JP2011520051A - Bidet flow system - Google Patents

Abstract

A bidet flow path system capable of supplying raw water at room temperature to a sterilizer is disclosed.
The bidet flow path system according to the present invention includes a flow path switching valve for switching the flow path so that the raw water flowing from the raw water supply section flows into at least one flow path among the plurality of flow paths, and the discharge of the flow path switching valve. A sterilizer that generates nozzle cleaning water containing antibacterial and / or sterilizing substances from the supplied raw water, and heating that is connected to the discharge side of the flow path switching valve and heats the supplied raw water A member, and a nozzle unit that is connected to the sterilizer and the heating member, and is provided with at least one nozzle to which nozzle cleaning water or warm water is supplied.

Description

  The present invention relates to a bidet channel system, and more particularly to a bidet channel system capable of supplying raw water at room temperature to a sterilizer.

  A washing machine, commonly referred to as a bidet, is installed integrally with the seat of the toilet seat, and the user does not use toilet paper after stool, and the user's anus or woman's local area is washed with washing water sprayed from the nozzle It is a device for doing. The nozzle includes a cleaning nozzle that cleans the user's anus and a bidet nozzle that cleans the local area of the woman, and may include a cleaning nozzle and / or a nozzle cleaning water discharge unit that cleans the bidet nozzle.

  Further, the bidet is provided with a cleaning nozzle, a bidet nozzle, and a flow path switching valve for switching the flow path so that cleaning water or nozzle cleaning water selectively flows into the nozzle cleaning water discharge section. Accordingly, the cleaning water or the nozzle cleaning water is distributed and flows to the respective nozzles by the operation of the flow path switching valve.

  FIG. 1 is a block diagram showing a bidet channel system according to the prior art.

  Referring to FIG. 1, a conventional bidet channel system 10 includes a water inlet valve 11, a hot water tank 12, a channel switching valve 13, a sterilizer 17, and a nozzle unit 18. The water used for the bidet is introduced through the water inlet valve 11, and the introduced water is stored in the hot water tank 12 and heated to an appropriate temperature. Therefore, when the user uses the bidet, the hot water stored in the hot water tank 12 is supplied to the nozzle unit 18.

  In addition, the flow path switching valve 13 is connected to the hot water tank 12 so that hot water supplied from the hot water tank 12 is supplied to a cleaning nozzle and a bidet nozzle provided in the nozzle unit 18 or supplied to the nozzle cleaning water discharge unit through the sterilizer 17. I will let you.

  For example, when the user selects the cleaning function, the flow path of the flow path switching valve 13 is switched, and hot water supplied from the hot water tank 12 is jetted from the cleaning nozzle through the cleaning nozzle flow path 15, and the user selects the bidet function. The flow path of the flow path switching valve 13 is switched and hot water supplied from the hot water tank 12 is jetted from the bidet nozzle through the bidet nozzle flow path 16.

  On the other hand, when the user's seating is detected by the sensor that detects the user's seating, the bidet supplies hot water to the nozzle cleaning water discharge section through the nozzle cleaning channel 14, and the bidet nozzle and / or the cleaning nozzle is cleaned. At this time, the nozzle cleaning flow path 14 is provided with a sterilization device 17 that generates nozzle cleaning water containing antibacterial and / or sterilizing substances, and supplies the nozzle cleaning water to the nozzle cleaning water discharge unit, thereby the cleaning nozzle and / or Alternatively, the bidet nozzle is sterilized and washed. Such a sterilizer 17 serves to generate nozzle cleaning water through electrolysis so that water supplied to the nozzle cleaning water discharge unit has a sterilizing action in order to forcibly clean the cleaning nozzle and the bidet nozzle. .

  For example, the sterilizer 17 can be configured to ionize the supplied raw water to produce nozzle wash water containing antibacterial and / or sterilizing substances. Accordingly, the nozzle cleaning water generated by the sterilization apparatus 17 is supplied to the nozzle cleaning water discharge unit, and sterilizes the cleaning nozzle and the bidet nozzle.

  On the other hand, when the user selects the nozzle cleaning function, hot water is supplied to the sterilizing device 17 through the nozzle cleaning flow path 14, and the nozzle cleaning water generated by the sterilizing device 17 is supplied to the nozzle cleaning water discharge unit to be cleaned. And / or the bidet nozzle is cleaned.

  However, in the conventional bidet channel system 10, since the channel switching valve 13 is mounted between the hot water tank 12 and the nozzle unit 18, the cleaning nozzle, the bidet nozzle and the nozzle cleaning water discharge unit provided in the nozzle unit 18 are always equipped. Hot water is supplied. Accordingly, when the cleaning nozzle and the bidet nozzle are cleaned, the hot water is used and wasted.

  Eventually, when hot water is not required, hot water is used, so energy loss occurs for heating the raw water, and the storage capacity of the hot water tank 12 must be set in consideration of the amount of hot water used unnecessarily. In other words, the storage capacity of the hot water tank 12 increases unnecessarily.

  Moreover, in the conventional bidet flow path system 10, since hot water is supplied to the sterilizer 17, electrolysis efficiency is lower than when cold water is supplied, and effective nozzle cleaning water is not generated. There is a problem. That is, by using warm water that is not room temperature water (or cold water) as raw water for generating nozzle washing water, nozzle washing water having a lower sterilization performance than when generating nozzle washing water using room temperature water is used. generate. Accordingly, there is a problem that the nozzle cleaning performance, that is, the sterilization performance is deteriorated.

  Further, in the conventional bidet flow path system 10, the flow path switching valve 13 is provided at the rear end of the hot water tank 12, so that the flow rate that has already entered the hot water tank 12 through the water inlet valve 11 is controlled by the flow path switching valve 13. . As a result, since a negative pressure is generated in the hot water tank 12, it is necessary to reinforce the strength of the hot water tank 12 to withstand such a negative pressure, which causes an increase in cost. In addition, there is a problem that water leakage occurs due to the negative pressure generated in the hot water tank 12, which may cause an electric shock accident.

  The present invention has been devised in order to solve at least a part of the above-described problems of the prior art, and can supply water having a temperature suitable for the component parts of the bidet. It is an object of the present invention to provide a bidet channel system that can be enhanced.

  It is another object of the present invention to provide a bidet flow path system in which nozzle cleaning water with improved sterilization performance is generated, thereby improving nozzle cleaning performance and preventing unnecessary use of hot water. .

  Another object of the present invention is to provide a bidet channel system that can implement a complex channel while reducing the number of components.

  As one aspect for achieving the above-described object, the present invention provides a flow path switching valve that switches a flow path so that raw water flowing from a raw water supply section flows into at least one flow path among a plurality of flow paths, Connected to the discharge side of the flow path switching valve, connected to the discharge side of the flow path switching valve, and a sterilization device that generates nozzle cleaning water containing antibacterial and / or sterilizing substances from the supplied raw water There is provided a bidet flow path system including a heating member that heats raw water, and a sterilizer and a nozzle unit that is connected to the heating member and is provided with at least one nozzle that is supplied with nozzle cleaning water or hot water.

  Preferably, the bidet flow path system is disposed between the heating member and the nozzle portion, and the hot water discharged from the heating member flows to only one of the nozzles provided in the nozzle portion. A branch valve may be further included.

  As another aspect, the present invention relates to a sterilizer that generates nozzle cleaning water containing antibacterial and / or sterilizing substances, a heating member that heats supplied raw water, and nozzle cleaning water generated by the sterilizer. Or a nozzle part provided with at least one nozzle to which hot water heated by the heating member is supplied, and connected to the inflow side of the sterilizer and the heating member, and the raw water supplied from the raw water supply part is converted into the sterilizer. Alternatively, a bidet including a flow path switching valve that selectively supplies the heating member and is connected to a discharge side of the heating member and switches the flow path so as to supply hot water heated by the heating member to the nozzle portion. A flow path system is provided.

  Preferably, the flow path switching valve can block the flow path connected to the heating member when the raw water flowing in from the raw water supply unit is discharged to the sterilizer.

  Preferably, the flow path switching valve is connected to the inflow side and the discharge side of the heating member when the hot water flows through the nozzle portion, blocking the flow path connected to the sterilizer. The flow path and the flow path connected to the nozzle part can be opened in conjunction with each other.

  Preferably, the nozzle unit includes a plurality of nozzles, and the flow path switching valve switches the flow path so that the hot water flowing from the heating member is selectively discharged to one of the plurality of nozzles. it can.

  In addition, the sterilizing material may include an oxidizing mixed material generated by electrolysis.

  The sterilizing material may contain iodine or silver oxide.

  According to one embodiment of the present invention, by arranging the flow path switching valve at the front end of the heating member, it is possible to supply water at a temperature suitable for the component parts of the bidet, and to increase the use efficiency of the hot water. effective.

  Also, according to one embodiment of the present invention, the flow path switching valve is arranged at the front end of the heating member, so that raw water at room temperature, not hot water, can be supplied to the sterilizer, and the nozzle cleaning with improved sterilization performance Water is produced, which has the effect of increasing nozzle cleaning performance, i.e., sterilization efficiency.

  In addition, according to an embodiment of the present invention, since raw water at room temperature is supplied to the sterilizer, an effect that unnecessary use of hot water can be prevented is obtained.

  In addition, according to an embodiment of the present invention, since a plurality of flow paths are implemented through one flow path switching valve, the flow path structure is simplified and the number of components is reduced.

It is a block diagram which shows the channel system of a bidet by a prior art. 1 is a configuration diagram illustrating a bidet channel system according to an embodiment of the present invention; It is a block diagram which shows the flow-path system of the bidet by the other Example of this invention. FIG. 4 is an exploded perspective view illustrating an embodiment of the flow path switching valve illustrated in FIG. 3. FIG. 5 is a plan view of a second housing of the flow path switching valve illustrated in FIG. 4. 4A and 4B illustrate a fixed disk of the flow path switching valve illustrated in FIG. 4, where FIG. 4A is a plan view, FIG. 4B is a bottom view, and FIG. 4C is a cross-sectional view taken along line AA in FIG. is there. 4A and 4B illustrate a rotating disk of the flow path switching valve illustrated in FIG. 4, where FIG. 4A is a plan view, FIG. 4B is a bottom view, and FIG. 4C is a cross-sectional view taken along line BB in FIG. is there. FIG. 5 is a schematic diagram of a state in which a fixed disk is mounted on a second housing of the flow path switching valve illustrated in FIG. 4. FIG. 9 is a schematic diagram illustrating a state in which a rotating disk is mounted on the fixed disk of FIG. FIG. 9 is a schematic diagram illustrating a state in which a rotating disk is mounted on the fixed disk of FIG. 8 and rotated, and is a position of the rotating disk when performing a nozzle cleaning function. FIG. 9 is a schematic diagram illustrating a state in which a rotating disk is mounted on the fixed disk of FIG. FIG. 9 is a schematic diagram illustrating a state in which a rotating disk is mounted on the fixed disk of FIG.

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

  FIG. 2 is a block diagram showing a bidet flow path system according to an embodiment of the present invention.

  Referring to FIG. 2, a bidet channel system 300 according to an embodiment of the present invention includes a channel switching valve 320, a sterilizer 340, a heating member 360, a branch valve 370, and a nozzle unit 380.

  The raw water supplied from the raw water supply unit 310 that includes a valve and adjusts the supply of the raw water flows into the flow path switching valve 320 through the raw water inflow path 315. As a result, normal temperature raw water from the raw water supply unit 310 flows into the flow path switching valve 320.

  In addition, the flow path switching valve 320 switches the flow path so that the flowed-in water flows to at least one of the multiple flow paths arranged on the discharge side of the flow path switching valve 320. That is, the flow path switching valve 320 includes a plurality of discharge ports (not shown), and discharges the raw water that has flowed into at least one of the plurality of discharge ports.

  In addition, the sterilizer 340 is connected to the discharge side of the flow path switching valve 320 through the nozzle cleaning flow path 325, whereby normal temperature raw water is supplied to the sterilization apparatus 340 from the flow path switching valve 320. The sterilizer 340 generates nozzle cleaning water containing antibacterial and / or sterilizing substances so that the water supplied to the nozzle cleaning water discharge unit 381 through the nozzle cleaning water supply channel 345 has a sterilizing action. At least one nozzle provided in the nozzle is cleaned through nozzle cleaning water.

If the said sterilizer 340 can produce | generate the nozzle washing water containing an antibacterial and / or sterilization substance, the kind and structure of the said sterilizer 340 will not be restrict | limited in particular. For example, the sterilizer 340 has a bactericidal action such as hypochlorous acid (HOCl), hypochlorite ion (OCl ⁻ ), chlorine (Cl ₂ ), antibacterial and / or bactericidal ions or free radicals. It is possible to have a configuration that generates various oxidizing mixed substances. Here, the oxidizing mixed material may be generated by electrolysis while water passes between electrodes having different polarities. In this case, the oxidizing mixed substance functions as an antibacterial and / or bactericidal substance. On the other hand, the sterilizer 340 may be configured by a device that discharges a certain amount of antibacterial and / or sterilizing substances such as iodine and silver oxide.

  The heating member 360 is connected to the discharge side of the flow path switching valve 320 through the heating raw water supply flow path 330, and normal temperature raw water discharged from the flow path switching valve 320 is supplied to the heating member 360. Further, the discharge side of the heating member 360 is connected to the nozzle unit 380 through the hot water supply channel 365. The heating member 360 may include a hot water tank that heats and stores the water that has flowed into the interior, but is not limited thereto, and is instantaneous heating that is instantaneously heated while the water that has flowed in flows. It can also consist of a device. Accordingly, when the user uses the cleaning function or the bidet function, hot water heated by the heating member 360 is jetted through the nozzle unit 380.

  In addition, the nozzle unit 380 can include a cleaning nozzle 382 for cleaning the anus, a bidet nozzle 383 for cleaning a local area of a woman, and the like, and nozzle cleaning water for cleaning the cleaning nozzle 382 and / or the bidet nozzle 383. A discharge unit 381 can be provided.

  As described above, when the nozzle unit 380 includes a plurality of nozzles, the branch valve 370 is provided so that the hot water discharged from the heating member 360 is supplied to only one of the nozzles provided in the nozzle unit 380. be able to. The branch valve 370 is connected to the heating member 360 through the hot water supply channel 365, and receives one of the cleaning nozzle channel 375a and the bidet nozzle channel 375b in response to the supply of hot water discharged from the heating member 360. Hot water is selectively supplied to the washing nozzle 382 or the bidet nozzle 383 through the flow path.

  2 is disposed at the front ends of the sterilization device 340 and the heating member 360, and the raw water at room temperature is supplied to the sterilization device 340. Only one of the heating members 360 is selectively supplied.

  That is, when hot water is used in the nozzle unit 380, the flow path switching valve 320 switches the flow path so that raw water flows only to the heating member 360, and the hot water discharged from the heating member 360 is branched by the branch valve 370. Then, it is supplied to the cleaning nozzle 382 or the bidet nozzle 383 through one of the cleaning nozzle flow path 375a and the bidet nozzle flow path 375b, and is injected. When the cleaning nozzle 382 or the bidet nozzle 383 needs to be sterilized and cleaned, the flow path switching valve 320 switches the flow path so that the raw water at room temperature flows only to the sterilizer 340, and the nozzle cleaning water generated by the sterilizer 340 is used. Is supplied to the nozzle cleaning water discharge unit 381 through the nozzle cleaning water supply channel 345 to clean the nozzles.

  On the other hand, since the flow path switching valve 320 and the branch valve 370 used in the bidet flow path system 300 shown in FIG. To do.

  As described above, according to the bidet flow path system 300 according to an embodiment of the present invention, the flow path switching valve 320 is disposed at the front ends of the sterilization apparatus 340 and the heating member 360, and normal temperature raw water flows into the sterilization apparatus 340. Therefore, energy loss caused by unnecessary heating can be prevented, and the hot water storage capacity of the heating member 360 can be reduced.

  That is, in the prior art shown in FIG. 1, since warm water is supplied to the sterilizer, unnecessary energy loss occurs, and the capacity of the hot water tank is increased corresponding to the amount of water supplied to the sterilizer. As shown in FIG. 2, the bidet flow path system 300 according to an embodiment of the present invention solves the problems of the prior art because raw water at room temperature flows into the sterilizer 340. Can do.

  In addition, the bidet flow path system 300 according to an embodiment of the present invention can directly supply raw water at room temperature to the sterilizer 340, and can generate nozzle cleaning water with improved sterilization performance by the sterilizer 340. . Thereby, nozzle cleaning performance, ie, sterilization performance can be improved.

  FIG. 3 is a block diagram illustrating a bidet channel system according to another embodiment of the present invention. Referring to FIG. 3, the bidet flow path system 400 includes a flow path switching valve 100, a sterilizer 440, a heating member 460, and a nozzle unit 480.

  The raw water supplied from the raw water supply unit 410 flows into the flow path switching valve 100 through the raw water inflow path 415 and the raw water inlet 111a. As a result, normal temperature raw water from the raw water supply unit 410 flows into the flow path switching valve 100.

  In addition, the flow path switching valve 100 switches the flow path so that the water that has flowed in flows into at least one flow path among a plurality of flow paths disposed on the discharge side of the flow path switching valve 100. That is, the flow path switching valve 100 includes a plurality of inlets 111a and 121a and a plurality of outlets 122a, 123a, 125a, and 126a, and the raw water introduced from the inlets 111a and 121a is supplied to the plurality of outlets 122a. , 123a, 125a, 126a are discharged to at least one discharge port.

  In addition, the sterilizer 440 is connected to the nozzle cleaning water discharge port 122a of the flow path switching valve 100 through the nozzle cleaning water supply flow path 425, whereby the normal temperature raw water is supplied to the sterilizing apparatus 440 from the flow path switching valve 100. The The sterilizer 440 generates nozzle cleaning water containing antibacterial and / or sterilizing substances so that water supplied to the nozzle cleaning water discharge unit 481 has a sterilizing action, and at least one nozzle provided in the nozzle unit 480. Is cleaned through the nozzle cleaning water. As such a sterilization apparatus 440, an apparatus that generates a bactericidal substance through electrolysis can be used.

  The heating member 460 is connected to the heating raw water discharge port 123a of the flow switching valve 100 through the heating raw water supply channel 430, and the discharge side of the heating member 460 is switched through the hot water supply channel 450. It is connected to the warm water inlet 121a of the valve 100. As a result, normal temperature raw water discharged from the heating raw water discharge port 123a of the flow path switching valve 100 is supplied to the heating member 460 and heated, and the hot water heated by the heating member 460 also flows through the hot water inlet 121a. Supplied to the path switching valve 100. The heating member 460 may include a hot water tank that heats and stores the water that has flowed into the interior, but is not limited thereto, and is instantaneous heating that is instantaneously heated while the water that has flowed in flows. It can also consist of a device. Accordingly, when the user uses the cleaning function or the bidet function, the hot water heated by the heating member 460 is re-introduced into the flow path switching valve 100 and injected through the nozzle unit 480.

  In addition, the nozzle unit 480 can include a cleaning nozzle 482 for cleaning the anus, a bidet nozzle 483 for cleaning the local area of the woman, and the like, and nozzle cleaning water for cleaning the cleaning nozzle 482 and / or the bidet nozzle 483. A discharge part 481 is provided.

  Thus, when the nozzle part 480 consists of a plurality of nozzles, the hot water heated by the heating member 460 and reflowed into the flow path switching valve 100 is supplied to only one of the nozzles provided in the nozzle part 480. It is necessary to let

  For this purpose, the flow path switching valve 100 supplies the warm water heated by the heating member 460 and re-inflowed to the cleaning nozzle 482 or the bidet nozzle 483 through one of the cleaning nozzle path 465 and the bidet nozzle path 470. The flow path is switched to supply hot water selectively.

  As described above, the flow path switching valve 100 provided in the bidet flow path system 400 illustrated in FIG. 3 is disposed at the front ends of the sterilization apparatus 440 and the heating member 460, and the normal temperature raw water that flows in is supplied to the sterilization apparatus 440. Only one of the heating members 460 is selectively supplied.

  That is, the flow path switching valve 100 switches the flow path so that raw water flows only to the heating member 460 when hot water is used in the nozzle portion 480, and the hot water heated by the heating member 460 In this case, it is branched again and supplied to the cleaning nozzle 482 or the bidet nozzle 483 through one of the cleaning nozzle channel 465 and the bidet nozzle channel 470 and sprayed. Further, when the cleaning nozzle 482 or the bidet nozzle 483 needs to be sterilized and cleaned, the channel switching valve 100 switches the channel so that the raw water at room temperature flows only to the sterilizer 440, and the nozzle cleaning water generated by the sterilizer 440 is The nozzle cleaning water is supplied to the nozzle cleaning water discharge unit 481 through the nozzle cleaning water supply channel 445 to clean the nozzle.

  The operation of the bidet flow path system 400 shown in FIG. 3 will be described.

  When water is necessary to perform the nozzle cleaning function or the bidet / cleaning function, the raw water supply unit 410 is opened, and the normal temperature raw water supplied from the raw water supply unit 410 passes through the raw water inlet 111a to the flow path switching valve 100. Is flowed into.

  At this time, when the nozzle cleaning function is performed, the flow path switching valve 100 blocks the heating raw water supply flow path 430, the hot water inflow flow path 450, the cleaning nozzle flow path 465, and the bidet nozzle flow path 470, and the nozzle cleaning water supply flow Only the road 425 is opened. As a result, the raw water at room temperature discharged from the nozzle cleaning water supply port 122a of the flow path switching valve 100 flows into the sterilizer 440, and the nozzle cleaning water in which antibacterial and / or sterilizing substances are generated by the sterilizer 440 is The water is discharged through the nozzle cleaning water discharge unit 481, and the cleaning nozzle 482 and / or the bidet nozzle 483 are sterilized and cleaned.

  When the cleaning function or the bidet function is performed by the cleaning nozzle 482 or the bidet nozzle 483, the flow path switching valve 100 blocks the nozzle cleaning water supply path 425, the heating raw water supply path 430, and the hot water inflow path 450. The cleaning nozzle channel 465 and the bidet nozzle channel 470 are opened.

  As a result, normal temperature raw water discharged through the heating raw water discharge port 123a of the flow path switching valve 100 flows into the heating member 460 and is heated, and the heated hot water flows through the hot water inlet 121a. Is again flowed into. The hot water that has flowed into the flow path switching valve 100 is sprayed to the cleaning nozzle 482 or the bidet nozzle 483 of the nozzle unit 480. At this time, the flow path switching valve 100 allows the hot water flowing through the hot water inlet 121a to flow in both directions so that the hot water is jetted to only one of the cleaning nozzle 482 and the bidet nozzle 483. A path is formed.

  An embodiment of the flow path switching valve 100 used in such a bidet flow path system 400 will be described with reference to FIGS.

  4 is an exploded perspective view showing an embodiment of the flow path switching valve shown in FIG. 3, and FIG. 5 is a plan view of a second housing of the flow path switching valve shown in FIG. FIG. 6 shows a fixed disk of the flow path switching valve shown in FIG. 4, where (a) is a plan view, (b) is a bottom view, and (c) is taken along line AA in (a). It is sectional drawing. FIG. 7 shows a rotating disk of the flow path switching valve shown in FIG. 4, where (a) is a plan view, (b) is a bottom view, and (c) is BB in (a). FIG. 8 is a cross-sectional view taken along a line, and FIG. 8 is a schematic view of a state in which a fixed disk is mounted on the second housing of the flow path switching valve shown in FIG. 4, and FIGS. It is a general | schematic path diagram which illustrated in figure the state rotated by mounting | wearing a rotating disk on a fixed disk.

  Referring to FIG. 4, a flow path switching valve 100 used in a bidet flow path system 400 includes a valve housing 130 formed by integrating a first housing 110 and a second housing 120 with each other, and is fixed to the valve housing 130. A fixed disk 210 provided in contact with the upper surface of the fixed disk 210, and a rotating disk 220 provided so as to be rotated by a rotation driving means such as a motor 150. , 121a and a plurality of outlets 122a, 123a, 125a, 126a.

  Referring to FIGS. 4 and 5, the valve housing 130 includes a raw water inflow part 111 communicating with the raw water supply part 410, and water that has flowed into the raw water inflow part 111 to the nozzle cleaning water discharge part 481 or the heating member 460. The nozzle cleaning water supply unit 122 and the heating raw water supply unit 123 that are selectively communicated with the raw water inflow unit 111 to selectively supply, the hot water inflow unit 121 into which the water that has passed through the heating member 460 flows, The washing water supply unit 125 and the bidet water supply unit 126 which are selectively communicated with the warm water inflow unit 121 are selectively partitioned so as to selectively supply water flowing in from the warm water inflow unit 121 to the washing nozzle 482 or the bidet nozzle 483. To be formed.

  At this time, the valve housing 130 is located at the upper part of the rotating disk 220 and the first housing 110 is formed with the raw water inflow part 111, and the warm water inflow part 121 and the nozzle cleaning water supply part are located at the lower part of the fixed disk 210. 122, the heating raw water supply unit 123, the cleaning water supply unit 125, and the bidet water supply unit 126 are separately formed in the second housing 120, which is partitioned and then fastened with screws or the like in the fastening holes 118 and 128. You may couple | bond by a means (not shown). Further, a sealing means 140 such as an O-ring may be provided in the mounting groove 129 provided in the second housing 120 to seal between the first housing 110 and the second housing 120.

  In addition, the second housing 120 has a warm water inflow portion 121 formed in the center and a nozzle cleaning water supply portion 122 formed on the upper side, as viewed from above, and cleaning water on the left and right sides of the nozzle cleaning water supply portion 122. The supply unit 125 and the bidet water supply unit 126 may be formed, and the heating raw water supply unit 123 may be formed on the side opposite to the nozzle cleaning water supply unit 122.

  Referring to FIGS. 4 and 6, the fixed disk 210 is fixed to the upper portion of the second housing 120, and includes the hot water inflow part 121, the nozzle cleaning water supply part 122, the heating raw water supply part 123, and the cleaning water supply. A plurality of communication holes 211, 212, 213 ′, 213 a, 214 ′, 214 a, 215 a, 216 a formed so as to communicate with the portion 125 and the bidet water supply unit 126, respectively.

  Referring to FIGS. 4, 7, and 8, the rotating disk 220 is rotatably provided on the fixed disk 210. By rotating, the raw water inflow part 111 and the nozzle cleaning water supply part 122 and the heating raw water supply are supplied. The hot water inflow part 121 is selectively connected to any one of the washing water supply part 125 and the bidet water supply part 126. At this time, the rotating disk 220 rotates to cause some of the plurality of communication holes 211, 212, 213 ′, 213a, 214 ′, 214a, 215a, and 216a to communicate with each other, At least one of 212, 213 ′, 213 a, 214 ′, 214 a, 215 a, and 216 a can be communicated with the raw water inflow portion 111 formed at the top of the rotating disk 220.

  For this purpose, the rotating disk 220 includes any one of communication holes 212, 213 ′, 213a, 214 ′, and 214a in which the raw water inflow portion 111 communicates with the heating raw water supply portion 123 and the nozzle cleaning water supply portion 122, respectively. Selection holes 221, 222, and 223 formed so as to be selectively connected, and communication holes 211 that communicate with the hot water inflow portion 121 communicate with the cleaning water supply portion 125 and the bidet water supply portion 126, respectively. A guide groove 226 formed on the lower surface may be provided to be selectively connected to any one of the holes 125a and 126a.

  The guide groove 226 includes a central groove 224 positioned above the communication hole 211 that communicates with the hot water inflow portion 121, and each of the central groove 224 that communicates with the cleaning water supply portion 125 and the bidet water supply portion 126. An extension groove 225 extending to the upper part of the communication holes 125a and 126a can be provided.

  As described above, the nozzle cleaning water supply unit 122 is fixed to the selection holes 221 and 222 of the rotary disk 220 by the configuration of the fixed disk 210 fixed to the second housing 120 and the rotary disk 220 rotating on the fixed disk 210. It communicates with the raw water inflow portion 111 through the selective connection of the communication hole 212 of the disk 210, receives water supplied from the raw water inflow portion 111, and discharges it to the outside through the nozzle cleaning water discharge port 122a.

  Further, the heating raw water supply unit 123 communicates with the raw water inflow unit 111 through a selective connection of the selection hole 223 of the rotating disk 220 and the communication holes 213 ′, 213a, 214 ′, and 214a of the fixed disk 210, and the raw water inflow The water supplied from the section 111 is supplied and discharged to the outside through the discharge port 123a for the raw water for heating.

  Further, the washing water supply unit 125 and the bidet water supply unit 126 communicate with the hot water inflow unit 121 through the selective connection of the selection holes 221 and 222 of the rotating disk 220 and the communication holes 215a and 216a of the fixed disk 210, and flow in the hot water. The water supplied from the part 121 is supplied and discharged to the outside through the washing water supply part 125a and the bidet water supply part 126a.

  That is, the hot water that has flowed into the hot water inflow portion 121 is supplied to the cleaning nozzle 482 through the cleaning water supply port 125a and the cleaning nozzle channel 465 and jetted, or is supplied to the bidet nozzle 483 through the bidet water supply port 126a and the bidet nozzle channel 470. Supplied and injected.

  As described above, when the bidet flow path switching valve 100 shown in FIGS. 4 to 8 is used, there is an advantage that a complicated flow path can be simplified and the number of necessary valves can be reduced.

  The operation of the flow path switching valve 100 will be described with reference to FIGS. 3 and 9 to 12.

  FIG. 9 illustrates the position of the rotating disk 220 in the initial state of the flow path switching valve 100. As shown in FIG. 9, in the initial state, the selection holes 221, 222, 223 or the guide grooves 226 formed in the rotating disk 220 have communication holes 211, 212, 213 ′, 213 a, formed in the fixed disk 210. Since it does not communicate with 214 ', 214a, 215a, 216a, the flow path is blocked and water does not flow.

  In this state, when the user selects the use of the bidet, for example, the cleaning function, the rotating disk 220 is rotated counterclockwise as shown in FIG. 10 by driving the motor 150 to perform the nozzle cleaning function. That is, the selection hole 222 of the rotary disk 220 and the communication hole 212 of the fixed disk 210 are aligned, and the raw water flows into the nozzle cleaning water supply part 122 from the raw water inflow part 111 formed in the first housing 110 above the rotary disk 220. The raw water that has flowed into the nozzle cleaning water supply unit 122 passes through the nozzle cleaning water supply port 122a and the sterilization device 440 and is supplied to the nozzle cleaning water discharge unit 481 to sterilize and clean the cleaning nozzle 482 and / or the bidet nozzle 483. Cleaning is performed. On the other hand, in FIG. 10, the remaining selection holes 221 and 223 and the guide groove 226 of the rotating disk 220 are closed by the upper surface of the fixed disk 210, so that no flow path is formed in addition to the nozzle cleaning water supply.

  Thereafter, in order to supply water to the cleaning nozzle 482, the rotating disk 220 is further rotated counterclockwise as shown in FIG. Accordingly, the selection hole 223 of the rotating disk 220 communicates with the communication hole 214 ′ of the stationary disk 210 and the communication hole 214 a connected to the groove 214, and the guide groove 226 of the rotating disk 220 communicates with the hot water inflow portion 121. The communication hole 211 is connected to the communication hole 215 a connected to the groove 215.

  At this time, the raw water introduced from the raw water inflow part 111 through the selection hole 223, the communication hole 214 ′ and / or the communication hole 214a communicates, moves to the heating raw water supply part 123 and passes through the heating raw water supply port 123a. After flowing into the heating member 460 and being heated, the heated warm water flows again into the warm water inflow portion 121 through the warm water inlet 121a. Thereafter, the hot water that has passed through the communication hole 211 of the fixed disk 210, the central groove 224 of the guide groove 226 formed on the lower surface of the rotating disk 220, and the extension groove 225 in this order is connected to the groove 215 of the fixed disk 210. Is supplied to the cleaning water supply unit 125 through the cleaning water supply port 125a, and is supplied to the cleaning nozzle 482 for injection.

  At this time, immediately after the raw water flowing in from the raw water inflow section 111 moves to the heating raw water supply section 123 and is discharged from the heating member 440 side, the hot water heated by the heating member 440 flows into the hot water inflow section 121, The water is supplied to the cleaning nozzle 481 through the cleaning water supply unit 125.

  On the other hand, the groove 214 connected to the communication hole 214a may be formed so that the width of the groove 214 gradually increases toward the other side so that the injection of the cleaning water gradually increases as the rotating disk 210 rotates.

  As shown in FIG. 12, when the rotating disk 220 further rotates and reaches the position where the width of the groove 214 is the widest, the cleaning water injection amount becomes maximum, and the rotating amount (rotating angle) of the rotating disk 220 is reduced. The amount or strength of the cleaning water sprayed can be adjusted.

  After the cleaning function is finished, the rotary disk 220 rotates clockwise, passes through the position of the nozzle cleaning function shown in FIG. 10, and returns to the initial state shown in FIG.

  On the other hand, in order to perform the bidet function, the rotating disk 220 may be rotated clockwise at the initial position of the rotating disk 220 in FIG. The specific process is similar to the cleaning function except that when the rotating disk 220 rotates clockwise, the selection hole 221 of the rotating disk 220 and the communication hole 212 of the fixed disk 210 are aligned to perform the nozzle cleaning function. Therefore, detailed description is omitted.

  The flow path switching valve 100 illustrated in FIGS. 4 to 12 corresponds to an embodiment of the flow path switching valve applicable to the bidet flow path system 400 illustrated in FIG. 3, and the flow path illustrated in FIG. If the channel system can be implemented, the internal configuration of the channel switching valve 100 is not particularly limited.

  As described above, according to the bidet flow path system 400 according to the embodiment of the present invention, the flow path switching valve 100 is disposed at the front ends of the sterilizer 440 and the heating member 460, and normal temperature raw water flows into the sterilizer 440. Therefore, loss of energy generated by unnecessary heating can be prevented, and the hot water storage capacity in the heating member 460 can be reduced.

  In addition, the bidet flow path system 400 according to an embodiment of the present invention can directly supply raw water at room temperature to the sterilizer 440, and the sterilizer 440 can generate nozzle cleaning water with improved sterilization performance. . Thereby, nozzle cleaning performance, ie, sterilization performance can be improved.

  Also, in the bidet flow path system 400 according to an embodiment of the present invention, since the flow path switching valve 100 includes a plurality of inlets and a plurality of outlets, the number of components for realizing a complicated flow path is small. There is an advantage of reducing.

  While the foregoing has illustrated and described specific embodiments of the present invention, those having ordinary skill in the art should not depart from the spirit and scope of the present invention as set forth in the appended claims. It is apparent that various modifications and changes can be made to the present invention.

300, 400 Bidet flow path system 320, 100 Flow path switching valve 340, 440 Sterilizer 360, 460 Heating member 380, 480 Nozzle

Claims (8)

A flow path switching valve for switching the flow path so that the raw water flowing in from the raw water supply section flows into at least one flow path among the plurality of flow paths,
A sterilizer that is connected to the discharge side of the flow path switching valve and generates nozzle cleaning water containing a sterilizing substance from the supplied raw water;
A heating member that is connected to the discharge side of the flow path switching valve and heats the supplied raw water;
A nozzle unit that is connected to the sterilizer and the heating member, and is provided with at least one nozzle to which nozzle cleaning water or hot water is supplied;
Including bidet channel system.   It further includes a branch valve that is disposed between the heating member and the nozzle part, and that allows hot water discharged from the heating member to flow only to any one of the nozzles provided in the nozzle part. The bidet flow path system according to claim 1. A sterilizer for generating nozzle cleaning water containing a sterilizing substance;
A heating member for heating the supplied raw water;
A nozzle unit provided with at least one nozzle to which nozzle washing water generated by the sterilizer or hot water heated by the heating member is supplied;
Connected to the inflow side of the sterilization device and the heating member, and selectively supplies the raw water flowing in from the raw water supply unit to the sterilization device or the heating member, connected to the discharge side of the heating member, and the heating member A flow path switching valve for switching the flow path so as to supply the hot water heated by the nozzle section,
Including bidet channel system.   4. The flow path switching valve cuts off a flow path connected to the heating member when raw water flowing in from the raw water supply unit is discharged to the sterilizer. A bidet channel system according to claim 1.   The flow path switching valve shuts off the flow path connected to the sterilizer when the hot water flows through the nozzle portion, and the flow path connected to the inflow side and the discharge side of the heating member and the nozzle The bidet channel system according to claim 3, wherein the channel connected to the unit is opened in conjunction with each other. The nozzle part includes a plurality of nozzles,
6. The bidet flow path according to claim 5, wherein the flow path switching valve switches the flow path so that hot water flowing from the heating member is selectively discharged to one of the plurality of nozzles. system.   4. The bidet channel system according to claim 1, wherein the sterilizing material includes an oxidative mixed material generated by electrolysis.   4. The bidet channel system according to claim 1, wherein the sterilizing material contains iodine or silver oxide.

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