JP4637201B2 - Microbubble generator - Google Patents

Description

  The present invention relates to a fine bubble generator.

  FIG. 1 is a structural diagram of a bubble generator using a conventional non-self-priming motor pump.

  In the conventional fine bubble generator disclosed in Patent Document 1, the water nozzle 101 and the water discharge nozzle 118 are immersed in the bath water, and then the motor pump 100 is operated to circulate the cleaning water, and the air inlet 109 on the pump inlet side. The air is introduced into the motor pump 100 through the water tank 126 in which the air vent 125 is installed, and a high pressure is formed through a pressure plate installed in the water discharge nozzle 118. The micro-bubbles are generated by strongly colliding with the mesh body.

  As shown in FIG. 1, the conventional fine bubble generator includes a water inlet nozzle 101 in the water inlet hose 102 of the motor pump 100, and a foreign substance removal net that removes foreign matters during suction inside the water inlet nozzle 101. Then, a water tank 126 having an air vent 125 attached to the rear end of the outlet channel 115 through the pump outlet was constructed and used.

  In the case of using a fine bubble generator configured as in the prior art, when the water level of the bathtub is at a lower position than the motor pump 100, the water is filled in the water inlet hose 102 and the water inlet nozzle 101 to pump wash water in the bathtub. Since it cannot be sucked by the head 113, the washing water must be artificially injected into the pump head 113 through the water-injecting nozzle 101.

  Also, since there is no separate shut-off device at the air suction port 109 and air is manually introduced into the air suction port 109, air will continuously flow into the air suction port 109, so it takes a long time to form the water pressure of the motor pump. Met.

  As described above, even when the water pressure of the motor pump 100 is formed and the cleaning water is circulated and used, the cleaning water is formed into fine bubbles through the water tank 126 and the water discharge nozzle 118 in which another air vent 125 is mounted, and the bathtub. Must be discharged. At this time, in the water tank 126, an air vent 125 is mounted on the upper portion of the water tank 126 in order to discharge air that is not mixed with cleaning water into the atmosphere.

  This occupies a lot of the internal space of the fine bubble generator and has limited space utilization.

  In addition, while using the fine bubble generator, the mesh body provided in the water discharge nozzle 118 is blocked by foreign matter, dust, skin keratin, etc. inside the bathtub, overloading the motor pump 100 and increasing the pressure on the water discharge port 115. As a result, a dangerous situation may occur in which the water tank 126 is damaged or the water discharge hose 117 is torn and the washing water is leaked into the fine bubble generating device and the wires are connected.

Furthermore, during use of the micro-bubble generating device, when replacing blocked mesh body, Nozzle body, the nozzle cover, the mesh body, the pressure plate is configured separately from the replacement of the mesh body is difficult.

Korean Patent Publication No. 2003-0010685

  Accordingly, the present invention has been made to solve the problems of the prior art as described above, and its purpose is to configure a multi-function water tank 120 that helps self-priming while using a non-self-priming motor pump. The flow sensor 106 and the pressure sensor 116 that can sense the pressure in the flow path are used while the microbubble generator is used, and the nozzle base 141, the nozzle cover 142, and the mesh body 153 are integrated. By configuring and providing the water discharge nozzle 118, the design is reduced in size and weight is reduced, and when the mesh body 153 is blocked, the operation is stopped to ensure safety, and the mesh is provided to the user. The time for replacement of the body 153 is notified so that the mesh body 153 can be easily replaced so that a healthy and comfortable bath and foot washing can be enjoyed.

  Another object of the present invention is to enable quiet and safe use of a fine bubble generator even in an industrial fine bubble generator.

In order to solve the above problems, the present invention is a microbubble generator, wherein a multifunctional water tank 120 is formed so as to communicate with a pump outlet 112 connected to a motor pump 100, and the multifunctional water tank 120 is formed. multifunctional water tank bottom hole 124 pressure valve 130 is formed in communication with the pressure bulb 130 forms communicates with the pump priming holes 114 of the motor pump 100 through the multi-function water tank upper hole 123 communicates with the air vent 125 structure of The multifunctional water tank 120 forms a multifunctional water tank inlet 121 on one surface communicating with the pump outlet 112 of the motor pump 100, and a multifunctional water tank outlet 122 on the opposite surface of the multifunctional water tank inlet 121. A multi-function water tank upper hole 123 communicating with the air vent 125 is formed in the upper part, and a pressure valve is formed in the lower part. A multi-function water tank lower hole 124 communicating with 130 is formed, and the multi-function water tank is constant with respect to the center line so that the multi-function water tank inlet side is inclined with respect to the multi-function water tank outlet side. Provided is a fine bubble generating device formed at an angle .

  The fine bubble generating device may further include an air inlet 109 configured by installing a solenoid valve 110 between the pump head 113 and the pump inlet 111 of the motor pump 100.

  In the fine bubble generating apparatus, a water inlet 103 that is connected to the motor pump 100 and sucks water is formed by a main water inlet 104 and an auxiliary water inlet 105, and a flow rate sensor 106 is installed in the auxiliary water inlet 105. It may be.

  The fine bubble generator may further include a pressure sensor 116 in the water discharge path 115 of the motor pump 100.

The present invention also includes a water discharge nozzle 118 that communicates with the multifunctional water tank . The nozzle cover 142 has a nozzle cover central hole (upper) 143 formed therein, and is integrated with the nozzle cover central hole (upper) 143 to form a nozzle. A cover center hole (lower) 144 is formed, a hook home 145 is provided above the nozzle cover center hole (lower) 144, a hook 157 is provided on the mesh support base (lower) 151, and the nozzle cover center hole is provided. A fine bubble generating apparatus in which (upper) 143, the nozzle cover central hole (lower) 144 and the mesh body 153 are integrated is provided.

  In addition, by using the multi-function water tank 120 to configure the fine bubble generator without the need for a separate water tank 126, the space utilization of the product can be improved and the cost can be reduced. By providing the mesh body 153 integrated with 142, the mesh body 153 can be conveniently replaced.

  In addition, when the pressure sensor 116 is mounted between the water discharge passage 115 and the water discharge nozzle 118 of the motor pump 100, when the mesh body 153 is blocked or excessive pressure is generated due to an abnormality of the motor pump 100, the motor pump is stopped. Thus, a fine bubble generator that can be used safely can be provided.

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

  2 and 3 are configuration diagrams of a microbubble generator according to the present invention.

  In the present invention, as shown in the configuration diagrams of FIGS. 2 and 3, the water inlet 103 of the motor pump 100 includes a water inlet nozzle 101 and a water inlet hose 102. It comprises and comprises the mesh which removes.

  A check valve 119 is formed between the water inlet 103 of the motor pump 100 and the water inlet hose 102 to prevent the wash water flowing into the water inlet 103, the main water inlet 104, and the auxiliary water inlet 105 from flowing out. Configure as follows. This is to make the motor pump 100 useful for self-priming during operation. The water inlet 103 of the motor pump 100 is divided into a main water inlet 104 and an auxiliary water inlet 105, and the auxiliary water inlet 105 is provided with a flow rate sensor 106.

  In addition, when the cleaning water is sucked into the water inlet 103, when the water inlet nozzle 101 is protruded to the outside of the bathtub due to the carelessness of the user during use, and the air flows into the water inlet nozzle 101 through the atmosphere, Are configured to be divided.

  When washing water flows into the water inlet nozzle 101, the viscosity of the washing water is higher than that of the air, so that the pulse of the flow rate sensor 106 falls significantly compared to the washing water. It is determined whether washing water or air flows into the water inlet nozzle 101. By using this, it is configured that the use of the fine bubble generating device is stopped by sensing the inflow of air into the water inlet nozzle 101.

  By configuring as described above and preventing the motor pump 100 from idling, it is possible to prevent wear of internal components of the motor pump 100.

  Further, the connection between the inlet / outlet hoses 102, 117 and the inlet / outlet channels 103, 115 is constituted by a coupling 119, and when storing the product after using the fine bubble generating device, the hose and the product base can be easily connected. Use them separately.

The washing water sucked as described above flows into the pump head 113 through the pump inlet 111. An invitation water hole 114 communicating with the pressure valve 130 is formed between the pump inlet 111 and the pump head 113, the air inlet 109 is configured to communicate with the solenoid valve 110, and the temperature sensor hole 107 includes a temperature sensor. 108 is attached and configured.

The pump outlet 112 side is configured to communicate with the multifunctional water tank 120, and the multifunctional water tank 120 is configured to communicate with the multifunctional water tank inlet 121 that communicates with the pump outlet 112, and with multifunctional water that communicates with the air vent 125 at the top. A tank upper hole 123, a multifunctional water tank lower hole 124 communicated with the pressure valve 130 at the lower part, and a multifunctional water tank outlet 122 communicated with the water discharge path 115 are provided.

  The drainage channel 115 is configured to communicate with the multifunctional water tank outlet 122, and a “T” -shaped pipe is used between the drainage channel 115 and the drainage nozzle 117 to configure a pressure sensor 116, and one surface is a drainage hose 117. It is made to communicate with.

  When the mesh body 153 of the water discharge nozzle 118 is blocked when taking a bath, the pressure sensor 116 detects the pressure on the flow path and notifies the user of this, and also replaces the mesh body 153. To inform.

  The water discharge nozzle 118 is configured to communicate with the water discharge hose 117.

  When driving the fine bubble generating apparatus configured as described above, when the motor pump 100 is operated, the wash water in the bathtub starts to be sucked through the water inlet nozzle 101, and the sucked wash water passes through the water inlet hose 102 and the water inlet passage 103. The water flows into the pump head 113 through the main water inlet 104, the auxiliary water inlet 105, and the pump inlet 111. At this time, the auxiliary water intake path 105 is configured to be equipped with a flow rate sensor 106 so as to detect whether the wash water is normally sucked or air is introduced. The reason why the flow rate sensor 106 is configured on the inlet channel 103 side is that the pressure of the inlet channel 103 is lower than the pressure of the outlet channel 115, so that the damage and error rate of the flow rate sensor 106 can be minimized.

  As described above, at the moment when the number of washings flows into the pump head, air is made to flow through the air suction port 109, and the inflow of air is configured to control the opening and closing of the air suction port 109 using the solenoid valve 110. .

  If air flows into the pump head 113 during the initial drive of the motor pump, the motor pump 100 cannot create pressure, so the solenoid valve 110 is closed for several seconds during the initial drive to maintain the vacuum state, and pressure is formed. Thereafter, the solenoid valve 110 is opened so that air is introduced and fine bubbles are generated.

  The temperature sensor hole 107 is configured by attaching a temperature sensor 108, and senses the temperature of the cleaning water in use to display the temperature to the user.

  The washing water and air that have flowed into the pump head 113 flow into the multi-function water tank inlet 121 through the pump outlet 112 due to the motor pump pressure. As shown in FIGS. 4A to 4C, the multifunctional water tank inlet 121 is configured at the lower end portion of one surface of the multifunctional water tank 120, and the multifunctional water tank outlet 122 is configured at the upper end portion of the other surface. Inclined at a certain angle (negative angle) with respect to. This is to secure a space where air floats and collects in the multifunctional water tank 120 as shown in FIGS. 4A to 4C when the motor pump 100 is driven.

  When the multifunctional water tank 120 is tilted, it is desirable that the multifunctional water tank inlet 121 is tilted in a state where the lateral direction of the multifunctional water tank inlet 121 is higher than the lateral direction of the multifunctional water tank outlet 122.

  In addition, when the microbubble generator is re-driven so that the flush water is always accumulated in the multi-function water tank 120 by maintaining a constant water level in the multi-function water tank 120 even when the motor pump is not driven, it is inhaled by itself. Configure to self-prime.

On the other hand, in the configuration capable of self-priming, when the motor pump 100 is driven, a certain amount of washing water of the multi-function water tank 120 flows into the pressure valve 130 through the multi-function water tank lower hole 124, and the inlet / outlet hole of the pressure valve 130 133, cleaning water flows into the pump head 113 through the sheet guide home 139, the water outlet orifice, and the pump invitation water hole 114. Since the motor pump is driven, the washing water in the bathtub on the water inlet nozzle 101 side is sucked little by little while repeating such washing water flow so that the washing water is sucked into the pump head 113.

When the cleaning water on the water inlet nozzle 101 side is sucked up to the pump head 113, a water pressure of a certain level or more is formed in the flow path after the pump outlet 112, but when the water pressure is formed, the seat 134 of the pressure valve 130 is The motor pump is prevented from being in a vacuum state by being pushed by water pressure to block the outlet orifice 136 and preventing the washing water from flowing into the water hole 114 through the pressure valve 130.

  When pressure is formed in the multi-function water tank 120, wash water and air are discharged through the multi-function water tank outlet 122, but the discharged wash water and air are discharged from the water discharge nozzle 118 through the water discharge path 115 and the water discharge hose 117. Fine water bubbles are generated while flowing into the nozzle inlet 149 and the washing water and air form a high pressure through the pressure plate 146 and pass through the mesh body 153.

  When the microbubble generator configured as described above is used repeatedly several times, the mesh body 153 must be replaced by the fine dust in the bathtub, foreign matter, skin keratin, etc., and the mesh body must be replaced.

  In order to facilitate replacement even when the mesh body 153 is replaced, a nozzle inlet 149 is formed on the upper portion of the nozzle base 141, and a spring fixing base 148 capable of supporting a spring is formed in the center of the nozzle inlet 149. A nozzle spring 147 is formed at the lower part of the nozzle. The lower part of the nozzle spring 147 is connected by forming a pressure plate 146 having a spring guide, and a plurality of mesh support bases 155 are formed at the lower part of the pressure plate 146, and the mesh support bases 155 are meshed between them. 152, and a lower mesh support 155 having a hook 157 at the lower end of the mesh body 153.

  The mesh bodies 153 are integrally formed by fusing.

  The nozzle cover center hole (lower) 144 includes a hook home 145 that can be rotated and connected to the hook 157 of the integrated mesh body 153 so that fine bubbles discharged through the mesh body 153 are distributed at an appropriate pressure. The pressure distribution holes 150 are provided on the side surface and the lower surface.

  Further, the nozzle cover center hole (lower) 144 is configured to mesh with the nozzle cover center hole (upper) 143 so as to be integrated. The nozzle cover 142 includes a nozzle cover central hole (upper) 143 and is integrated.

  In addition, the nozzle cover 142 is constituted by a female screw, and the nozzle base 141 is constituted by a male screw so that the nozzle cover 142 and the nozzle substrate 141 are screwed together.

  When the mesh body 152 is blocked by a foreign object and needs to be replaced when the mesh body 152 needs to be replaced when the structure is used as described above, the nozzle cover 142 and the nozzle are separated by rotating the nozzle cover 142 from the nozzle base 141. Since the cover center holes (upper and lower) 143 and 144 and the mesh body 153 are integrated, they are attached to the nozzle cover 142 and separated from the nozzle base 141.

  After separating the nozzle base 141 and the nozzle cover 142 in this way, the mesh body 153 fixed to the hook home 145 in the nozzle cover center hole (lower) is rotated and separated, and then replaced.

It is a flow-path block diagram of the conventional fine bubble generator. It is a flow-path block diagram of the microbubble generator by this invention. It is a flow-path block diagram of the microbubble generator by this invention. 1 is a structural diagram of a multifunctional water tank according to the present invention. 1 is a structural diagram of a multifunctional water tank according to the present invention. 1 is a structural diagram of a multifunctional water tank according to the present invention. 1 is a structural diagram of a pressure valve according to the present invention. 1 is a structural diagram of a water discharge nozzle according to the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Board | substrate 100 Motor pump 101 Inlet nozzle 102 Inlet hose 103 Inlet channel 104 Main inlet channel 105 Auxiliary inlet channel 106 Flow rate sensor 107 Temperature sensor hole 108 Temperature sensor 109 Air inlet 110 Solenoid valve 111 Pump inlet 112 Pump outlet 113 Pump head 114 Inlet water hole 115 Water outlet 116 Pressure sensor 117 Water outlet hose 118 Water outlet nozzle 119 Check valve 119-1 Coupling 120 Multifunctional water tank 121 Multifunctional water tank inlet 122 Multifunctional water tank outlet 123 Multifunctional water tank upper hall 124 Multifunctional water Tank lower hole 125 Air vent 126 Water tank 130 Pressure valve 131 Pressure valve inlet 132 Inlet orifice 133 Inlet outlet hole 134 Seat 135 Seat guide 136 Outlet Refis 137 Spring 138 Pressure valve outlet 139 Seat guide home 141 Nozzle base 142 Nozzle cover 143 Nozzle cover center hole (upper)
144 Nozzle cover center hole (bottom)
145 Hook home 146 Pressure plate 147 Nozzle spring 148 Nozzle souplin fixing base 149 Nozzle inlet 150 Pressure distribution hole 151 Mesh support base (bottom)
152 Mesh 153 Mesh body 155 Mesh support base 157 Hook

Claims (4)

A microbubble generator,
A multi-function water tank is formed to communicate with the pump outlet connected to the motor pump,
Forming a multi-function water tank lower hole of the multi-function water tank so as to communicate with a pressure valve;
The pressure valve is formed so as to communicate with the motor pump invitation water hole,
The multifunction water tank upper hole is configured to communicate with an air vent,
The multifunctional water tank is
A multifunctional water tank inlet is formed on one side that communicates with the pump outlet of the motor pump,
Forming a multifunctional water tank outlet on the opposite surface of the multifunctional water tank inlet;
A multi-function water tank upper hole communicating with the air vent is constructed at the top,
The lower part of the multifunctional water tank that communicates with the pressure valve
The multi-function water tank is formed to be inclined at a constant angle with respect to the center line so that the multi-function water tank inlet side is inclined in a state of being raised from the multi-function water tank outlet side.
Fine bubble generator.   The fine bubble generating apparatus according to claim 1, further comprising an air suction port configured by installing a solenoid valve between a pump head of the motor pump and a pump inlet.   3. A water intake channel connected to the motor pump for sucking water is formed by a main water intake channel and an auxiliary water intake channel, and a flow rate sensor is installed in the auxiliary water intake channel. The microbubble generator described.   The fine bubble generating device according to claim 1, further comprising a pressure sensor in a water discharge channel of the motor pump.

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