JP2011010806A - Cleaning apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cleaning apparatus which is safe, can save power, generates less noise, can effectively wipe off contamination only, and can easily be used in a short period of time.SOLUTION: This cleaning apparatus 1 can clean a surface S by feeding out a mist M, which is generated by an ultrasonic vibrator 13 of an atomizer 6, on an air stream F which is generated by an electric blower 7, and jetting the mist M toward the surface S from a mist nozzle 24 through a mist passage 8 to wet the surface S, and wiping off the moisture on the surface S together with contamination or dust and dirt with a wiping sheet 23 of a wiping member 4. Then, since the mist M and the air stream F have comparatively low temperatures, a wax or the like on the surface S is not removed, and dust and dirt can be removed without splashing them. Also, a user and persons around the site do not suffer burns or the like. In addition, a large amount of the mist M can be instantly generated with low noise and little power.

Description

  The present invention relates to a cleaning device for wiping and cleaning a floor or the like.

  Conventionally, as this type of cleaning device, after the steam generated by the steam generator is ejected from the steam ejection pipe to the floor surface, etc., the floor surface etc. together with the condensed steam by the rag attached to the rag attachment portion. A steam cleaner that wipes off dirt is known (for example, see Patent Document 1).

JP 2001-327449 A

  However, such a conventional cleaning apparatus may unintentionally peel even the wax applied to the surface to be cleaned such as the floor surface due to the heat of the steam used. In addition, since the conventional cleaning device uses high-temperature steam, there is a possibility that a user or a person around may be burned in some cases. In addition, the conventional cleaning device must generate a large amount of steam in a short time using a high-power heater, which not only consumes a large amount of power, but also generates water boiling noise and steam injection noise. As a result, there is a problem that it cannot be cleaned gently. Furthermore, in the conventional cleaning device, it is necessary to boil water in order to generate steam. Even if a high-power heater is used, steam is generated and can be used after starting to supply power. It takes a long time, so there is a problem that it cannot be used easily when it is desired.

  SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems, and to provide a cleaning device that is safe and power-saving, has low noise, can effectively wipe off only dirt, and can be used easily in a short time.

  The cleaning device according to claim 1 of the present invention includes a main body, a wiping member movably attached to the main body, and a grip provided on the main body. An atomizing device having a child, an electric blower for generating an air flow, a mist passage for sending the mist generated by the atomizing device on the air flow and sending it out of the main body, and a mist toward the surface to be cleaned A mist nozzle for jetting is provided in the vicinity of the wiping member.

  Further, the cleaning device according to claim 2 of the present invention includes a main body, a wiping member that is movably attached to the main body, and a grip portion provided on the main body. An atomizing device having a sound wave oscillator, an electric blower for generating an air flow, and a mist passage for sending the mist generated by the atomizing device to the outside of the main body on the air flow are provided. And a wind guide path for introducing the airflow in a tangential direction with respect to the cylindrical section, and a discharge path provided coaxially in the center of the cylindrical section and connected to the mist path And a mist nozzle for ejecting mist toward the surface to be cleaned is provided in the vicinity of the wiping member.

  The cleaning device according to claim 3 of the present invention is the cleaning device according to claim 1 or 2, wherein a liquid stopper is provided in the middle of the mist passage.

  Furthermore, the cleaning device according to claim 4 of the present invention is the atomizing device according to claim 1 or 2, wherein the main body is attached to the wiping member so as to be inclined backward from a vertical state. The ultrasonic vibrator is provided in the lower rear part of the atomization chamber.

  By configuring the cleaning device according to claim 1 of the present invention as described above, the mist generated by vibrating the ultrasonic vibrator of the atomizing device is converted into the air flow generated by the electric blower. It is sent out and ejected from the mist nozzle toward the surface to be cleaned through the mist passage. Then, the surface to be cleaned is wetted by the mist ejected toward the surface to be cleaned, and the surface to be cleaned is wiped up by wiping the moisture on the surface to be cleaned together with dirt and dust with the wiping member. At this time, since the mist having a relatively low temperature is sprayed on the surface to be cleaned, not only can the protective layer such as wax applied to the surface to be cleaned be removed, but also the user and the surrounding area. You can prevent burners from being burned. In addition, since the temperature of the airflow for sending out the mist is substantially equal to the ambient air temperature (that is, the density of the airflow is approximately equal to the density of the surrounding air), the airflow rises after being ejected from the mist nozzle. Without spreading, it spreads along the surface to be cleaned. As a result, the mist can sink due to its own weight in the air flow and effectively wet the surface to be cleaned, so that the mist effectively adheres to the dust on the surface to be cleaned and the dust rises during cleaning. Can be difficult. Further, since the atomizing device has an ultrasonic vibrator, not only can a large amount of mist be generated with a small electric power, but also a mist can be generated in a short time from an operation for starting use. At the same time, noise accompanying the generation of mist can be suppressed.

  Moreover, the cleaning device according to claim 2 of the present invention is configured as described above, so that the electric blower generates the mist generated by vibrating the ultrasonic vibrator of the atomizing device. It is sent out in the air current and ejected from the mist nozzle toward the surface to be cleaned through the mist passage. Then, the surface to be cleaned is wetted by the mist ejected toward the surface to be cleaned, and the surface to be cleaned is wiped up by wiping the moisture on the surface to be cleaned together with dirt and dust with the wiping member. At this time, since the mist having a relatively low temperature is sprayed on the surface to be cleaned, not only can the protective layer such as wax applied to the surface to be cleaned be removed, but also the user and the surrounding area. You can prevent burners from being burned. Also, among the mist generated in the atomizer, coarse mist is separated in the centrifugal separation chamber, and fine mist is sprayed from the nozzle to the surface to be cleaned through the mist passage. By increasing the ratio of the surface area to the volume of mist, the reactivity with respect to dirt adhered to the surface to be cleaned can be increased. In addition, since the temperature of the airflow for sending out the mist is substantially equal to the ambient air temperature (that is, the density of the airflow is approximately equal to the density of the surrounding air), the airflow rises after being ejected from the mist nozzle. Without spreading, it spreads along the surface to be cleaned. As a result, the mist can sink due to its own weight in the air flow and effectively wet the surface to be cleaned, so that the mist effectively adheres to the dust on the surface to be cleaned and the dust rises during cleaning. Can be difficult. Further, since the atomizing device has an ultrasonic vibrator, not only can a large amount of mist be generated with a small electric power, but also a mist can be generated in a short time from an operation for starting use. At the same time, noise accompanying the generation of mist can be suppressed.

  Further, by providing a liquid stopper in the middle of the mist passage, water in the atomization device flows from the nozzle to the surface to be cleaned through the mist passage even when the cleaning device is tilted. Can be prevented.

  Further, the main body can be tilted backward from the vertical state with respect to the wiping member, and the ultrasonic vibrator is provided at the lower rear part of the atomization chamber of the atomizer, so that the use is Even if the main body is tilted backward, the vibrating ultrasonic transducer is difficult to be exposed to the air, so that the ultrasonic transducer can be hardly damaged.

It is a front view of a cleaning device showing a first embodiment of the present invention. FIG. It is an enlarged right side view near the wiping member. It is the schematic of an atomizer. It is an AA expanded sectional view same as the above. It is AA sectional drawing in the state which inclined the main body same as the above. It is BB sectional drawing. It is CC sectional drawing similarly. It is the schematic of a liquid stop part same as the above. FIG. It is a circuit diagram of the cleaning apparatus which shows 2nd embodiment of this invention.

  Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. Reference numeral 1 denotes a cleaning device according to the present invention. The cleaning device 1 includes a main body 2, a wiping member 4 that is swingably attached to a lower portion of the main body 2 via a joint portion 3, and a grip portion 5 that is attached to the upper portion of the main body 2. It is configured. The main body 1 and the grip portion 5 are configured to be inclined rearward (right side in FIG. 2) from the upright state of the main body 2 shown in FIG. 2 around the rotation axis of the joint portion 3. The

  An atomizing device 6, an electric blower 7, and a mist passage 8 are provided in the main body 2. The atomization device 6 includes a water tank 9, an atomization chamber 10, and a centrifuge chamber 11. The water tank 9 is detachably attached to the atomization chamber 10. The water tank 9 is configured to keep the water level in the atomization chamber 10 substantially constant. A through hole 12 is formed at the bottom of the atomizing chamber 10, and an ultrasonic vibrator 13 is attached so as to close the through hole 12. The through hole 12 is formed near the rear of the atomization chamber 10. That is, the ultrasonic transducer 13 is provided near the rear of the atomization chamber 10. The centrifuge chamber 11 includes a cylindrical tubular portion 14, an air guide path 15, and a discharge path 16. The air guide path 15 is connected to the atomizing chamber 10 side of the cylindrical portion 14 (that is, the lower portion of the cylindrical portion 14 in FIG. 5) in a tangential direction with respect to the inner surface of the cylindrical portion 14. It is formed so that. The electric blower 7 is connected to the air guide path 15. Further, the discharge passage 16 extends from the side of the cylindrical portion 14 opposite to the atomizing chamber 10 (that is, the upper portion of the cylindrical portion 14 in FIG. 5) to the side of the atomizing chamber 10 (that is, the lower side in FIG. 5). It is provided to extend coaxially. Further, the discharge passage 16 is connected to an upstream side passage 8 </ b> A constituting a part of the mist passage 8.

  A liquid stopper 17 is provided in the middle of the mist passage 8 to prevent liquid water from being discharged. As shown in FIG. 9, the liquid stop portion 17 includes a water storage portion 18, an inlet pipe portion 19 provided at the upper portion of the water storage portion 18, and an outlet pipe portion 20 provided at the lower portion of the water storage portion 18. It is comprised. FIG. 9 shows the liquid stopper 17 in a state where the main body 2 is upright. The end 19A of the inlet pipe 19 in the water reservoir 18 opens downward in the state shown in FIG. On the other hand, the end 20A of the outlet pipe part 20 in the water storage part 18 is bent so as to open downward in the state of FIG. A bendable hose portion 21 constituting a part of the mist passage 8 is connected to the lower end of the outlet pipe portion 20.

  The wiping member 4 includes a base 22 and a wiping sheet 23 that is detachably attached to the base 22. In addition, a well-known structure can be used for the attachment structure of the wiping sheet 23 to the base 22. A mist nozzle 24 is attached in front of the wiping member 4. The mist nozzle 24 has an arm portion 24 </ b> A at a rear portion thereof, and the arm portion 24 </ b> A is pivotally supported by the joint portion 3. The mist nozzle 24 is connected to the hose portion 21. A jet port 24B formed at the front end of the mist nozzle 24 opens close to the surface to be cleaned S and is formed to be approximately equal to the width of the base portion 22.

  The grip portion 5 includes a rod-like portion 25 connected to the main body 2, a grip portion 26 provided at the tip of the rod-like portion 25, and an operation portion 27 provided on the grip portion 26. Is done. By operating the operation unit 27, the switch 28 is turned on or off, and power is supplied to or cut off from the electric blower 7 and the ultrasonic vibrator 13 by the control circuit 29. Reference numeral 30 denotes an AC-DC conversion circuit that converts an AC current supplied from a power plug 31 connected to an AC power source (not shown) into a DC current.

  Next, the operation of this embodiment will be described. First, the user puts water into the water tank 9 and then attaches the water tank 9 to the atomization chamber 10. When the water tank 9 is thus attached to the atomization chamber 10, the water in the water tank 9 flows into the atomization chamber 10. When the water level in the atomizing chamber 10 reaches a predetermined value, the inflow of water from the water tank 9 to the atomizing chamber 10 is stopped. Here, as described above, the ultrasonic transducer 13 is attached so as to close the through-hole 12 formed in the bottom of the atomization chamber 10, so that the most in the atomization chamber 10. Since it is provided at a low position, the ultrasonic transducer 13 is always located in water when the main body 2 is upright. In addition, when using the said cleaning apparatus 1, the grip part 26 of the said holding part 5 is hold | gripped, and as shown in FIG. 3, the said main body 2 will incline back. However, as described above, since the through-hole 12 is formed closer to the rear of the atomization chamber 10, the ultrasonic vibrator 13 is provided closer to the rear of the atomization chamber 10, so that FIG. As shown in FIG. 3, even if the main body 2 is inclined backward, the ultrasonic transducer 13 is difficult to be exposed on the water surface. Then, the user attaches the wiping sheet 23 to the base 22. Further, the user connects the power plug 31 to an AC power source (not shown). In this way, the cleaning device 1 is ready for use.

  Then, by operating the operation unit 27 to turn on the switch 28, the control circuit 29 causes the electric blower 7 and the ultrasonic transducer to convert the electric power that has been DC-converted by the AC-DC conversion circuit 30. 13 is supplied. Thus, when electric power is supplied to the ultrasonic vibrator 13, the ultrasonic vibrator 13 vibrates at a frequency in the ultrasonic band, and atomizes the water in the atomizing chamber 10. In this way, mist M is generated. In addition, the operation sound of the electric blower 7 and the ultrasonic vibrator 13 is quieter than that of the steam generator used in the conventional cleaning device. Therefore, the cleaning device 1 of the present application can be made quieter than the conventional one. In addition, since the mist is generated immediately by applying ultrasonic vibration to the water in the atomization chamber 10, the cleaning device 1 of the present application quickly generates the mist by turning on the switch 28. Can do. Therefore, the cleaning device 1 of the present application can be put into a usable state in a shorter time than the conventional one. Furthermore, the ultrasonic transducer 13 consumes less power than a steam generator (ie, a heater) used in a conventional cleaning device. Therefore, the cleaning device 1 of the present application can save power compared to the conventional one. The air flow F generated by the operation of the electric blower 7 flows into the cylindrical portion 14 from the air guide path 15 formed in the lower portion of the cylindrical portion 14 of the centrifugal separation chamber 11. In addition, even if the said main body 2 is inclined back by the said air guide path 15 being provided in the front side of the lower part of the said cylindrical part 14, the water in the said atomization chamber 10 is the said air guide. There is no leakage from the road 15. Therefore, the water in the atomization chamber 10 does not wet the electric blower 7. And since the said air guide path 15 is formed so that it may connect in a tangential direction with respect to the inner surface of the said cylindrical part 14, the said air flow F turns into the swirl | vortex flow V in the said cylindrical part 14. FIG. Then, as the mist M rides on the swirl flow V and rotates in the cylindrical portion 14, the mist M having a coarse particle size (Ml) is caused by centrifugal force of the cylindrical portion 14. Gather on the outer periphery. On the other hand, fine particles (Mf) of the mist M gather on the center side of the cylindrical portion 14. The fine mist Mf gathered on the center side of the cylindrical portion 14 is sent from the discharge path 16 to the mist path 8 by the airflow F. In this way, only the fine mist Mf flows out of the centrifuge chamber 11. The coarse mist Ml collected on the outer peripheral side of the cylindrical portion 14 adheres to the inner wall of the cylindrical portion 14 and becomes water droplets. The water droplets flow down along the inner wall of the cylindrical portion 14 and return to the atomization chamber 10. Moreover, although the water in the atomization chamber 10 is reduced due to the generation of the mist M, this reduced amount of water is supplied from the water tank 9 to the atomization chamber 10.

  The mist Mf sent to the mist passage 8 is sent to the mist nozzle 24 via the upstream passage 8A, the liquid stopper 17 and the hose portion 21, and is discharged from the jet outlet 24B of the mist nozzle 24. Sprayed onto the cleaning surface S. The mist Mf can pass through the liquid stopper 17 by entering the water reservoir 18 from the inlet pipe 19 and exiting the outlet pipe 20. On the other hand, when the cleaning device 1 is turned over, liquid water W may flow into the liquid stopper 17 from the discharge passage 16 through the upstream passage 8A. In the state of FIG. 9 in which the main body 2 stands upright, W is configured to be bent so that the end portion 20A of the outlet pipe portion 20 opens downward. It cannot flow out from the end portion 20 </ b> A of the pipe portion 20. And since the hose part 21 is bendable as described above, the movement of the joint part 3 is not hindered.

  Further, the relative position of the mist nozzle 24 with the base portion 22 of the wiping member 4 is substantially fixed when the cleaning device 1 is used. That is, when the cleaning device 1 is used, the jet outlet 24B of the mist nozzle 24 continues to be close to the surface to be cleaned S. As described above, when the mist Mf is sprayed onto the surface to be cleaned S, the mist Mf wets the surface to be cleaned S thinly. Note that the airflow F that sends out the mist Mf is air sucked from the outside of the cleaning device 1 by the electric blower 7, so that the temperature is almost the same as the ambient temperature of the cleaning device 1 (that is, almost the same density as the ambient air). ). Accordingly, the air flow F does not rise after being ejected from the ejection port 24B, and spreads thinly along the surface to be cleaned S. Therefore, the particulate mist Mf riding on the air flow F spreads thinly along the surface to be cleaned S while being ejected from the ejection port 24B and then sinking. As described above, the mist Mf spreads thinly along the surface to be cleaned S, so that the mist Mf easily adheres to dust on the surface to be cleaned S. Accordingly, the dust on the surface to be cleaned S is less likely to rise due to the mist Mf adhering thereto. The dirt and dust on the surface to be cleaned S wetted by the mist Mf is obtained by the user moving the wiping member 4 along the surface to be cleaned S with the grip portion 26 of the grip portion 5. The wiping sheet 23 attached to the base 22 of the wiping member 4 is wiped off. In this way, the surface to be cleaned S is cleaned. Most of the moisture on the surface to be cleaned S is absorbed by the wiping sheet 23 and the remaining portion is naturally dried.

  Since the mist Mf is relatively low in temperature, the wax applied to the surface to be cleaned S is not unintentionally melted. Therefore, the cleaning device 1 of the present application that blows the mist Mf onto the surface to be cleaned S can remove only dirt and dust. Moreover, since the said mist Mf is comparatively low temperature, the cleaning apparatus 1 of this application can prevent a user or those around around from a burn etc.

  As described above, in the present embodiment, only the fine mist Mf is sprayed from the mist nozzle 24 onto the surface to be cleaned S. The fine mist Mf has a larger surface area ratio to the volume than the coarse mist Ml. Therefore, when the mist Mf contains a drug by adding the drug to the water in the water tank 9, the mist Mf Mf is expected to accelerate the chemical reaction by allowing the drug to come into contact with air and dirt over a wide area. Further, the mist Mf spreads over a wider range than the width of the base portion 22 and adheres to the surface to be cleaned S by forming the ejection port 24B substantially equal to the width of the base portion 22 of the wiping member 4. At this time, the mist Mf may rewet the portion of the surface to be cleaned S that has been wiped by the wiping sheet 23. However, as described above, since the mist Mf is fine, the surface to be cleaned S is wetted thinly and widely. Therefore, even if the water that wets the surface to be cleaned S is left unwiped, it quickly evaporates. Therefore, the surface to be cleaned S is not left wet for a long time.

  As described above, the cleaning device 1 of the present invention sends out the mist M generated by the ultrasonic vibrator 13 of the atomizing device 6 on the airflow F generated by the electric blower 7 and passes through the mist passage 8. Then, the surface to be cleaned S is wetted by being ejected from the mist nozzle 24 toward the surface to be cleaned S, and moisture on the surface to be cleaned S is wiped off along with dirt and dust by the wiping sheet 23 of the wiping member 4. The cleaning surface S can be wiped and cleaned. And since the temperature of not only the mist M but also the air flow F for sending out the mist M is relatively low, it is possible to remove only dirt and dust without peeling off the wax or the like of the surface S to be cleaned. Further, the airflow F and the mist M riding on the airflow F do not rise after being ejected from the mist nozzle 24 and spread thinly on the surface to be cleaned S, so that the mist M is applied to dust on the surface to be cleaned S. It is possible to effectively adhere, prevent dust from flying up during cleaning, and prevent the user and those around him from being burned. Further, since the atomizing device 6 includes the ultrasonic vibrator 13, not only can a large amount of the mist M be generated with a small amount of electric power, but also the mist M can be generated in a short time after power is supplied. It is possible to suppress noise caused by the generation of the mist M.

  Further, the cleaning device 1 of the present invention is rough in the mist M generated in the atomizing device 6 because the air flow F flowing in from the air guide path 15 becomes the swirl flow V in the cylindrical portion 14. The mist Ml is centrifuged in the centrifuge chamber 11, and the fine mist Mf is sprayed from the discharge passage 16 through the mist passage 8 to the surface to be cleaned S from the mist nozzle 24, so that the mist Mf contains a medicine or the like. In this case, the ratio of the surface area to the volume of the mist Mf can be increased, and the reactivity to dirt and air adhering to the surface to be cleaned S can be increased.

  In addition, the cleaning device 1 of the present invention is provided with the liquid stopper 17 in the middle of the mist passage 8, so that the water W in the atomization device 6 remains in the atomizing device 6 even when the cleaning device 1 is tilted. It is possible to prevent the mist nozzle 4 from flowing out to the surface to be cleaned S through the mist passage 8.

  Further, the cleaning device 1 of the present invention enables the main body 2 to tilt backward from a state where it is upright with respect to the wiping member 4, and the ultrasonic wave is applied to the lower rear portion of the atomizing chamber 10 of the atomizing device 6. The provision of the vibrator 13 makes it difficult for the ultrasonic vibrator 13 that is vibrating to be exposed to the air even if the main body 2 is tilted backward with use. Can be made difficult to damage.

  Next, a second embodiment of the present invention will be described based on FIG. In the present embodiment, the electric blower 7 and the ultrasonic vibrator 13 are operated using the secondary battery 41 charged by the charging circuit 40. Reference numeral 42 denotes a charging terminal. Other configurations and operations are basically the same as those in the first embodiment.

  In addition, this invention is not limited to the above embodiment, A various deformation | transformation implementation is possible within the range of the summary of invention. For example, in the above embodiment, only the fine mist in the mist is ejected from the mist nozzle by the centrifugal separation chamber, but all the generated mist may be ejected from the mist nozzle.

DESCRIPTION OF SYMBOLS 1 Cleaning apparatus 2 Main body 4 Wiping member 5 Holding part 6 Atomization apparatus 7 Electric blower 8 Mist passage 10 Atomization room 11 Centrifugation room 13 Ultrasonic vibrator 14 Cylindrical part 15 Air guide path 16 Discharge path 17 Liquid stop part 24 Mist nozzle M Mist S Surface to be cleaned F Airflow

Claims (4)

  A main body, a wiping member movably attached to the main body, and a gripping portion provided on the main body, and an atomization device having an ultrasonic transducer in the main body, and an electric motor that generates an air flow Provided with a blower and a mist passage for sending the mist generated by the atomizing device to the outside of the main body in an air flow, and a mist nozzle for ejecting the mist toward the surface to be cleaned is in the vicinity of the wiping member A cleaning device provided.   A main body, a wiping member movably attached to the main body, and a gripping portion provided on the main body, and an atomization device having an ultrasonic transducer in the main body, and an electric motor that generates an air flow A blower and a mist passage for sending the mist generated by the atomizing device to the outside of the main body on an air flow are provided, and the atomizing device is arranged in a tangential direction with respect to the cylindrical portion and the cylindrical portion. It has a centrifugal separation chamber having a wind guide path for introducing an air flow and a discharge path connected to the mist passage and coaxially provided at the center of the cylindrical portion, and on the surface to be cleaned. A cleaning apparatus comprising a mist nozzle for ejecting mist toward the wiping member.   The cleaning device according to claim 1, wherein a liquid stopper is provided in the middle of the mist passage.   The main body is attached to the wiping member so as to be tiltable backward from a vertical state, and the ultrasonic vibrator is provided at a lower rear portion of the atomization chamber of the atomizer. Item 3. A cleaning device according to item 1 or 2.

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