JP2011172740A - Vacuum cleaner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vacuum cleaner capable of effectively spreading electrolytic water to every part of the interior of a room without decreasing its bacteria elimination effect. <P>SOLUTION: In a vacuum cleaner body 2, an emission port 33 of the electrolytic water is provided above an exhaust port 14. Electrolytic water mist M generated by an electrolytic water mist generation unit 30 is emitted from the emission port 33. The mist M is emitted from the emission port 33 that is upward spaced from an exhaust port 14 from which relatively high-temperature exhaust is emitted. This constitution can suppress the decrease in the bacteria elimination effect of the mist M caused by the heat of the exhaust, at a step when the mist M is emitted from the emission port 33. The exhaust port 14 emits the exhaust diagonally upward. Therefore, when the mist M once emitted diagonally upward from the emission port 33, starts to descend by the dead weight, the mist M is spread diagonally upward again by the exhaust, which is cooled to such an extent as not to decrease the bacteria elimination effect of the mist M, thus sending the mist M to the distance. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a vacuum cleaner.

There is known a vacuum cleaner provided with an electrolyzed water generating device that generates electrolyzed water containing hypochlorous acid and active oxygen having a sterilizing effect (see Patent Document 1).
In the electric vacuum cleaner described in Patent Document 1, the electrolyzed water generated by the electrolyzed water generating device is pumped and injected into the exhaust filter. Therefore, the air exhausted through the exhaust filter can be sterilized by exposure to the electrolyzed water contained in the exhaust filter.

There is also known an electric vacuum cleaner that generates negative ions that have a positive effect on a living body and releases the negative ions out of the main body of the vacuum cleaner (see Patent Document 2).
In the electric vacuum cleaner described in Patent Document 2, an ion generator chamber having an ion discharge port facing to the rear side is provided in the upper portion of the cleaner body, and the ion generator is accommodated in the ion generator chamber. Yes. A part of the air (exhaust gas) discharged from the electric blower enters the ion generator chamber, and is discharged out of the machine from the ion discharge port together with the negative ions generated by the ion generator. Thereby, negative ions are diffused into the room.

JP 2006-175043 A JP 2004-24414 A

Recently, interest in indoor air is high, and it is desired that indoor air can be sterilized strongly. Moreover, a high added value is always calculated | required by the vacuum cleaner.
Then, the vacuum cleaner which has a function which diffuses the electrolyzed water of patent document 1 in a room | chamber interior and performs air cleaning is considered. However, even if electrolyzed water becomes mist shape, it is comparatively heavy, and even if it uses the structure of the vacuum cleaner of patent document 2, it is difficult to spread electrolyzed water far.

Moreover, when the electrolyzed water is applied to the electric vacuum cleaner described in Patent Document 2, the electrolyzed water is discharged from the electric blower and diffused into the room on a relatively high temperature exhaust gas, as in the case of negative ions. In this case, there is a possibility that the sterilizing effect of the electrolyzed water is lowered by the heat of the exhaust.
Furthermore, as long as a liquid called electrolyzed water is handled, electrolyzed water may spill from the vacuum cleaner and wet the floor.

The present invention has been made under such a background, and has as its main object to provide a vacuum cleaner that can effectively distribute electrolyzed water indoors without reducing its sterilizing effect. To do.
Another object of the present invention is to provide a vacuum cleaner that can prevent electrolyzed water from spilling out and wet the floor surface.

  The invention according to claim 1 is provided with a vacuum cleaner main body having an electric blower built therein and provided with an exhaust port for discharging exhaust gas generated when the electric blower is driven, and provided above the exhaust port. An electrolyzed water mist generating unit, and an electrolyzed water mist generating unit that generates electrolyzed water mist in order to eject electrolyzed water mist from the jet port. The electric vacuum cleaner is characterized in that the exhaust from the exhaust port is discharged obliquely upward in order to dissipate the electrolyzed water mist ejected from the ejection port obliquely upward.

  According to a second aspect of the present invention, the exhaust port and the jet port are provided on one side surface of the cleaner body, and the electrolyzed water mist generating unit includes a tank capable of storing water therein, An electrode for electrolyzing water into electrolyzed water and a plate having a large number of through holes, and one side faces the tank while being inclined at a predetermined angle with respect to the vertical direction. The other side surface is attached to the tank in a state where the other side surface is exposed from the one side surface of the cleaner body through the jet port, and the electrolytic water mist is generated from the electrolyzed water of the tank, and is inclined from the through hole. The vacuum cleaner according to claim 1, further comprising an ultrasonic vibrator for ejecting upward.

The invention according to claim 3 is characterized in that the angle formed between the discharge direction of the electrolyzed water mist obliquely above and the horizontal direction is less than the angle formed between the discharge direction of the exhaust gas obliquely above and the horizontal direction. A vacuum cleaner according to claim 2.
The invention according to claim 4 is the electric vacuum cleaner according to claim 3, wherein an inclination angle of the ultrasonic transducer with respect to a vertical direction is about 15 °.

The invention according to claim 5 is characterized in that the angle formed between the discharge direction of the electrolyzed water mist obliquely above and the horizontal direction is equal to or greater than the angle formed between the discharge direction obliquely above the exhaust gas and the horizontal direction. A vacuum cleaner according to claim 2.
The invention according to claim 6 is the electric vacuum cleaner according to claim 5, wherein an inclination angle of the ultrasonic transducer with respect to a vertical direction is about 60 °.

  According to a seventh aspect of the present invention, in the vacuum cleaner main body in the storage state, the one side surface is opposed to the floor surface from above, and is provided in the vacuum cleaner main body, and the super vacuum cleaner main body is in the storage state. The receiving part which receives the water which spills from said other side surface of a sound wave vibrator, The water absorption member which is provided in the said receiving part and absorbs the water which the said receiving part received is characterized by the above-mentioned. It is a vacuum cleaner in any one of -6.

  According to the first aspect of the present invention, in the vacuum cleaner main body of the electric vacuum cleaner, the exhaust generated when the electric blower is driven is discharged from the exhaust port. In addition, an outlet for electrolyzed water mist is provided above the exhaust port. Here, an electrolyzed water mist generating unit is built in the cleaner body, and the electrolyzed water mist generated by the electrolyzed water mist generating unit is ejected from the ejection port.

Since the electrolyzed water mist is ejected from a jet outlet that is spaced upward from the exhaust port from which the relatively high temperature exhaust gas is discharged, the sterilization effect of the electrolyzed water mist is exhausted at the stage when the electrolyzed water mist is jetted from the jet port. It can suppress that it falls with the heat of.
The exhaust port then discharges the exhaust gas obliquely upward. Therefore, when the electrolyzed water mist once ejected obliquely upward from the jet outlet is going to descend by its own weight, the electrolyzed water mist is again inclined obliquely upward by the exhaust cooled so as not to reduce the sterilizing effect of the electrolyzed water mist. Dissipated. Thereby, the electrolyzed water mist can be moved away.

As a result, the electrolyzed water can be effectively distributed indoors without reducing the sterilizing effect.
According to invention of Claim 2, an exhaust port and a jet nozzle are provided in one side of the cleaner body.
The electrolyzed water mist generating unit includes a tank for storing water, an electrode for converting the water in the tank into electrolyzed water, and an ultrasonic vibrator attached to the tank.

The ultrasonic transducer has a plate shape in which a large number of through holes are formed, and is inclined by a predetermined angle with respect to the vertical direction. In the ultrasonic vibrator, one side faces the inside of the tank and the other side is exposed from one side of the cleaner body through the jet port.
Thereby, the ultrasonic vibrator generates electrolyzed water mist from the electrolyzed water in the tank and ejects it obliquely upward from the through hole. Therefore, since the electrolyzed water mist is ejected obliquely upward at the ejection port, the electrolyzed water mist can be blown as far as possible.

In addition, since the electrolyzed water mist is ejected obliquely upward at the ejection port, it is kept away from the exhaust gas discharged obliquely upward at the exhaust port below the ejection port, so that the electrolytic water mist is ejected from the ejection port. At the end, the sterilization effect of the electrolyzed water mist can be prevented from being lowered by the heat of the exhaust.
According to the third aspect of the present invention, the angle formed by the obliquely upward jet direction of the electrolyzed water mist and the horizontal direction is less than the angle formed by the obliquely upward discharge direction of the exhaust gas from the exhaust port and the horizontal direction. As a result, the electrolyzed water mist and the exhaust gas are always mixed, so that the electrolyzed water mist can be put on the exhaust gas and reliably traveled far and efficiently spread over a wide space.

  According to the invention of claim 4, the inclination angle of the ultrasonic transducer with respect to the vertical direction is about 15 °. As a result, even if external air enters the tank through the through hole when the electrolytic water of the tank passes through the through hole of the ultrasonic transducer and becomes a bubble, the bubble adheres to the ultrasonic transducer. And quickly move to the upper space of the tank without blocking the through hole. Thereby, it can prevent that the ejection of the electrolyzed water mist in the through-hole of an ultrasonic transducer | vibrator is prevented by the bubble.

According to the fifth aspect of the present invention, the angle formed by the obliquely upward jet direction of the electrolyzed water mist and the horizontal direction is equal to or greater than the angle formed by the obliquely upward discharge direction of the exhaust gas and the horizontal direction. Therefore, as in the invention described in claim 6, the inclination angle of the ultrasonic transducer with respect to the vertical direction is preferably about 60 °.
In this case, since the electrolyzed water mist that flows obliquely upward without descending can be separated from the exhaust, it is possible to prevent the sterilizing effect of the electrolyzed water mist from being lowered by the exhaust.

According to the seventh aspect of the present invention, in the vacuum cleaner main body in the housed state, one side surface provided with the jet nozzle faces the floor surface from above. For this reason, the other side surface of the ultrasonic vibrator exposed from one side surface of the cleaner body through the jet nozzle also faces the floor surface from above, so that the electrolyzed water in the tank passes from the through hole of the ultrasonic vibrator to the other side. It is assumed that it spills on the floor surface along the side.
Therefore, the vacuum cleaner main body is provided with a receiving portion. The receiving portion receives electrolyzed water that spills from the other side surface of the ultrasonic vibrator when the cleaner body is in the housed state. Furthermore, the water absorption member provided in the receiving part absorbs the water received by the receiving part.

  Therefore, when the cleaner body is in the housed state, it is possible to prevent electrolytic water from spilling and wetting the floor surface.

It is a right view of the vacuum cleaner main body 2 of the vacuum cleaner 1 which concerns on one Embodiment of this invention. It is right side sectional drawing of the cleaner body 2. FIG. It is a rear view of the cleaner body 2, and shows a state where the handle 7 is erected and the cover 32 is removed. It is a rear view of the cleaner body 2. (A) is a rear view of the electrolyzed water mist production | generation unit 30, (b) is AA arrow sectional drawing of (a), (c) is BB arrow view of (a). It is sectional drawing. It is right side sectional drawing of the cleaner body 2 in the accommodation state. It is the figure which applied the modification to FIG.

Embodiments of the present invention will be specifically described below with reference to the drawings.
FIG. 1 is a right side view of a cleaner body 2 of a vacuum cleaner 1 according to an embodiment of the present invention. In the following, regarding the description of the vacuum cleaner 1 and its components, for the sake of convenience, the left side in FIG. 1 will be described as the front side, the right side as the rear side, the back side as the left side, and the near side as the right side, unless otherwise specified. The left-right direction and the width direction are the same.

With reference to FIG. 1, the vacuum cleaner 1 is provided with the cleaner main body 2, the hose 3, the pipe (not shown), and the suction tool (not shown).
The vacuum cleaner main body 2 has a box shape that is slightly longitudinally rounded in the front-rear direction. In FIG. 1, a housing 4, which is a hollow body that forms an outline of the vacuum cleaner main body 2, wheels 5 attached to the rear end portions of the left and right side surfaces of the housing 4, and a front end portion of the bottom surface of the housing 4 An attached caster 6 and a handle 7 attached to the top surface of the housing 4 are shown.

When the wheel 5 and the caster 6 rotate on the floor surface X (surface to be cleaned), the cleaner body 2 can smoothly move on the floor surface X. The state of the cleaner body 2 when the wheel 5 and the caster 6 are in contact with the floor surface X is referred to as a normal state.
The handle 7 has a U-shape that bulges out to the rear side in a plan view, and can be rotated with the front end as a fulcrum. The handle 7 is between a tilted position along the top surface of the housing 4 (see FIG. 1) and a standing position (see FIG. 3 described later) that stands up so as to be substantially orthogonal to the top surface of the housing 4. It can be rotated.

Next, the internal configuration of the cleaner body 2 (housing 4) will be described.
FIG. 2 is a right side sectional view of the cleaner body 2.
Referring to FIG. 2, the cleaner body 2 mainly includes a first filter 8, an electric blower 9, and a second filter 10 in a housing 4.
Here, in the housing 4, an intake port 12 is formed on the front surface 11, an exhaust port 14 is formed on the rear surface 13 (one side surface), and the intake port 12 and the exhaust port 14 communicate with each other inside the housing 4. An air flow path 15 is defined. The first filter 8, the electric blower 9, and the second filter 10 described above are disposed in the air flow path 15. Specifically, the first filter 8, the electric blower 9, and the second filter 10 are seen from the air flow direction (see the thick black arrow) in the air flow path 15 from the first filter 8 → the electric blower 9 → the second from the upstream side. Two filters 10 are arranged in this order.

When the cleaner body 2 is in a normal state, the rear surface 13 of the housing 4 extends along a substantially vertical direction. A plurality (four in this case) of the exhaust ports 14 are provided at approximately the center of the rear surface 13 in the vertical direction. These exhaust ports 14 are slits that are elongated in the width direction (see also FIG. 3 to be described later), and are lined up and down at a predetermined interval.
Further, in relation to the lowermost exhaust port 14A, a recess 17 that is recessed forward is formed in a portion of the rear surface 13 where the exhaust port 14A is formed. The concave portion 17 has a substantially triangular shape that narrows toward the front side when viewed from the width direction, and is elongated in the width direction (see also FIG. 3). The exhaust port 14A forms a front lower side portion of the concave portion 17, is exposed from the concave portion 17 to the rear surface 13, and faces the rear upper side.

  The exhaust port 14A is provided with a shutter 18 having a plate shape elongated in the width direction. The shutter 18 can be opened and closed by rotating around a shaft (not shown) extending in the width direction at the front end portion thereof. The shutter 18 is closed so as to extend rearwardly and closes the exhaust port 14A from the inside of the housing 4 (not shown). On the other hand, when the shutter 18 is rotated by a predetermined amount counterclockwise in a right side view from the closed state, the shutter 18 opens so as to extend to the front upper side and opens the exhaust port 14A (see FIG. 2). The shutter 18 is closed except during cleaning.

The hose 3 is a flexible bellows-like hose, and one end of the hose 3 is connected to the air inlet 12 so that the inside of the hose 3 and the air flow path 15 communicate with each other.
In the vacuum cleaner 1, one end of a pipe (not shown) is connected to the other end of the hose 3, and a suction tool (not shown) is connected to the other end of the pipe. The suction tool (not shown) has a box shape that is long in the width direction and flat in the vertical direction, and a suction port (not shown) facing the floor surface X from above is formed on the bottom surface thereof.

  In such a vacuum cleaner 1, when cleaning the floor surface X, the electric blower 9 is driven by receiving electric power to generate a suction force. This suction force acts on a suction port (not shown) of a suction tool (not shown). Therefore, the dust on the floor surface X is sucked into the suction tool (not shown) from the suction port (not shown) by this suction force, and the suction tool, pipe (not shown), and hose 3 are moved in this order. Then, the air is sucked from the air inlet 12 to the air flow path 15 of the cleaner body 2. Further, the air around the suction tool (not shown) is sucked up to the air flow path 15 together with the dust on the floor surface X.

  The air and dust sucked up to the air flow path 15 are first received by the first filter 8 as indicated by a thick black arrow. At that time, dust is captured by the first filter 8, whereby air and dust are separated, and only air passes through the first filter 8 and continues to flow through the air flow path 15. The air that has passed through the first filter 8 is discharged by the electric blower 9 to the downstream side of the electric blower 9 in the air flow direction described above in the air flow path 15.

  The air discharged to the downstream side of the electric blower 9 passes through the second filter 10. The second filter 10 has a high dust capturing performance belonging to a so-called HEPA filter (High Efficiency Particulate Air Filter) or ULPA filter (Ultra Low Penetration Air Filter), and captures finer dust than the first filter 8. can do. Therefore, when the air passes through the second filter 10, fine dust that cannot be captured by the first filter 8 in the air is captured by the second filter 10. Thus, the air is completely cleaned by passing through the second filter 10.

The air that has passed through the second filter 10 continues to flow through the air flow path 15 toward the rear surface 13 of the housing 4.
Then, the air (exhaust gas) reaching the exhaust port 14 above the lowermost exhaust port 14A is exhausted from the exhaust port 14 above the lowermost exhaust port 14A toward the rear along the substantially horizontal direction. (See thick dashed arrows).

  On the other hand, the exhaust (see the thick white arrow) toward the lowest exhaust port 14A reaches the shutter 18. As a result, the shutter 18 that has been closed so far is pushed open by the wind pressure of the air that has reached the shutter 18 (see the thick white arrow), and rotates until it tilts rearward. As a result, the exhaust port 14A is opened rearward and the air reaching the shutter 18 is discharged from the exhaust port 14A upward (specifically, rear upper side) from the exhaust port 14A as indicated by a thick white arrow. .

  Thus, the air discharged from the lowest exhaust port 14A toward the rear upper side (see the thick white arrow) is discharged from the exhaust port 14 above the exhaust port 14A to the outside of the vehicle substantially horizontally. Collision from below (see thick dashed arrow). As a result, the air discharged from the exhaust port 14 above the exhaust port 14A and flowing out backward is corrected so that the flow direction is upward, and as a result, the air flows to the rear upper side as indicated by a thick white arrow. .

The discharge of the exhaust gas from the exhaust port 14 so as to flow upward is referred to as upward exhaust. The exhaust discharged from the exhaust port 14A toward the rear upper side is called an air curtain.
Since the air discharged from the air flow path 15 to the outside of the machine is exhausted upward, it is possible to prevent the dust on the floor surface X from rising when the air is bathed on the floor surface X.

  When the driving of the electric blower 9 is stopped after the cleaning of the floor surface X, the electric blower 9 does not generate a suction force, so that air does not flow in the air flow path 15, so that the air that pushes the shutter 18 open. The shutter 18 closes due to its own weight and closes the exhaust port 14A again (not shown). Thereby, when there is no need to blow out air from the exhaust port 14A, it is possible to prevent external dust from entering the housing 4 from the exhaust port 14A.

  Here, in this electric vacuum cleaner 1, in addition to the normal mode for cleaning the floor surface X, it is possible to operate in the air cleaning mode. The operation in the air cleaning mode is performed after the floor surface X is cleaned. In the air cleaning mode, for example, the electric blower 9 is driven in a state where the hose 3 is removed from the cleaner body 2. Thereby, indoor air is taken into the air flow path 15 from the air inlet 12, and dust contained in the air is completely removed by the first filter 8 and the second filter 10. Then, the air that has passed through the second filter 10 and has been completely purified is returned from the exhaust port 14 to the room. That is, the indoor air can be cleaned by the operation in the air cleaning mode.

Next, an electrolyzed water mist generating unit 30 that is provided in the cleaner body 2 and generates electrolyzed water mist described later will be described.
FIG. 3 is a rear view of the cleaner body 2 and shows a state in which the handle 32 is raised and the cover 32 is removed.
In relation to the electrolyzed water mist generating unit 30, as shown in FIG. 3, in the center portion in the width direction of the rear surface 13 of the housing 4, the portion above the uppermost exhaust port 14 has a front side (the back in FIG. A housing chamber 31 having a concave shape recessed toward the side) is formed. The storage chamber 31 is a substantially rectangular parallelepiped space that is long in the width direction (see also FIG. 2). The electrolyzed water mist generating unit 30 is accommodated in the accommodating chamber 31.

FIG. 4 is a rear view of the cleaner body 2.
As shown in FIG. 4, a cover 32 that covers the storage chamber 31 is detachably attached to the housing 4. The cover 32 is a part of the cleaner body 2. The cover 32 is formed by bending a thin plate into an L shape. When attached to the housing 4, the cover 32 extends to the rear side (front side in FIG. 3) and then bends to extend downward ( (See also FIG. 2). The rear side surface of the portion extending downward in the cover 32 is substantially flush with the rear surface 13 and is a part of the rear surface 13.

In the portion extending downward in the cover 32, a jet port 33 penetrating through this portion in the front-rear direction is formed at the approximate center in the vertical direction and the approximate center in the width direction. The jet nozzle 33 is round in the rear view. The part which divides the jet nozzle 33 in the cover 32 has comprised the substantially conical surface which becomes thick toward the back side, and is made into the guide surface 34 (refer also FIG. 2).
In a state where the cover 32 is attached to the housing 4, the jet outlet 33 is located at a position separated upward by a predetermined distance from the uppermost exhaust port 14.

Further, in this state, the storage chamber 31 communicates with the outside only through the ejection port 33.
Further, in this state, the rear end portion of the handle 7 in the tilted position is located directly above the cover 32.
Therefore, the cover 32 can be removed from the housing 4 by rotating the handle 7 to the upright position and moving it from above the cover 32 and then sliding the cover 32 upward (see FIG. 3). In this state, the storage chamber 31 is exposed rearward and upward (see FIG. 3).

In addition, the cover 32 can be attached to the housing | casing 4 by taking the procedure contrary to removal.
5A is a rear view of the electrolyzed water mist generating unit 30, FIG. 5B is a sectional view taken along the line AA in FIG. 5A, and FIG. It is -B arrow sectional drawing.
As shown in FIG. 5A, the electrolyzed water mist generating unit (hereinafter abbreviated as “generating unit”) 30 has a substantially L shape that is upside down in a rear view.

The generation unit 30 includes a main body 35, a cap 36, two electrodes 37, a water level sensor 38, an ultrasonic transducer unit 39, and a connection terminal 40 (see also FIG. 5B). .
The main body 35 is a portion that forms an outline of the generation unit 30 and has a substantially L shape that is upside down in a rear view. The main body 35 includes an electrolyzed water generating unit 41 that extends vertically, and a tank 42 that extends in a horizontal direction from a portion slightly above the vertical center of the electrolyzed water generating unit 41 (to the right in the rear view in FIG. 5A). Is integrated. Both the electrolyzed water generating unit 41 and the tank 42 are hollow bodies.

  With reference to FIG. 5B, two spaces of an electrolysis chamber 43 and a wiring chamber 44 are partitioned in the electrolyzed water generation unit 41. The electrolysis chamber 43 has a substantially rectangular parallelepiped shape, and is located above the electrolyzed water generation unit 41. The wiring chamber 44 extends upward from the lower end of the electrolyzed water generation unit 41, extends further upward while bypassing the electrolysis chamber 43 to the rear side (left side in FIG. 5B), and bends forward at the upper end portion. Yes. The upper end portion of the wiring chamber 44 is adjacent to the electrolysis chamber 43 from above.

An opening 45 communicating with the wiring chamber 44 from below is formed on the lower end surface of the electrolyzed water generating unit 41.
Referring to FIG. 5C, the cross section of the tank 42 has a substantially semicircular shape that bulges to the front side (right side in FIG. 5C). In response to this, the rear side wall 46 of the tank 42 extends flatly along a substantially vertical direction. Specifically, the rear side wall 46 is inclined approximately 15 ° with respect to the vertical direction and extends flatly toward the front upper side.

In the lower end portion of the rear side wall 46, an outflow hole 47 penetrating the rear side wall 46 in the front-rear direction is formed at a position slightly to the right of the center in the width direction in the rear view (see FIG. 5A).
A water supply port 48 communicating with the inside of the tank 42 is formed on the right end surface of the tank 42 in the rear view (see FIG. 5A).
The inside of such a tank 42 and the inside of the electrolysis chamber 43 (refer FIG.5 (b)) of the electrolyzed water production | generation part 41 are connecting. Water is stored in the tank 42 and the electrolysis chamber 43. Note that the electrolysis chamber 43 may be regarded as a part of the tank 42.

Referring to FIG. 5A, the cap 36 can be attached to and detached from the tank 42 of the main body 35, and closes the water supply port 48 when attached to the tank 42.
With reference to FIG. 5B, the two electrodes 37 are accommodated in the electrolysis chamber 43 of the electrolyzed water generation unit 41. These electrodes 37 are elongated in the vertical direction, and extend in parallel with a gap in the front-rear direction (left and right in FIG. 5B). The lower end of each electrode 37 is separated from the bottom of the electrolysis chamber 43.

The water level sensor 38 is elongated in the vertical direction, and the lower end thereof is located slightly below the center of the electrolytic chamber 43 in the vertical direction. The water level sensor 38 detects the water level in the electrolysis chamber 43.
With reference to FIG. 5A, the ultrasonic transducer unit 39 includes an ultrasonic transducer 49 and a support member 50 for attaching the ultrasonic transducer 49 to the tank 42.
The ultrasonic transducer 49 is a metal thin disk-shaped piezoelectric body having a front side surface 49A (one side surface) and a rear side surface 49B (the other side surface) (see also FIG. 5C). The diameter of the ultrasonic transducer 49 here is about 14 mm. A large number of through holes 51 are formed in the ultrasonic vibrator 49. Here, each through hole 51 is so small as to have a diameter of 10 μm or less. In FIG. 5A, for convenience of explanation, the through hole 51 is shown larger than the actual size.

With reference to FIG. 5C, the support member 50 includes a first ring member 52, a second ring member 53, and an attachment member 54.
The first ring member 52 and the second ring member 53 have an annular shape having substantially the same size. A portion that divides the hollow portion in the first ring member 52 forms a substantially conical surface that becomes thicker toward the rear side, and serves as a guide surface 56.

  The first ring member 52 and the second ring member 53 are overlapped so that the hollow portions thereof coincide with each other. In this state, the first ring member 52 is located on the rear side (left side in FIG. 5C) with respect to the second ring member 53. The ultrasonic transducer 49 is sandwiched between the first ring member 52 and the second ring member 53 that are in an overlapped state. In this state, in the ultrasonic transducer 49, the rear side surface 49B is exposed to the rear side from the hollow portion of the first ring member 52, and the front side surface 49A is exposed to the front side from the hollow portion of the second ring member 53. Has been.

  The mounting member 54 has an annular shape slightly larger in diameter than the first ring member 52 and the second ring member 53 and is externally fitted to the first ring member 52 and the second ring member 53 that are in an overlapped state from the rear side. Is fixed. The attachment member 54 is integrally provided with a protruding portion 55 that protrudes outward in the circumferential direction (see also FIG. 5A). The protruding portion 55 is attached to the tank 42 of the main body 35 with a screw (not shown) or the like, so that the ultrasonic transducer unit 39 is fixed to the main body 35 (tank 42) (see FIG. 5A as well). reference).

  In a state where the ultrasonic transducer unit 39 is fixed to the tank 42, the second ring member 53 is in contact with the rear side wall 46 of the tank 42 from the rear side. The hollow portion of the ring member 53 is in communication. At this time, the ultrasonic transducer 49, the first ring member 52, and the second ring member 53 extend to the front upper side along the rear side wall 46. Therefore, the inclination angle α of the ultrasonic transducer 49 (the front side surface 49A and the rear side surface 49B) with respect to the vertical direction is about 15 °.

In the ultrasonic transducer 49 in this state, the front side surface 49A faces the inside of the tank 42 through the outflow hole 47 and the hollow portion of the second ring member 53, while the rear side surface 49B is The exterior of the rear upper side is faced through the hollow portion of the first ring member 52.
With reference to FIG. 5B, the connection terminal 40 is accommodated in the lower end portion of the wiring chamber 44 of the electrolyzed water generation unit 41 and is exposed downward from the opening 45. The connection terminal 40 is electrically connected to the two electrodes 37, the water level sensor 38, and the ultrasonic transducer 49 (see FIG. 5C) via the lead wire 57.

  In the generation unit 30 as described above, first, the cap 36 is removed, and water is poured into the tank 42 of the main body 35 from the water supply port 48 (see FIG. 5A). The water in the tank 42 also reaches the electrolysis chamber 43 of the electrolyzed water generation unit 41. When the water supply port 48 is closed with the cap 36 after pouring a predetermined amount of water, water accumulates up to the same water level T in each of the tank 42 and the electrolysis chamber 43 (see also FIG. 5C). At this time, in the electrolysis chamber 43, the lower portions of the two electrodes 37 and the water level sensor 38 are immersed in water. Further, the front side surface 49A of the ultrasonic transducer 49 is immersed in water in the tank 42 (see FIG. 5C).

Here, in the production | generation unit 30, the sealing performance is ensured by using packing etc. FIG. For this reason, water in the electrolysis chamber 43 leaks into the wiring chamber 44, or water leaks from the joint between the rear side wall 46 of the tank 42 and the ultrasonic transducer unit 39, or the joint of each component in the ultrasonic transducer unit 39. There is nothing (see also FIG. 5 (c)).
Next, as shown in FIG. 3, after removing the cover 32 (see FIG. 4) from the housing 4 of the cleaner body 2 as described above, the generation unit 30 is attached to the housing 4 from above and accommodated. Housed in chamber 31 from above. When the generation unit 30 is completely attached to the housing 4, the connection terminal 40 (see FIG. 5B) is connected to a main body terminal (not shown) provided in the housing 4.

  Then, when the cover 32 is attached to the housing 4 (see FIG. 4), the generation unit 30 is covered from the outside by the cover 32 and is built in the cleaner body 2 as shown in FIG. In this state, the jet port 33 of the cover 32 faces the hollow portion of the first ring member 52 of the ultrasonic transducer unit 39 from the rear upper side. Thereby, the rear side surface 49 </ b> B of the ultrasonic transducer 49 is exposed from the rear surface 13 of the housing 4 (the vacuum cleaner main body 2) to the rear upper side through the ejection port 33. Also at this time, the inclination angle α (see FIG. 5C) of the ultrasonic transducer 49 with respect to the vertical direction is about 15 °.

In this state, the floor surface X is cleaned as described above. At that time, power is generated from the main body power supply (not shown) built in the vacuum cleaner main body 2 to the generation unit 30 via the main body terminal (not shown) and the connection terminal 40 (see FIG. 5B). Is supplied.
Here, with reference to FIG. 5B, in the generation unit 30, as described above, the pair of electrodes 37 in the electrolysis chamber 43 are immersed in water, and a voltage is applied to the pair of electrodes 37 via the lead wires 57. Is applied, the water in the electrolysis chamber 43 is electrolyzed to become electrolyzed water.

More specifically, a voltage is applied to the pair of electrodes 37 so that a predetermined current alternately flows so as to have opposite polarities to each other intermittently via the lead wire 57. The water inside is electrolyzed. As water, tap water is usually used, and tap water contains chlorine. Therefore, the following electrochemical reaction occurs by electrolysis.
(Anode side)
4H ₂ O-4e ⁻ → 4H ⁺ + O ₂ ↑ + 2H ₂ O
2Cl ⁻ → Cl ₂ + 2e ⁻
H ₂ O + Cl ₂ ⇔HClO + H ⁺ + Cl ⁻
(Cathode side)
4H ₂ O + 4e ⁻ → 2H ₂ ↑ + 4OH ⁻
(Between electrodes)
H ⁺ + OH ⁻ → H ₂ O
By the electrochemical reaction as described above, electrolyzed water containing hypochlorous acid (HClO) and active oxygen having a sterilizing effect and a deodorizing effect can be generated. By generating mist from the generated electrolyzed water as described later, electrolyzed water mist having a sterilizing effect and a deodorizing effect can be generated.

  And since the electrolysis chamber 43 and the inside of the tank 42 (refer FIG.5 (c)) are connecting, each water of the electrolysis chamber 43 and the tank 42 goes back and forth mutually. Then, when the cleaning of the floor surface X (see FIG. 2) is completed, the water inside the electrolysis chamber 43 and the tank 42 becomes electrolyzed water having a predetermined concentration. The front side surface 49A of the ultrasonic transducer 49 is immersed in the electrolyzed water in the tank 42 (see FIG. 5C).

  When the switch (not shown) provided in the cleaner body 2 is pushed after the cleaning of the floor surface X is completed, the electric blower 9 (see FIG. 2) is driven to enter the above-described air cleaning mode. In FIG. 5C, a voltage pulse is applied to the ultrasonic transducer 49, and the ultrasonic transducer 49 vibrates. As a result, the electrolyzed water in the vicinity of the through-hole 51 (see FIG. 5A) of the ultrasonic vibrator 49 is ultrasonically vibrated in the electrolyzed water in the tank 42, and electrolysis that is fine water particles from the through-hole 51. Water mist (hereinafter, sometimes simply referred to as “mist”) M is generated and is ejected to the rear upper side (obliquely upward) through the hollow portion of the first ring member 52.

  As shown in FIG. 2, the mist M ejected from the through hole 51 is ejected from the ejection port 33 of the cover 32 and diffused to the rear upper side. Here, the mist M is ejected from the ejection port 33 that is spaced upward from the exhaust port 14 from which the heat of the electric blower 9 is received and a relatively high temperature exhaust gas is discharged, so that the mist M is ejected from the ejection port 33. It is possible to suppress the sterilization effect of the mist M from being lowered by the heat of the exhaust gas at the stage. Further, by disposing the generating unit 30 separately from the exhaust port 14, it is possible to suppress the sterilization effect of the mist M from being reduced due to the influence of the exhaust temperature and the exhaust flow (turbulent flow).

The mist M about to be ejected in a direction different from the rear upper side is correctly ejected to the rear upper side (diagonally upward) by the guide surface 56 of the first ring member 52 and the guide surface 34 at the ejection port 33. In addition, the ejection direction is corrected.
The mist M diffused to the rear upper side rises to the upper limit, and then tries to descend to the lower rear side while drawing a parabola by its own weight. At that time, the mist M is scooped up from below by the air (see the thick white arrow) exhausted upward from the exhaust port 14 of the cleaner body 2 as described above. , Spread throughout the room. As a result, the virus or allele floating in the room is removed by the mist M so that the indoor space is sterilized and the room is deodorized by the mist M.

  Thus, since the exhaust port 14 has a configuration of exhausting upward (a configuration of exhausting the exhaust from the exhaust port 14 obliquely upward), the mist M once ejected obliquely upward from the ejection port 33 is self-weighted. When the mist M is lowered by the mist M, the mist M is again diffused obliquely upward by the exhaust gas cooled to such an extent that the sterilizing effect of the mist M is not lowered. Therefore, it is possible to disperse the mist M ejected from the ejection port 33 to the rear upper side so as to reach the corners of the room.

Originally, the ultrasonic vibrator 49 generates mist M from the electrolyzed water in the tank 42 and ejects it obliquely upward from the through hole 51 (see FIG. 5A). It is ejected diagonally upward, and the electrolyzed water mist can be blown as far as possible.
Further, since the mist M is ejected obliquely upward at the ejection port 33, the mist M is ejected from the ejection port 33 because it is kept away from the exhaust gas discharged obliquely upward at the exhaust port 14 below the ejection port 33. As a result, it is possible to prevent the sterilization effect of the mist M from being lowered by the heat of the exhaust.

As described above, in the cleaner body 2, the electrolyzed water can be effectively distributed indoors without reducing the sterilizing effect.
Here, an angle formed between the jet direction on the rear upper side (obliquely upward) of the mist M and the horizontal direction is β, and the discharge direction obliquely upward (see the thick white arrow) from the exhaust port 14 is defined between the horizontal direction and the horizontal direction. Assuming that the angle is γ, as described above, when the inclination angle α of the ultrasonic transducer 49 is about 15 ° (see FIG. 5C), β is less than γ (smaller than γ).

When the angle β is less than the angle γ, the mist M and the exhaust gas are always mixed, so that the mist M can be put on the exhaust gas and surely fly far and can be efficiently spread over a wide space.
Further, referring to FIG. 5C, the inclination angle α of the ultrasonic transducer 49 with respect to the vertical direction is about 15 °. As a result, when the electrolyzed water in the tank 42 passes through the through hole 51 (see FIG. 5A) of the ultrasonic vibrator 49, external air enters the tank 42 from the through hole 51 and becomes bubbles. However, the bubbles quickly move to the upper space Y of the tank 42 without adhering to the front side surface 49A of the ultrasonic transducer 49 and blocking the through hole 51. Thereby, it can prevent that the ejection of the mist M in the through-hole 51 of the ultrasonic transducer | vibrator 49 is prevented by the bubble.

Referring to FIG. 2, the ultrasonic vibrator 49 can generate mist M even when the cleaner body 2 is moved on the floor surface X.
Moreover, since the exhaust from the exhaust port 14 passes through the second filter 10 having a high dust capturing performance, it is very clean. Therefore, even if the mist M comes into contact with the exhaust, there is no problem that the sterilization performance of the mist M is lowered due to the reaction between the dust in the exhaust and the mist M.

Referring to FIG. 4, a vertically long display lamp 60 is provided on the rear surface 13 of the housing 4 at a position on the left side of the cover 32 in the rear view. When the mist M is released, the user may be notified that the mist M is released by turning on the display lamp 60.
Here, as the mist M is released, the electrolyzed water in the generation unit 30 decreases. Accordingly, when the water level T (see FIGS. 5B and 5C) of the tank 42 and the electrolysis chamber 43 is lowered to a predetermined water level, the water level sensor 38 (see FIG. 5B) detects it. . Then, the display lamp 60 may blink according to the detection result of the water level sensor 38 to notify the user that the generation unit 30 is to be replenished with water.

As shown in FIG. 3, when the cover 32 is removed from the housing 4 and the generation unit 30 is pulled up, the generation unit 30 is detached from the housing 4, and the tank 42 (see FIG. 5A) is removed from the water supply port 48 (see FIG. 5A). Water can be replenished as shown in FIG. Here, since the generation unit 30 is located at the upper end portion of the rear surface 13 in the housing 4, the generation unit 30 can be easily attached and detached.
And when cleaning the vacuum surface 1 after finishing the cleaning of the floor surface X and air cleaning, the cleaner main body 2 can change an attitude | position from the normal state mentioned above to the accommodation state shown in FIG. In the cleaner body 2 in the housed state, the rear surface 13 of the housing 4 faces the floor surface X from above. Thereby, the vacuum cleaner 1 can be stored compactly.

  In this state, the rear side surface 49B exposed from the rear surface 13 of the cleaner body 2 through the ejection port 33 in the ultrasonic vibrator 49 is opposed to the floor surface X from above while being inclined with respect to the horizontal direction. . Therefore, the electrolytic water in the tank 42 travels from the through hole 51 (see FIG. 5A) of the ultrasonic vibrator 49 to the rear side surface (lower side surface in FIG. 6) 49B (along the inclination of the rear side surface 49B). It is assumed that the surface X is spilled.

  Therefore, on the inner surface of the cover 32, a concave receiving portion 61 is provided at the tip of the rear side surface 49B of the ultrasonic vibrator 49 where water spills. In addition, a water supply member 62 made of sponge or the like is disposed in the receiving portion 61. Therefore, water spilled from the rear side surface 49B of the ultrasonic vibrator 49 is received by the receiving portion 61 and absorbed by the water supply member 62. Therefore, when the cleaner body 2 is in the stored state, the electrolyzed water is removed from the cleaner. It is possible to prevent the floor surface X from being spilled out of the main body 2 and getting wet. Here, the rear side surface 49B of the ultrasonic transducer 49 guides the water on the rear side surface 49B to the receiving portion 61.

  Further, on the rear surface 13 of the housing 4, a vertically long guard 63 protruding rearward is integrally provided at a position surrounding the cover 32 from the left and right (see FIG. 4). Therefore, when the vacuum cleaner main body 2 is stored and the rear surface 13 faces the floor surface X, the left and right guards 63 come into contact with the floor surface X to move the cover 32 away from the floor surface X. Can prevent the generation unit 30) covered by the cover 32 from being damaged.

The present invention is not limited to the embodiment described above, and various modifications can be made within the scope of the claims.
FIG. 7 is a diagram in which a modification is applied to FIG.
For example, as shown in FIG. 7, the aforementioned angle (an angle formed by the obliquely upward ejection direction of the mist M and the horizontal direction) β is an angle (an obliquely upward discharge direction of the exhaust from the exhaust port 14 and the horizontal direction). (An angle formed) γ or more is also conceivable. In this case, the inclination angle of the ultrasonic transducer 49 (the front side surface 49A and the rear side surface 49B) with respect to the vertical direction (the angle corresponding to α described above, see FIG. 5C) is about 60 °. Further, in the cover 32, the spout 33 is formed in a bent portion (upper rear corner) of the cover 32.

In this case, since the mist M that flows obliquely upward without descending can be separated from the exhaust (see the thick white arrow), the sterilization effect of the mist M can be prevented from being reduced by the exhaust.
In the above-described embodiment, the mist M is diffused indoors during the air cleaning mode. However, the mist M may be diffused indoors during the cleaning of the floor surface X (in the normal mode described above).

In the above-described embodiment, the ultrasonic transducer 49 is immersed in the electrolyzed water in the tank 42, but another configuration can be used.
As another configuration, the ultrasonic vibrator 49 is disposed at a position away from the surface of the electrolyzed water in the tank 42 so that the ultrasonic vibrator 49 does not directly contact the electrolyzed water. On the other hand, a hollow pipe extending from the ultrasonic vibrator 49 to the lower surface of the electrolyzed water is provided in the tank 42. The lower end of the pipe is immersed in the electrolyzed water in the tank 42. A part of the exhaust gas flows from above toward the surface of the electrolyzed water in the tank 42.

  In this case, during operation of the vacuum cleaner 1, a part of the exhaust gas flows into the tank 42 and pushes down the surface of the electrolyzed water while increasing the pressure in the tank 42, and accordingly, the electrolyzed water in the tank 42 is reduced. The pipe rises up to the ultrasonic transducer 49. Then, the electrolyzed water that has reached the ultrasonic vibrator 49 is ultrasonically vibrated by the ultrasonic vibrator 49 to become mist, and is diffused into the room.

DESCRIPTION OF SYMBOLS 1 Electric vacuum cleaner 2 Vacuum cleaner main body 9 Electric blower 13 Rear surface 14 Exhaust port 30 Electrolytic water mist production | generation unit 33 Spout outlet 37 Electrode 42 Tank 49 Ultrasonic vibrator 49A Front side surface 49B Rear side surface 51 Through-hole 61 Receiving part 62 Water absorption member X Floor α angle β angle γ angle

Claims (7)

A vacuum cleaner body provided with an exhaust port for discharging exhaust generated when the electric blower is built-in and the electric blower is driven;
An electrolyzed water mist outlet provided above the exhaust port;
An electrolyzed water mist generating unit that is built in the vacuum cleaner body and generates electrolyzed water mist in order to eject electrolyzed water mist from the ejection port;
With
The vacuum cleaner according to claim 1, wherein the exhaust port is configured to discharge exhaust gas from the exhaust port diagonally upward in order to dissipate the electrolytic water mist ejected from the jet port diagonally upward. The exhaust port and the jet port are provided on one side of the cleaner body,
The electrolyzed water mist generating unit is
A tank that can store water inside,
An electrode for electrolyzing the water in the tank into electrolyzed water;
The vacuum cleaner main body has a plate shape in which a large number of through holes are formed and is inclined at a predetermined angle with respect to the vertical direction, with one side faced into the tank and the other side faced through the spout. An ultrasonic transducer for generating an electrolyzed water mist from the electrolyzed water of the tank and ejecting it obliquely upward from the through hole;
The vacuum cleaner according to claim 1, comprising:   3. The electric vacuum cleaner according to claim 2, wherein an angle formed between the discharge direction of the electrolyzed water mist obliquely above and the horizontal direction is less than an angle formed between the discharge direction of the exhaust gas obliquely above and the horizontal direction. .   The electric vacuum cleaner according to claim 3, wherein an inclination angle of the ultrasonic transducer with respect to a vertical direction is about 15 °.   3. An electric vacuum cleaner according to claim 2, wherein an angle formed between a discharge direction of the electrolyzed water mist obliquely above and a horizontal direction is equal to or greater than an angle formed between the discharge direction of the exhaust gas obliquely above and a horizontal direction. .   The electric vacuum cleaner according to claim 5, wherein an inclination angle of the ultrasonic transducer with respect to a vertical direction is about 60 °. In the vacuum cleaner main body in the stored state, the one side surface is opposed to the floor surface from above,
A receiving portion that is provided in the vacuum cleaner main body and receives water that spills from the other side surface of the ultrasonic vibrator when the vacuum cleaner main body is in a stored state;
A water-absorbing member that is provided in the receiving portion and absorbs water received by the receiving portion;
The vacuum cleaner according to claim 2, wherein the vacuum cleaner is included.

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