 400 which may be fixed thereto. When the Hössens book is used as the position sensor 670, a magnet may be inserted into the magnet insertion groove 560 formed in the first cover 500 to form a magnetic field, as described above. In addition, a plurality of position sensors 670 may be provided on the circuit board 660 so that each rotational position at which the fluid flows out can be detected. For example, in the present embodiment, three position sensors 670 may be provided on the circuit board 660 as shown to detect three rotational positions. In this case, by the rotation of the second cover 600, one of the plurality of position sensors 670 senses the magnetic field formed by the magnet inserted in the magnet insertion groove 560 of the first cover 500, 600 can be detected. In addition, a plurality of LEDs (not shown) may be provided on the circuit board 660. The plurality of LEDs may be electrically connected to the plurality of position sensors 670 through the circuit board 660, respectively. Accordingly, when one of the plurality of position sensors 670 senses the rotational position at which the fluid flows out of the plurality of rotational positions, the LED connected to the rotational position is turned on to display the fluid currently flowing out. For example, in the case of the present embodiment, when the purified water, the warm water, or the purified water in the cold water flows out, one of the three position sensors 670 senses the rotational position of the corresponding second cover 600, The LED may be turned on. In addition, an opening / closing valve (not shown) may be provided in each of the plurality of fluid outflow paths 410. Each on / off valve may also be electrically connected to each of the plurality of position sensors 670 via the circuit board 660. In addition, the second cover 600 may be provided with a fluid outflow button (not shown). In this case, if the user does not press the fluid outflow button, even if the second cover 600 rotates to one of the plurality of fluid outflow positions, the fluid is prevented from flowing out to the outside through the fluid outflow path 410 . At this time, when the user presses the fluid outflow button, the open / close valve provided in the fluid outflow path 410 rotated to the fluid outflow position among the open / close valves, which may be provided in each of the plurality of fluid outflow paths 410, have. This function may be performed by an electric circuit (not shown) which may be provided on the circuit board 660.

In addition to being capable of electrically detecting the rotational position as described above, it is also possible to allow the user to know the rotational position by sound or the like. For this purpose, the second cover 600 is provided with a rotation position detecting stopper 680, which can be respectively positioned in the rotation position detecting groove 580 formed in the first cover 500 according to the rotational position . In this embodiment, the rotational position detecting stopper 680 is elastically supported by a spring (not shown) incorporated in the rotational position detecting stopper 680. When the ball 681 of the rotational position detecting stopper 680 is not inserted into the rotational position detecting groove 580 by the rotation of the second cover 600, the ball 681 is rotated by the rotational position detecting stopper 680, When the second cover 600 rotates at a predetermined angle and the ball 681 of the rotation position detecting stopper 680 is positioned in the rotation position detecting groove 580, The ball 681 is inserted into the rotation position detection groove 580 by the elastic force of the elastic supporting spring and the user can know the rotation position of the second cover 600 due to the clicking sound.

The first cover 500 included in the water purifier cock 100 according to the present invention and the fluid inlet 200, the first sealing member 700, the flow changing portion 300, When the sealing member 800, the fluid outlet 400, and the second cover 600 are assembled in order, the water purifier cock 100 is formed as shown in FIG. The cockpit valve 100 for the water purifier assembled as described above may be provided in a water purifier (not shown).

Hereinafter, the operation of the water purifier cock valve 100 according to the present invention will be described in detail with reference to FIGS. 10 to 12. FIG. A plurality of inflow pipes 212 (three inflow pipes 212 in this embodiment) included in the cock pump 100 according to the present invention as shown in FIG. 2 are connected to a water purifier Such as, for example, a purified water tank, a warm water tank, or a cold water tank. Thus, when each of the plurality of inflow pipes 212 is connected to a different fluid supply source, each fluid flows from the fluid supply source to the connection pipe and flows into each inflow pipe 212. The fluid introduced into the inlet pipe 212 flows directly into the flow changing passage 310 through the inlet hole 211 or flows into the flow changing groove 311 and then flows along the flow changing groove 311 And flows to the flow changing path 310. If the rotational position of the fluid outlet 400 is at a position not in communication with any of the fluid outlet passages 410, the fluid will stop at the fluid change path 310.

In this state, when the second cover 600 is rotated using the lever 610 to a position as shown in FIG. 10A, the fluid outlet portion 400, which can be fixed to the second cover 600, (Not shown). 10 (b), the uppermost flow changing path 310 and the plurality of flow changing paths 310 formed in the fluid outlet portion 400 of the plurality of flow changing paths 310 formed in the flow changing portion 300, The fluid outflow passages 410 at the uppermost one of the fluid outflow passages 410 coincide with each other to communicate with each other and the remaining fluidic change passages 310 and the fluid outflow passages 410 are staggered from each other and can not communicate with each other. Therefore, only the fluid stopped at the uppermost flow changing path 310 flows out to the outside through the uppermost fluid outflow path 410. For example, if the purified water has stopped at the uppermost flow changing path 310, the purified water flows out to the outside through the uppermost fluid outflow path 410.

When the second cover 600 is rotated using the lever 610 to the position shown in FIG. 11A, the fluid outlet portion 400, which can be fixed to the second cover 600, And rotates with the second cover 600. 11 (b), at the lowest position of the plurality of flow changing paths 310 formed in the flow changing portion 300 and the plurality of flow changing paths 310 formed in the fluid outflow portion 400 The fluid outflow passages 410 in the lowermost one of the fluid outflow passages 410 coincide with each other to communicate with each other and the remaining fluidic change passages 310 and the fluid outflow passages 410 are staggered from each other and can not communicate with each other. Therefore, only the fluid stopped at the lowermost flow changing path 310 flows out through the lowermost fluid outflow path 410 to the outside. For example, if the warming water has stopped at the lowermost flow changing path 310, the warming water flows out to the outside through the fluid outflow path 410 having the lowest level.

When the second cover 600 is rotated using the lever 610 to the position shown in FIG. 12A, the fluid outlet portion 400, which can be fixed to the second cover 600, Rotate together. 12 (b), a central flow path 310 of the plurality of flow path changing paths 310 formed in the flow changing part 300 and a plurality of The central fluid outflow passages 410 of the fluid outflow passages 410 are in communication with each other and the remaining fluidized outflow passages 310 and the fluid outflow passages 410 are staggered from each other and can not communicate with each other. Accordingly, only the fluid stopped at the central flow path 310 flows out to the outside through the central fluid outflow path 410. For example, if the cold water has stopped at the central flow path 310, the cold water flows out to the outside through the central fluid outflow path 410.

When the water purifier cock 100 according to the present invention is used in a water purifier, a plurality of different fluids can be flowed out through separate outflow passages by a single water purifier cock pump, Only one of the plurality of fluids can be discharged, the rotation position of the cock valve through which the fluid flows can be detected, the rotation position of the cock valve through which the fluid flows can be detected and displayed to the user, The opening / closing valve provided in the outflow passage can be opened.

The above-described water purifier cock valve can be applied to a water pump of a water purifier according to the embodiment of the present invention. have.

1 is an exploded perspective view of an embodiment of a cock pump for a water purifier according to the present invention.

FIG. 2 is a view showing an embodiment of a cock pump for a water purifier according to the present invention shown in FIG. 1; FIG.

3 is a view showing a first cover included in an embodiment of a cock pump for a water purifier according to the present invention.

4 is a view of a fluid inlet included in an embodiment of a cock pump for a water purifier according to the present invention.

5 is a view showing a first sealing member included in an embodiment of a cock pump for a water purifier according to the present invention.

6 is a view showing a flow changing part included in an embodiment of a cock pump for a water purifier according to the present invention.

7 is a view showing a second sealing member included in an embodiment of a cock pump for a water purifier according to the present invention.

8 is a view of a fluid outlet included in an embodiment of a cock pump for a water purifier according to the present invention.

9 is a view showing a second cover included in an embodiment of a cock pump for a water purifier according to the present invention.

10 is a first use state view of an embodiment of a cock pump for a water purifier according to the present invention.

11 is a second use state view of an embodiment of a cock pump for a water purifier according to the present invention.

12 is a third use state view of an embodiment of a cock pump for a water purifier according to the present invention.

        Description of the Related Art [0002]

100: Cock valve 200: Fluid inlet

210: fluid inflow path 211: inflow hole

212: inlet pipe 220: insertion groove

221: hook portion 222, 240:

230, 630: Fixing projection 300: Flow changing part

310: Flow change path 311: Flow change path

320: first sealing member insertion groove 330, 541: fitting groove

400: fluid outflow portion 410: fluid outflow path

411: outflow hole 412: outflow pipe

420: second sealing member insertion groove 430:

500: first cover 510: inlet pipe passage hole

520: guide hole 530: projection insertion groove

540: fluid inlet portion insertion groove 550: wire passage hole

560: magnet insertion groove 570: first fitting jaw

580: Rotation position detecting groove 600: Second cover

610: Lever 620: Outlet pipe protection pipe

640: guide projection 650: second fitting jaw

660: circuit board 670: position sensor

680: Stopper for detecting rotational position 681: Ball

700: first sealing member 800: second sealing member

Claims (9)

A fluid inlet (200) having a plurality of fluid inlets (210) connected to a plurality of different fluid sources; A flow changing part 300 having a plurality of flow changing paths 310 communicating with the plurality of fluid inflow paths 210; And A plurality of fluid outflow passages 410 are provided and are rotatable with respect to the fluid flow modifying portion 300 and are connected to one of the plurality of flow modifying passages 310 and one of the plurality of fluid outflow passages 410 A fluid outlet portion 400 communicating with the fluid outlet portion 400; And, Each of the plurality of fluid outflow passages 410 has a distance from a center of the flow changing portion 300 of one of the plurality of flow modifying paths 310 communicating with the rotational position of the fluid outflow portion 400, Is formed at a position on a virtual circular arc that can be formed in the fluid outlet (400) with a radius. delete A fluid inlet (200) having a plurality of fluid inlets (210) connected to a plurality of different fluid sources; A flow changing part 300 having a plurality of flow changing paths 310 communicating with the plurality of fluid inflow paths 210; And A plurality of fluid outflow passages 410 are provided and are rotatable with respect to the fluid flow modifying portion 300 and are connected to one of the plurality of flow modifying passages 310 and one of the plurality of fluid outflow passages 410 A fluid outlet portion 400 communicating with the fluid outlet portion 400; And, Wherein the plurality of flow changing paths (310) are arranged in a line in a virtual line passing through the center of the flow changing part (300). 4. The apparatus according to claim 3, wherein the flow changing part (300) is formed with a plurality of flow changing grooves (311) so that each of the plurality of fluid inflow paths (210) and the plurality of flow changing paths (310) Wherein the water pump is a water pump. A fluid inlet (200) having a plurality of fluid inlets (210) connected to a plurality of different fluid sources; A flow changing part 300 having a plurality of flow changing paths 310 communicating with the plurality of fluid inflow paths 210; A plurality of fluid outflow passages 410 are provided and are rotatable with respect to the fluid flow modifying portion 300 and are connected to one of the plurality of flow modifying passages 310 and one of the plurality of fluid outflow passages 410 A fluid outlet portion 400 communicating with the fluid outlet portion 400; And a plurality of inflow pipe holes (510) passing through the plurality of inflow pipes (212) located on the fluid inflow part (200) side and respectively included in the plurality of fluid inflow paths (210) 500); And A plurality of outflow pipe protection pipes 620 are provided on the fluid outflow portion 400 side and are provided with levers 610 and protect a plurality of outflow pipes 412 included respectively in the plurality of fluid outflow paths 410. [ A second cover 600 formed on the second cover 600; And a water supply pipe connected to the water supply pipe. 6. The water purifier according to claim 5, wherein the first cover (500) or the second cover (600) is provided with a position sensor (670) for detecting the rotational position of the second cover (600) Cock valve. The apparatus according to claim 5, wherein the first cover (500) is provided with a plurality of rotation position detection grooves (580), and the second cover (600) And a rotational position detecting stopper (680) capable of being positioned in each of the rotational position detecting grooves (580). The water purifier of any one of claims 1, 3 and 4, wherein a first sealing member (700) is inserted between the fluid inlet (200) and the flow changer (300) Fork cock valve. The water purifier according to any one of claims 1, 3 and 4, wherein a second sealing member (800) is inserted between the flow changing part (300) and the fluid outlet part (400) Fork cock valve.

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