JP7453646B2 - deodorizing device - Google Patents

Description

The present invention relates to a deodorizing device that can deodorize a room.

For example, Patent Document 1 describes an ozone spray that generates ozone by electrolyzing water stored in a container and sprays ozonated water containing the generated ozone in the water.

Patent No. 6249200

The ozone spray mentioned above sprays ozonated water onto objects such as toilet bowls and kitchen sinks to disinfect and sterilize them. Release amount is required. Therefore, ozone water cannot be made into a mist with very small particle diameters, and it is difficult to diffuse it widely indoors, so it is difficult to deodorize a room using the above-mentioned ozone spray.

Therefore, it may be possible to deodorize the room by releasing ozone-containing air into the room instead of using ozone water as described above. Unlike ozonated water, air containing ozone easily spreads throughout the room.

However, the concentration of ozone in the air released into a room where people may be present is limited to a very low concentration, for example, 0.1 ppm or less. For this reason, it is difficult to sufficiently deodorize a room using only ozone.

The present invention has been made in view of such problems, and an object of the present invention is to provide a deodorizing device that can effectively deodorize a room using ozone.

A main aspect of the present invention relates to a deodorizing device that can deodorize a room. The deodorizing device according to this aspect includes a first releasing portion that releases ozone to the outside of the deodorizing device , a second releasing portion that releases a mist made of water to the outside of the deodorizing device, and a second releasing portion that releases ozone from the first releasing portion to the outside of the deodorizing device. The control unit includes a control unit that discharges ozone, discharges the mist from the second discharge unit at the same time as the ozone discharge , and executes a deodorizing process of mixing ozone and the mist in an indoor space . The second discharge part is located above the first discharge part and discharges the mist in a horizontal direction, and the first discharge part is configured to discharge the mist by the second discharge part when the deodorizing device is viewed from above. The ozone is emitted diagonally upward in the same direction as the ozone emitted.

According to the above configuration, it is possible to generate OH radicals by mixing the ozone emitted from the first emitting part with the mist emitted from the second emitting part in the indoor space. Thereby, the interior of the room can be deodorized not only by the ozone from the first emission part but also by the OH radicals, and the interior of the interior can be effectively deodorized.
Furthermore, the ozone emitted from the first emitting part is more likely to intersect with the mist emitted from the second emitting part located above the first emitting part, making it easier for ozone and mist to mix, and OH radicals to be generated. more likely to be generated. Therefore, the indoor deodorizing effect is enhanced.

In the deodorizing device according to this aspect, the first discharge section includes a housing having a discharge port, an ozone generation section that generates ozone from air, and a case in which the ozone generated by the ozone generation section is transmitted through the discharge port. The configuration may include a blower unit that sends air to the outside.

According to the above configuration, ozone can be emitted from the first emitting section by operating the ozone generating section and the blowing section.

In the case of the above configuration, the discharge port may further be provided on a side surface of the housing. In this case, the first discharge section may be configured to discharge ozone generated by the ozone generation section obliquely upward from the discharge port.

With such a configuration, the ozone emitted from the first emitting part can easily reach the upper part of the room.

In the deodorizing device according to this aspect, the second discharge section may be configured to include a container in which water is stored, and a mist generation section that generates the mist from the water in the container.

According to the above configuration, mist can be emitted from the second emitting section by operating the mist generating section.

In the case of the above configuration, the second discharge section may further include an electrolysis section that generates ozone from the water in the container by electrolysis. In this case, the mist generation section generates the mist from water containing ozone generated by the electrolysis section.

With such a configuration, the mist containing ozone can be emitted from the second emitting section, so that the effect of ozone contained in the mist further enhances the deodorizing effect in the room.

In the deodorizing device according to this aspect, the second emitting section includes a charging ground that is a source of power required to emit the mist, and is configured to be removably installed in the first emitting section. The first discharge section may be configured to include a power supply section that supplies power for charging the rechargeable battery while the second discharge section is installed. In this case, the control unit may execute the deodorizing process based on the fact that the second discharge unit is installed in the first discharge unit.

According to the above configuration, it is possible to use the second emitting part in a state separated from the first emitting part. Moreover, since the second discharge part is located away from the first discharge part, ozone and mist can be prevented from being discharged in a state where it is difficult for them to mix. In other words, by determining the discharge position, ozone and mist can be prevented from being discharged. Ozone and mist can be released in a state where the mist is easily mixed, and the ozone and OH radicals can fully exhibit the deodorizing effect.

According to the present invention, it is possible to provide a deodorizing device that can effectively deodorize a room using ozone.

The effects and significance of the present invention will become clearer from the description of the embodiments shown below. However, the following embodiments are merely one example of implementing the present invention, and the present invention is not limited to what is described in the following embodiments.

FIG. 1 is a perspective view of an ozone deodorizing device according to an embodiment. FIG. 2 is a longitudinal sectional view of the ozone deodorizing device according to the embodiment. FIG. 3 is a perspective view of a water supply section, a shower discharge section, and a mist discharge section according to the embodiment. FIG. 4(a) is a cross-sectional view of the shower discharge part according to the embodiment, and FIG. 4(b) is a cross-sectional view of the mist discharge part according to the embodiment. FIG. 5 is a block diagram showing the configuration of the ozone spray according to the embodiment. FIG. 6 is a block diagram showing the configuration of the charger according to the embodiment. FIG. 7 is a flowchart showing ozone spray control processing by the control unit according to the embodiment. FIG. 8 is a flowchart showing the charger control process by the control unit according to the present embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS An ozone deodorizing device, which is an embodiment of the deodorizing device of the present invention, will be described below with reference to the drawings.

FIG. 1 is a perspective view of an ozone deodorizing device 1. FIG. 2 is a longitudinal cross-sectional view of the ozone deodorizing device 1. FIG. 3 is a perspective view of the water supply section 30, the shower discharge section 40, and the mist discharge section 50. 4(a) is a cross-sectional view of the shower discharge section 40, and FIG. 4(b) is a cross-sectional view of the mist discharge section 50.

Note that, hereinafter, the shower discharge section 40 side will be described as the front side of the ozone deodorizing device 1.

The ozone deodorizing device 1 includes an ozone spray 2 and a charger 3. The ozone spray 2 corresponds to the second discharge part of the present invention, and the charger 3 corresponds to the first discharge part of the present invention.

The ozone spray 2 includes a generation section 20 , a water supply section 30 , a shower discharge section 40 , a mist discharge section 50 , and an operation section 60 in a housing 10 .

The ozone spray 2 sends the ozone water generated by the generation unit 20 to the shower discharge unit 40 through the water supply unit 30 based on the operation of the operation unit 60, and discharges the ozone water from the shower discharge unit 40 to the outside in a shower shape. do. Further, the ozone spray 2 sends the ozonated water generated by the generation unit 20 to the mist emission unit 50 through the water supply unit 30, generates a mist containing ozone from the ozonated water, and transfers the mist from the mist emission unit 50 to the outside. Release to.

Further, the ozone spray 2 includes a power supply unit 70 including a rechargeable battery 710 within the housing 10. Ozone spray 2 is removably installed in charger 3 for charging rechargeable battery 710.

The charger 3 includes a power supply unit 110 in a housing 100, and supplies power to charge the rechargeable battery 710 with the ozone spray 2 installed. Furthermore, the charger 3 includes an ozone generator 120 and a fan 130 in the housing 100, and the ozone generated from the air by the ozone generator 120 is contained in the air and sent to the outside by the operation of the fan 130. Let it be released.

The configuration of the ozone spray 2 will be described in detail with reference to FIGS. 1 to 4(b).

The housing 10 includes a body portion 10a, a neck portion 10b, and a head portion 10c. The body portion 10a is formed into a substantially bottomed cylindrical shape with a taper in the upper portion that becomes narrower toward the neck portion 10b. A vertically elongated display window 11 is formed on the front side of the body portion 10a. Further, a mode display section 12 is formed on the body section 10a. A display lamp 13 such as an LED is attached to the inside of the body 10a at the position of the mode display section 12. The display lamp 13 can be lit in a plurality of colors, and is lit in a color corresponding to an operation mode to be described later.

The neck portion 10b has a substantially cylindrical shape and extends in the vertical direction. The head 10c has a substantially rectangular cylindrical shape and extends in the front-rear direction. The head 10c is open at a front end surface corresponding to the shower discharge section 40 and at a rear end surface corresponding to the mist discharge section 50.

When the user holds the ozone spray 2 in his hand, he mainly grasps the neck 10b of the housing 10 from the rear side of the ozone spray 2.

The generation unit 20 includes a container 210 in which water is stored, an electrolytic unit 220 that generates ozone by electrolysis from the water stored in the container 210, and an electrolytic unit 220 that generates ozone by dissolving the ozone generated in the electrolytic unit 220 in the water. a pump 230 for sending ozone water generated within the shower to the shower discharge section 40 and the mist discharge section 50 through the water supply section 30;

The container 210 is transparent or has translucency, and is formed in a shape corresponding to the housing 10 . The water stored in the container 210 is, for example, pure water. The height of the top surface of the container 210 is made lower than the height of the neck portion 10b of the housing 10, and a space is formed above the neck portion 10b in which parts such as the pump 230, the switching portion 360, the operating portion 60, etc. are arranged. Ru. In this way, the ozone spray 2 can be made compact by utilizing the inside of the neck portion 10b that is held by the user and arranging parts such as the pump 230.

A protrusion 211 having a shape corresponding to the display window 11 is formed on the front side of the container 210 . The protrusion 211 is exposed to the outside through the display window 11. The user can check the amount of water in the container 210 through the display window 11. Further, the container 210 is provided with a water inlet 212 on the rear side for filling water into the container 210. The water supply port 212 slightly protrudes outward from the opening 14 provided in the housing 10 . A cap 15 that closes the water supply port 212 fits into the opening 14.

Electrolytic section 220 includes an anode, a cathode, and an ion exchange membrane, and is disposed at the bottom of container 210. The pump 230 is arranged above the container 210 inside the neck 10b of the housing 10. Pump 230 is, for example, a small diaphragm-driven pump. A water suction pipe 240 is connected to the suction port 231 of the pump 230 . A water suction port 241 at the tip of the water suction pipe 240 is located at the bottom of the container 210.

When the anode and cathode of the electrolytic section 220 are energized, water flowing into the electrolytic section 220 is electrolyzed and ozone is generated. The generated ozone is released into the water in the container 210 and dissolves in the water. This produces ozonated water. When the pump 230 operates, ozonated water in the container 210 is sucked in from the water intake port 241 of the water intake pipe 240, passes through the water intake pipe 240 and the pump 230, and is discharged from the discharge port 232 of the pump 230.

The water supply section 30 includes a water supply pipe 310, a shower pipe 320, a mist pipe 330, a shower valve 340, and a mist valve 350.

Water pipe 310 is connected to discharge port 232 of pump 230. The shower pipe 320 and the mist pipe 330 are branched from the water pipe 310 and connected to the shower discharge section 40 and the mist discharge section 50, respectively. The shower pipe 320 and the mist pipe 330 are composed of two pipes, and a shower valve 340 and a mist valve 350 are respectively arranged between the two pipes. The shower valve 340 and the mist valve 350 are electromagnetic valves, and constitute a switching section 360 that switches which of the shower pipe 320 and the mist pipe 330 the ozone water flowing out from the generation section 20 is to flow through. Similar to the pump 230, the switching unit 360 is arranged above the container 210 within the neck portion 10b of the housing 10.

When pump 230 is not operating, shower valve 340 and mist valve 350 are closed, and when pump 230 is operating, one valve is opened.

Ozonated water discharged from the pump 230 flows through the water pipe 310. If the shower valve 340 is open, the ozonated water sent to the water pipe 310 is sent to the shower discharge part 40 through the shower pipe 320, and if the mist valve 350 is opened, it is sent to the shower discharge part 40. The mist is sent to the mist emitting section 50 through the pipe 330.

The shower discharge section 40 is arranged at the front end of the head 10c of the housing 10. An annular outlet 41 with a tapered outer circumference is provided on the front surface of the shower outlet 40. The discharge port 41 is exposed to the outside from the front end surface of the head 10c. A circular discharge plate 42 is attached to the discharge port 41 . A plurality of holes 42a are formed in the discharge plate 42 in a distributed manner. A connection port 43 is provided at the rear of the shower discharge section 40, and a shower pipe 320 is connected to this connection port 43. A flow path 44 is formed inside the shower discharge section 40 from the connection port 43 toward the discharge port 41 . As shown by the dashed-dotted line arrow in FIG. 4(a), the ozonated water sent to the shower discharge part 40 by the shower pipe 320 is vigorously discharged in the form of a shower from the plurality of holes 42a of the discharge plate 42, that is, it is sprayed. Ru.

The mist emitting section 50 is arranged at the rear end of the head 10c of the housing 10. The front surface of the mist emitting section 50 is exposed to the outside from the rear end surface of the head 10c. Mist emitting section 50 includes a housing 510, an ultrasonic vibrator 520, and a water tank 530. The mist emitting section 50 corresponds to the mist generating section of the present invention.

A circular recess 511 is formed in the front surface of the housing 510, and a disc-shaped ultrasonic transducer 520 is mounted in the recess 511. The ultrasonic vibrator 520 includes a vibrating surface 521 that has a large number of micropores and vibrates ultrasonically.

Water tank 530 is disposed at an upper portion within housing 510 . The volume of water tank 530 is significantly smaller than the volume of container 210. An inflow pipe 531 is formed on the top surface of the water tank 530. The inflow pipe 531 protrudes rearward from the rear surface of the housing 510. A mist pipe 330 is connected to an inflow pipe 531. Further, an overflow port 532 is formed at the upper rear surface of the water tank 530. The overflow port 532 protrudes rearward from the rear surface of the housing 510. An overflow pipe 540 is connected to the overflow port 532. The tip of the overflow pipe 540 is placed inside the container 210.

The water tank 530 has a portion that extends obliquely downward toward the recess 511 of the housing 510, and an outlet 533 is provided at the tip of the portion. The outlet 533 is connected to the vibration surface 521 of the ultrasonic transducer 520 within the recess 511 .

The water tank 530 stores ozonated water sent to the mist discharge section 50 through the mist pipe 330. When the ultrasonic vibrator 520 operates, the vibrating surface 521 vibrates ultrasonically. As a result, as shown in FIG. 4(b), the ozonated water that has touched the vibrating surface 521 at the outlet 533 of the water storage tank 530 is atomized and becomes a mist containing ozone. The mist is emitted from a large number of micropores in the vibrating surface 521 that serve as ejection ports.

The operating section 60 is provided on the front side of the neck section 10b of the housing 10. The operation unit 60 includes an operation button 61, and when the operation button 61 is pressed, an internal contact opening/closing switch is turned on.

Power supply unit 70 includes a rechargeable battery 710 and a charging device 720. Rechargeable battery 710 is, for example, a lithium ion battery, and outputs power for driving electrical components such as electrolysis section 220, pump 230, and switching section 360. That is, the rechargeable battery 710 is a power supply source required for emitting ozone-containing mist and shower-like ozonated water from the ozone spray 2. Charging device 720 includes a power receiving coil 721 and a charging circuit board 722, and charges rechargeable battery 710. The power receiving coil 721 is formed by winding a conducting wire in a spiral shape, and is arranged close to the bottom surface of the housing 10 . The rechargeable battery 710 and the charging circuit board 722 are arranged in the housing 10 at the rear lower part of the container 210.

A proximity switch 16 is arranged at the bottom of the housing 10. The proximity switch 16 is composed of a reed switch or the like, and reacts to the magnetic force of a magnet provided on the charger 3 when the ozone spray 2 is installed on the charger 3, that is, placed on the mounting surface of the charger 3. and turn it on.

FIG. 5 is a block diagram showing the configuration of the ozone spray 2. As shown in FIG.

In addition to the above-described configuration, the ozone spray 2 includes a control section 81, a storage section 82, an operation detection section 83, a lamp drive section 84, an electrode current supply section 85, a pump drive section 86, a valve drive section 87, a vibrator drive section 88, and A communication section 89 is provided.

The operation detection section 83 outputs an operation signal to the control section 81 when the operation button 61 of the operation section 60 is pressed. When the proximity switch 16 is turned on, an on signal is output from the proximity switch 16 to the control section 81 .

The lamp drive section 84 lights up the display lamp 13 according to a control signal from the control section 81 . The electrode current supply section 85 applies a voltage for electrolysis to the electrodes of the electrolysis section 220 in accordance with a control signal from the control section 81 . Pump driving section 86 drives pump 230 according to a control signal from control section 81 .

The valve drive unit 87 drives the shower valve 340 and the mist valve 350, that is, the switching unit 360, in accordance with the control signal from the control unit 81. The transducer drive unit 88 drives the ultrasound transducer 520 according to the control signal from the control unit 81.

The communication unit 89 communicates with the communication unit 156 of the charger 3 using a short-range wireless communication method such as an infrared communication method.

The storage unit 82 includes ROM, RAM, and the like. The storage unit 82 stores a program for causing the control unit 81 to execute predetermined processing. Furthermore, the storage unit 82 stores various parameters and various control flags used for executing the program.

The control unit 81 operates the lamp drive unit 84, electrode current supply unit 85, pump drive unit 86, and valve drive unit according to the program stored in the storage unit 82 based on signals from the operation detection unit 83, the proximity switch 16, etc. 87, controls the vibrator drive unit 88, communication unit 89, etc.

Referring again to FIGS. 1 and 2, the configuration of the charger 3 will be described in detail.

The charger 3 includes a substantially cylindrical casing 100 that is vertically flat. A slightly recessed portion 101 is formed on the top surface of the housing 100. The bottom surface of the recess 101 becomes a mounting surface 102 on which the ozone spray 2 is placed, and is parallel to the bottom surface of the housing 100. A discharge port 103 is formed at the upper rear side of the side surface, that is, the circumferential surface, of the housing 100. The discharge port 103 is composed of a plurality of slit holes arranged in the circumferential direction. When the ozone spray 2 is installed in the charger 3, the discharge port 103 faces in the same direction as the vibration surface 521, which is the discharge port of the mist discharge section 50 of the ozone spray 2, that is, toward the rear of the ozone deodorizing device 1. .

A power feeding unit 110 and a magnet 140 are provided inside the housing 100. Power feeding unit 110 includes a power supply device 111 and a power transmission coil 112. A plug (not shown) is connected to the power supply device 111. When the plug is connected to an outlet, power is supplied to the power supply device 111 from the commercial power source. The power transmitting coil 112 is formed by winding a conductive wire in a spiral shape, and is arranged close to the mounting surface 102 at a position facing the power receiving coil 721 when the ozone spray 2 is installed in the charger 3. The magnet 140 is arranged close to the mounting surface 102 at a position facing the proximity switch 16 when the ozone spray 2 is mounted on the charger 3.

Furthermore, an air passage 104 extending in the front-rear direction is provided within the housing 100. The front side of the air passage 104 is parallel to the bottom surface of the housing 100, and the rear side is inclined diagonally upward with respect to the bottom surface. A housing chamber 105 is formed in the housing 100 so that the front side of the side surface is recessed inward, and an entrance 104a of the air passage 104 is connected to the housing chamber 105. The outlet 104b of the air passage 104 is connected to the discharge port 103. An ozone generator 120 is arranged in the air passage 104, and a fan 130 is arranged in the storage chamber 105. The ozone generator 120 corresponds to the ozone generation section of the present invention, and the fan 130 corresponds to the blower section of the present invention.

The ozone generator 120 is a discharge type ozone generator, and generates discharge such as corona discharge or silent discharge between a pair of electrodes, and generates ozone from the air passed between the pair of electrodes.

The fan 130 is an axial fan that takes in air from outside the housing 100 and sends the taken air to the ozone generator 120 in the air path 104. Further, the fan 130 causes the air to contain ozone generated by the ozone generator 120, and sends it out through the discharge port 103. Note that the fan 130 may be a centrifugal fan.

A positioning structure is provided between the ozone spray 2 and the charger 3 by a protrusion 106 formed on the casing 100 of the charger 3 and a recess 17 formed on the casing 10 of the ozone spray 2 in which the protrusion 106 is accommodated. This positioning structure prevents the ozone spray 2 from being placed on the charger 3 with the ozone spray 2 directed in the opposite direction.

FIG. 6 is a block diagram showing the configuration of the charger 3.

The charger 3 includes a control section 151, a storage section 152, an inverter 153, a generator drive section 154, a fan drive section 155, and a communication section 156 in addition to the configuration described above.

Inverter 153 generates an alternating current voltage from the voltage supplied from power supply device 111 according to a control signal from control unit 151 and applies it to power transmission coil 112 . Inverter 153 constitutes power feeding section 110 together with power supply device 111 and power transmission coil 112.

Generator drive section 154 drives ozone generator 120 according to a control signal from control section 151 . Fan drive section 155 drives fan 130 according to a control signal from control section 151 . The communication unit 156 communicates with the communication unit 89 of the ozone spray 2 using a short-range wireless communication method.

The storage unit 152 includes ROM, RAM, and the like. The storage unit 152 stores a program for causing the control unit 151 to execute predetermined processing. Furthermore, the storage unit 152 stores various parameters and various control flags used in executing the program.

The control unit 151 controls the inverter 153, generator drive unit 154, fan drive unit 155, communication unit 156, etc. according to a program stored in the storage unit 152.

Now, the ozone deodorizing device 1 operates in a cleaning mode and in a deodorizing mode. In the cleaning mode, when the ozone spray 2 is away from the charger 3, ozone water is discharged in a shower form from the shower discharge section 40 based on the operation of the operation section 60, that is, when the operation button 61 is pressed. In the deodorizing mode, when the ozone spray 2 is set in the charger 3 and being charged, the ozone spray 2 periodically releases a mist containing ozone from the mist emitting section 50, and at the same time. The charger 3 releases ozone from the release port 103.

The process for operating in the cleaning mode is executed by the control unit 81 of the ozone spray 2, and the process for operating in the deodorizing mode, that is, the deodorizing process, is executed by the control unit 81 of the ozone spray 2 and the control unit 81 for the charger 3. This is executed in cooperation with the section 151. The control unit 81 of the ozone spray 2 and the control unit 151 of the charger 3 constitute a control unit of the present invention.

FIG. 7 is a flowchart showing the control process of the ozone spray 2 by the control unit 81.

Referring to FIG. 7, the control unit 81 determines whether the ozone spray 2 is installed in the charger 3 based on whether the proximity switch 16 is turned on or off (S101).

When cleaning objects such as a toilet bowl or a kitchen sink, the user holds the ozone spray 2 in his hand and releases it from the charger 3.

If the ozone spray 2 is not installed in the charger 3 (S101: NO), the control unit 81 executes cleaning mode processing (S102 to S104). That is, the control unit 81 monitors whether the operation button 61 is pressed (S102). When the operation button 61 is pressed (S102: YES), the control unit 81 opens the shower valve 340 (S103), and then operates the pump 230 (S104). Thereby, the ozone water in the container 210 is sent to the shower discharge part 40 and is sprayed from the discharge port 41 of the shower discharge part 40 in a shower shape. Although not shown in the flowchart of FIG. 7, the control unit 81 periodically operates the electrolysis unit 220 to maintain the ozone concentration of the ozone water in the container 210 within a predetermined range. .

The operation of the pump 230 is performed for a predetermined time (for example, 1 second), and if the operation button 61 is kept pressed when the predetermined time has elapsed, the depression is released or the time limit (for example, 10 seconds) has elapsed. will continue until While the pump 230 is operating, ozonated water is discharged from the shower discharge section 40. In this way, the ozonated water is released in the form of a shower, which increases the amount of ozone water released. Therefore, the object is likely to be sufficiently wetted with ozonated water. Shower valve 340 is closed when pump 230 stops operating.

Note that in the cleaning mode process, the shower valve 340 is opened before the pump 230 operates, so water pressure can prevent the water pipe 310 from coming off the discharge port 232 of the pump 230.

When deodorizing a room such as a toilet or kitchen, or when charging the ozone spray 2, the user installs the ozone spray 2 on the charger 3.

When the ozone spray 2 is installed in the charger 3 (S101: YES), the control unit 81 instructs the control unit 151 of the charger 3 to transmit power using short-range wireless communication in order to charge the rechargeable battery 710. (S105). After that, the control unit 81 executes deodorizing processing (S106 to S109). That is, the control unit 81 monitors whether the operation timing has arrived (S106). The control unit 81 determines that the operation timing has arrived when a predetermined time (for example, 10 minutes) has elapsed after the start of charging or after the previous start of mist emission from the mist emission unit 50.

When the operation timing arrives (S106: YES), the control unit 81 opens the mist valve 350 (S107), and then operates the pump 230 (S108). As a result, the ozonated water in the container 210 is sent to the mist discharge section 50 and stored in the water storage tank 530. The operation of the pump 230 is continued until a predetermined amount (for example, about 1 cc) of ozonated water is stored in the water tank 530. The water level of the water tank 530 at this time is a water level at which at least the vibration surface 521 of the ultrasonic transducer 520 is submerged. However, the ozonated water is not stored in the water tank 530 to its full capacity. Mist valve 350 is closed when pump 230 stops operating.

Next, the control unit 81 operates the ultrasonic transducer 520 (S109). As a result, mist containing ozone is emitted from the vibrating surface 521, which is the ejection port of the mist emitting section 50. The released mist floats in the air and spreads into the room. The operation of the ultrasonic transducer 520 is continued until the time has elapsed for almost all of the ozone water stored in the water tank 530 to be released.

Note that in the deodorizing process, the mist valve 350 is opened before the pump 230 operates, so water pressure can prevent the water pipe 310 from coming off from the discharge port 232 of the pump 230.

Furthermore, if for some reason too much ozonated water is supplied to the water tank 530 and the water tank 530 becomes full, the ozonated water is discharged from the overflow port 532 and returned into the container 210 through the overflow pipe 540. This prevents ozone water from leaking into the housing 10 due to the mist pipe 330 coming off from the inflow pipe 531 of the water storage tank 530 due to water pressure. Additionally, the returned ozonated water can be reused.

If the ozone spray 2 is separated from the charger 3 while monitoring the arrival of the operation timing (S110: YES), the control unit 81 transmits power to the control unit 151 of the charger 3 using short-range wireless communication. It instructs to stop (S111). Then, the control unit 81 returns to the process of S101 and executes the cleaning mode process until the ozone spray 2 is installed in the charger 3 again.

Note that while the cleaning mode is being operated, the indicator lamp 13 lights up in a color that corresponds to the cleaning mode, and while the deodorizing mode is being operated, the indicator lamp 13 is lit in a color that corresponds to the deodorizing mode. Lights up in the desired color.

FIG. 8 is a flowchart showing control processing of the charger 3 by the control unit 151.

Referring to FIG. 8, the control unit 151 monitors the power transmission instruction from the control unit 81 of the ozone spray 2 (S201). Then, when there is an instruction to transmit power (S201: YES), the control unit 151 drives the inverter 153 (S202).

When the inverter 153 operates, an alternating current flows through the power transmission coil 112. Due to electromagnetic induction, an alternating current flows through the power receiving coil 721 on the ozone spray 2 side, and an alternating voltage is generated. The AC voltage is converted to DC voltage by the charging circuit board 722 and supplied to the rechargeable battery 710. This charges the rechargeable battery 710.

Next, the control unit 151 executes deodorization processing (S203, S204). That is, the control unit 151 monitors whether the operation timing has arrived (S203). The control unit 81 determines that the operation timing has arrived when a predetermined time (for example, 10 minutes), which is the same as the mist emission from the ozone spray 2, has elapsed after the start of charging or after the start of the previous ozone emission. Note that when the control unit 81 of the ozone spray 2 determines that the operation timing has arrived at S106 in FIG. It may be determined that the timing has arrived.

When the operation timing arrives (S203: YES), the control unit 151 operates the ozone generator 120 and the fan 130 (S204). As a result, ozone is released from the discharge port 103 of the charger 3. The emitted ozone is diffused indoors.

A mist containing ozone is emitted from the ozone spray 2 at the same timing and in the same direction as the ozone from the charger 3, that is, to the rear of the ozone deodorizing device 1. Ozone released from the charger 3 mixes with mist in the indoor space, and OH radicals are generated. Like ozone, OH radicals have oxidizing power, so not only the ozone from the charger 3 but also the OH radicals deodorize the room. Furthermore, the ozone contained in the mist also deodorizes the room. In the charger 3, the rear side of the air passage 104 is inclined diagonally upward. Therefore, ozone is emitted diagonally upward from the ejection port 103. This makes it easier for the ozone released from the charger 3 to mix with the mist emitted in the horizontal direction from the mist emitting part 50 of the ozone spray 2, making it easier to generate OH radicals.

The operation of the ozone generator 120 and the fan 130 continues for the same time as the mist is emitted from the ozone spray 2.

As described above, in the present embodiment, the timing at which the charger 3 releases and stops ozone is the same as the timing at which the ozone spray 2 releases and stops the mist. However, the above-mentioned timings do not have to be the same, and it is sufficient that there is a period in which the ozone emission period from the charger 3 and the mist emission period from the ozone spray 2 overlap. Alternatively, if ozone and mist mix indoors and OH radicals are generated, the ozone discharge from the charger 3 is performed immediately before or after the mist discharge from the ozone spray 2, and there is no overlapping period. You can.

While monitoring the arrival of the operation timing, the control unit 151 further monitors an instruction to stop power transmission from the control unit 81 of the ozone spray 2 (S205). Then, when there is an instruction to stop power transmission (S205: YES), the control unit 151 stops the inverter 153 (S206). As a result, power transmission from the power transmission coil 112 is stopped. The control unit 151 returns to S201 and again monitors the power transmission instruction from the control unit 81 of the ozone spray 2.

<Effects of the embodiment>
According to the present embodiment, a deodorizing process is performed in which ozone is released from the charger 3 and mist is released from the ozone spray 2. As a result, the ozone emitted from the charger 3 mixes with the mist from the ozone spray 2 in the indoor space and OH radicals are generated, so the room is deodorized not only by the ozone from the charger 3 but also by the OH radicals. be done. Therefore, the room can be effectively deodorized.

The charger 3 also includes a housing 100 having a discharge port 103, an ozone generator 120 that generates ozone from air, and a fan 130 that sends ozone generated by the ozone generator 120 to the outside through the discharge port 103. , so that ozone can be emitted from the charger 3 by operating the ozone generator 120 and the fan 130.

Furthermore, the charger 3 is configured to discharge ozone generated by the ozone generator 120 obliquely upward from the discharge port 103 provided on the side surface of the housing 100. This makes it easier for the emitted ozone to reach the upper part of the room. In addition, the ozone emitted from the charger 3 is more likely to intersect with the mist emitted from the ozone spray 2 located above the charger 3, making it easier for ozone and mist to mix and for OH radicals to be generated. Become. Therefore, the indoor deodorizing effect is enhanced.

Furthermore, the ozone spray 2 is configured to include a container 210 in which water is stored, and a mist emitting section 50 that generates and emits mist from the water in the container 210. By operating it, the ozone spray 2 can emit mist.

Further, the ozone spray 2 further includes an electrolytic section 220 that generates ozone from water in the container 210 by electrolysis, and a mist emitting section 50 that generates mist from the ozone-containing water generated by the electrolytic section 220. It is said that the structure is As a result, a mist containing ozone can be emitted from the ozone spray 2, and the effect of ozone contained in the mist further enhances the deodorizing effect in the room.

Furthermore, the control unit 81 of the ozone spray 2 and the control unit 151 of the charger 3 are configured to perform deodorization processing based on the ozone spray 2 being installed in the charger 3. This makes it possible to prevent ozone and mist from being released in a state where ozone from the charger 3 and mist from the ozone spray 2 are difficult to mix because the ozone spray 2 is located away from the charger 3. By determining the release position, ozone and mist can be released in a state where ozone and mist are easily mixed, and the deodorizing effect of ozone and OH radicals can be fully exhibited.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, etc., and the embodiments of the present invention can also be modified in various ways other than the above. be.

For example, in the embodiment described above, the water stored in container 210 is pure water. However, tap water may also be stored in the container 210. In this case, since tap water is more likely to contain impurities than pure water, a hollow fiber membrane, etc. A configuration may be adopted in which a filtration filter that filters water such as tap water to remove impurities, or a filter that can remove other impurities is disposed.

Furthermore, in the embodiment described above, the mist emitting unit 50 includes a water storage tank 530 in which ozonated water from the generation unit 20 is stored, and an ultrasonic vibrator that atomizes the ozonated water stored in the water storage tank 530 by ultrasonic vibration. 520. However, the mist emitting section 50 is not limited to the above configuration, and may have a structure having a nozzle with a hole diameter that allows ozonated water to be emitted in the form of a mist, for example.

Furthermore, in the embodiment described above, the mist emitting section 50 and the shower emitting section 40 are arranged so as to face in opposite directions, but they may be arranged side by side so as to face in the same direction.

Furthermore, the generation unit 20 may have a configuration other than that of the above embodiment. For example, the generation unit 20 generates ozone from air using a discharge-type ozone generator, dissolves the ozone in water in the container 210 to generate ozonated water, and pumps the ozonated water by sucking it with the pump 230 to supply the water. The configuration may be such that the information is sent to the section 30. In addition, the generation unit 20 does not generate ozone water in the container 210 as in the above embodiment, but an electrolysis unit 220 is provided upstream or downstream of the pump 230, and the water in the container 210 is generated by the pump 230. When sent to the water supply section 30, the amount of water sent may be electrolyzed by the electrolysis section 220 to generate ozone, and the ozone may be dissolved in the water to generate ozonated water.

Furthermore, in the above embodiment, as a configuration for the charger 3 to release ozone diagonally upward from the release port 103 of the housing 100, the release port 103 is provided at a higher position than the air path 104, and It was formed so that the rear side was slanted diagonally. However, for the above purpose, the outlet 103 is made to be at the same height as the air passage 104, and the entire air passage 104 is made parallel to the bottom surface of the housing 100. A plurality of louvers facing diagonally upward may be provided in the 104b so as to be arranged vertically. Furthermore, the entire air passage 104 may be tilted so that the outlet 103 side is higher. Furthermore, a configuration may be adopted in which the fan 130 is arranged in an inclined state within the air passage 104 so that air is sent obliquely upward toward the discharge port 103.

Furthermore, in the embodiment described above, mist is emitted from the mist emitting portion 50 of the ozone spray 2 in a horizontal direction with the ozone spray 2 being horizontal. However, the mist may be emitted obliquely downward from the ozone spray 2 by tilting the mist emitting section 50 or the like. This makes it easier for the emitted mist to intersect with the ozone emitted diagonally upward from the charger 3 and mix with the ozone, making it easier to generate OH radicals.

Furthermore, in the above embodiment, charging and deodorization processing were performed when the ozone spray 2 was placed on the charger 3. However, a power switch may be provided on the ozone spray 2, and when the power switch is off, only charging is performed and deodorization processing is not performed. In this case, when the power switch is off, periodic electrolysis by the electrolysis unit 220 may not be performed.

Furthermore, in the above embodiment, the ozone spray 2 is supplied with charging power from the charger 3 in a non-contact manner. However, a configuration may also be adopted in which charging power is supplied from the charger 3 to the ozone spray 2 using a contact method.

Furthermore, in the embodiment described above, the ozone deodorizing device 1 is composed of the ozone spray 2 and the charger 3. However, the configuration of the ozone deodorizing device 1 is not limited to such a configuration. For example, the ozone deodorizing device 1 is configured only with the ozone spray 2, and components for emitting ozone, such as an ozone generator 120 and a fan 130, which were provided in the charger 3, are provided at the bottom of the casing 10. You can do it like this. In this case, the bottom of the housing 10 having a configuration for emitting ozone corresponds to the first emitting part of the present invention. Furthermore, in this case, it is preferable to adopt a configuration in which an AC adapter is connected to the ozone spray 2 and power for charging is supplied from the AC adapter to the ozone spray 2.

Furthermore, the ozone deodorizing device 1 is composed of a discharge part that discharges a mist that does not contain ozone and a discharge part that discharges ozone. It may also be provided with a configuration for emitting.

In addition, the embodiments of the present invention can be appropriately modified in various ways within the scope of the technical idea shown in the claims.

2 Ozone spray (second discharge part)
3 Charging part (first discharge part)
50 Mist emission section (mist generation section)
81 Control section
100 housing
103 Outlet
110 Power supply section
120 Ozone generator (ozone generation section)
130 Fan (ventilation part)
151 Control section
210 Container
220 Electrolytic section
710 Rechargeable battery

Claims (6)

In a deodorizing device that can deodorize a room,
a first discharge part that discharges ozone to the outside of the deodorizing device ;
a second discharge part that discharges a mist made of water outside the deodorizing device ;
Control to perform deodorization processing by emitting ozone from the first emitting part and emitting the mist from the second emitting part at the same time as the ozone is emitted , and mixing ozone and the mist in an indoor space. and ,
The second discharge part is located above the first discharge part and discharges the mist in a horizontal direction,
The first discharge section discharges ozone obliquely upward in the same direction as the mist discharge direction by the second discharge section when the deodorizing device is viewed from above.
A deodorizing device characterized by: The deodorizing device according to claim 1,
The first emission part is
a casing having a discharge port;
an ozone generation unit that generates ozone from air;
an air blowing unit that sends ozone generated by the ozone generating unit to the outside through the discharge port;
A deodorizing device characterized by: The deodorizing device according to claim 2,
The discharge port is provided on a side surface of the housing,
The first discharge section discharges ozone generated by the ozone generation section obliquely upward from the discharge port.
A deodorizing device characterized by: The deodorizing device according to any one of claims 1 to 3,
The second emitting section is
A container that can store water,
a mist generating unit that generates the mist from water in the container;
A deodorizing device characterized by: The deodorizing device according to claim 4,
The second discharge part further includes an electrolytic part that generates ozone from water in the container by electrolysis,
The mist generating unit generates the mist from water containing ozone generated by the electrolytic unit.
A deodorizing device characterized by: The deodorizing device according to any one of claims 1 to 5,
The second discharge part includes a charging ground that is a source of power required to discharge the mist, and is removably installed in the first discharge part,
The first discharger includes a power supply unit that supplies power for charging the rechargeable battery with the second discharger installed,
The control unit executes the deodorizing process based on the second emission unit being installed in the first emission unit.
A deodorizing device characterized by:

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