JP3822839B2 - Suction washer and cleaning device equipped with the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a suction washer that injects a water stream onto a human or pet animal, and in particular, performs massage by locally sucking or rubbing the skin surface of the face or body with a water stream. The present invention relates to a suction cleaner and a cleaning device including the same.
[0002]
[Prior art]
2. Description of the Related Art In recent years, a suction washer has been researched and developed for jetting a water flow discharged from a nozzle port or the like onto a person or an animal to perform washing or massage.
For example, in Japanese Patent Application Laid-Open No. 08-196596 (hereinafter referred to as “a”), the water passage hole is arranged in the inner tangential direction on the closed side of one end inside the outer cylinder to which the water passage hole is attached. A swirl chamber for water flow having a pressurized fluid introduction hole through which pressurized fluid is supplied, an air intake port disposed at the rear end of the center position, and a water flow discharge port provided on the other end open side is installed. A central boss that is opened to face the water flow outlet, and a suction port that is open to the outside is installed on the other end of the central boss, and air is supplied to the opening of the central boss that faces the water flow outlet. A massage suction washer having a separation plate and a front swirl chamber formed between an outer cylinder and a central boss is disclosed.
In Japanese Utility Model Publication No. 63-74123 (hereinafter referred to as “B”), a liquid supply hole is provided in a tangential direction along the peripheral wall of the mixing chamber, and is disposed so as to protrude from the rear to the front of the mixing chamber. A suction massage bubble jet device is disclosed in which the discharge port of the air tube is positioned at the spray port of the mixing chamber and a plurality of protrusions are provided around the spray port.
[0003]
[Problems to be solved by the invention]
However, the above conventional technique has the following problems.
(1) The technology described in the Japanese Patent Publication (A) is directed to a front swivel formed between a central boss and an outer cylinder, in which a central boss provided with a gas-liquid separation plate is disposed facing the water flow outlet of the swirl chamber. Since the flow-through plate is provided in the chamber, the gas-liquid separation plate or flow-through plate becomes an obstacle, and the suction force by the swirl flow cannot be effectively exhibited. For this reason, there is a problem that the suction force of the swirl chamber is insufficient, and it is difficult to suck and remove dirt such as fat collected in pores or the like in the vicinity of the suction port close to the skin. It was.
(2) Since the gas sucked in from the air intake collides with the steam-water separator plate or the flow-through plate and is disturbed, it is difficult to generate fine and uniform bubbles in the water flow. There has been a problem that a cleaning effect for removing bubbles by causing bubbles to act on the contaminated portion and a massage effect due to stimulation by collision of fine bubbles against the skin surface cannot be obtained.
(3) Since there is no mechanism for adjusting and controlling the amount, size, form, etc. of bubbles in the discharged water flow, it contains fine bubbles with excellent cleaning ability and massage ability according to the conditions of use. There was a problem that the water flow could not be obtained.
(4) Since the air / water separation plate, the flow-through plate, the central boss and the like are incorporated in the interior, the structure is complicated and the maintenance performance is poor and the productivity is insufficient.
(5) In the technique described in the gazette, since the air discharge port of the air pipe is disposed in the immediate vicinity of the injection port of the mixing chamber, the water flow in the swirling state in the mixing chamber and the air may be in direct contact with each other. In addition, the swirling water flow and the air cannot be effectively brought into contact with each other while maintaining a predetermined contact area to generate fine bubbles having a predetermined size and form, and the massage effect and the cleaning effect are not sufficient. Had.
(6) Although the central portion of the mixing chamber becomes a low pressure due to the swirling liquid, a gap is formed between the spray port and the skin surface by the protrusion provided around the spray port, so the swirling flow is on the skin surface. Disturbed nearby, the low-pressure part is extremely difficult to form, and near the skin, the suction force is small, so it is difficult to suck and clean dirt such as fat accumulated in pores etc. Had.
(7) Since there is no means to control the size and generation amount of fine bubbles formed in the water flow, more air than the necessary amount is sucked from the air pipe, and large bubbles are formed, and sufficient massage effect and washing There was a problem that the effect could not be obtained.
(8) Since a space is formed between the human body and the injection hole by the protrusion provided around the injection port, the suction force is insufficient and the skin surface of the human body is sufficiently sucked to give a massage effect. It had the problem that it was not possible.
(9) Since the guide part for appropriately adjusting the discharge state of the water flow to be ejected is not provided, it is difficult to effectively cause the water flow containing fine bubbles to act on the skin surface. It was.
[0004]
The present invention solves the above-mentioned conventional problems, can form a swirling flow close to the skin surface and give a strong suction force, and maintain the state of the water flow including fine bubbles in the water flow properly for cleaning. It aims at providing the washing | cleaning apparatus excellent in productivity and maintenance property with simple structure while providing the suction washer excellent in the effect and the massage effect.
[0005]
[Means for Solving the Problems]
In order to solve the above-described problems, a suction cleaner and a cleaning device including the same according to the present invention have the following configurations.
[0006]
  The suction cleaner according to claim 1 of the present invention comprises: a. A container having a hollow portion converging from the rear side toward the front side; b. A gas-liquid ejection hole provided at the front end of the vessel, c. A liquid introduction pipe connected tangentially to the peripheral wall on the rear side of the vessel body; d. A gas-liquid ejection guide portion disposed on an outer peripheral portion of the gas-liquid ejection hole and expanded from the gas-liquid ejection hole in the ejection direction.A gas outlet part formed by opening a hole on the front side of the gas / liquid ejection guide part, or provided at the front edge of the gas / liquid ejection guide partConfigured.
  With this configuration, the following effects can be obtained.
(1) A liquid introduction pipe of a suction cleaning device is connected to a water supply port such as a water supply or a discharge outlet side of a pump, etc., and the liquid is allowed to flow from the liquid introduction tube into the hollow portion of the vessel body from the tangential direction of the peripheral wall. it can. The liquid that has flowed into the hollow portion moves toward the gas-liquid ejection hole while turning along the peripheral wall surface converged toward the front side of the hollow portion, and can be ejected from the gas-liquid ejection hole. The liquid flow (water flow) collides with the skin surface or the like disposed on the entire surface of the gas-liquid ejection guide part while turning along the inner wall surface of the gas-liquid ejection guide part connected to the gas-liquid ejection hole. The center part of the swirling flow becomes a low pressure by the swirling motion, and the skin surface and the like can be cleaned and massaged.
(2) By bringing the edge of the gas-liquid jet guide part into contact with the skin surface to be cleaned or massaged, the skin surface is sucked from the front of the gas-liquid jet guide part decompressed by the swirling flow, and the massage effect is obtained. can get. Further, when air or the like is mixed in the liquid supplied to the liquid introduction hole in advance, a gas shaft made of mixed air is formed in the hollow portion at the center of the vessel body, and the tip and periphery of the gas shaft are formed. The part is diffused as fine bubbles in the water flow due to the shearing force of the water flow suction force, and flows out from the gap between the skin surface and the edge of the gas-liquid ejection guide part together with the water flow through the skin surface to clean the skin surface Can be performed more effectively.
(3) Since the gas-liquid jet guide portion can maintain the swirling flow of the gas-liquid mixed fluid up to the edge of the gas-liquid jet guide portion where the water flow contacts the skin surface, The skin surface can be effectively sucked in a wide range, and a high massage effect can be obtained.
(4) Since the suction washer has no obstacle to the water flow in the inside thereof, desired fine bubbles can be generated very efficiently.
(5) Since the structure is simple and the number of parts is small, the productivity is excellent and the maintenance is excellent.
(6) When using the gas-liquid jet guide part away from the skin surface, the suction cleaner can be used effectively as a shower without restricting the diffusion of the water flow jetted by the air-flow jet guide part.
(7) When the front edge of the gas-liquid ejection guide part is ejected against the skin surface, the swirling liquid hitting the skin is closer to the gas axis of the central negative pressure part than the outflow part side. Invert to. The reversed negative pressure portion and the central negative pressure skin can be sucked in a wide range.
(8) Even if the front end of the gas-liquid jet guide part is strongly pressed against the skin surface, the swirling flow can be made to flow out of the gas-liquid jet guide part from the outflow part. It can flow.
(9) Since a plurality of outflow portions can be provided with respect to the gas-liquid ejection guide portion, it is possible to effectively generate a swirl flow or to increase the massage effect by complicating the flow.
[0007]
  Here, as the shape of the vessel, a shell shape, a truncated cone shape, a hemispherical shape, a shape in which a rear wall is bulged (for example, a spherical shape), or the like is used. When the shape in which the rear wall is bulged is used, a part of the liquid that has flowed into the container from the liquid introduction pipe moves to the rear wall side and then reverses, turning around the gas axis Since it moves to the jet hole side, it is possible to make a jet flow with straightness. Further, in contrast to the case where the rear wall is bulged, it can be formed in a recessed shape in the hollow portion, whereby the movement of the water flow in the hollow portion can be changed.
  As the shape of the gas-liquid ejection guide portion, a truncated cone shape, a hemispherical shape, a dish shape, or the like is used.This stabilizes the ejection state of the gas-liquid mixed fluid and also allows the gas-liquid mixed fluid to be ejected. It can be applied to the skin surface efficiently.
  The gas-liquid ejection hole is a constricted portion where the vessel converges from the rear side toward the front side, and varies depending on the size of the vessel, the flow rate of liquid supplied to the vessel, pressure, etc. The diameter d is preferably 1/15 to 1/3 times, preferably about 1/10 to 1/5 times the maximum inner diameter D of the vessel. This is because as the diameter d of the gas-liquid ejection hole is made smaller than 1/10 times the maximum inner diameter D of the body, it is difficult to ensure the liquid discharge flow rate necessary for effectively cleaning and massaging the skin surface. On the contrary, as it exceeds 1/5 times, a swirl flow of liquid cannot be formed in the body, and a tendency of insufficient suction force appears. These trends are 1/15 times. If it becomes smaller or exceeds 1/3 times, it becomes more remarkable, which is not preferable.
  The liquid introduction tube is attached to the peripheral wall of the container whose discharge portion is formed in a substantially cylindrical shape, in a tangential direction with respect to the peripheral wall surface. Accordingly, a swirling flow can be generated in the vessel body by connecting a supply port such as a pump or water supply to the liquid introduction pipe and flowing pressurized water.
  The flow rate of liquid flowing into the container, the diameter of the liquid introduction pipe, the volume of the container, the diameter of the gas self-priming holes, etc. are the required suction force, the flow speed of the swirling flow, and the amount of fine bubbles generated in the water flow. It is appropriately selected depending on the form such as particle size.
  The outflow part is an opening or notch that penetrates the front and back surfaces of the gas-liquid ejection guide part and is formed in a rectangular or circular shape, and part of the water flow introduced into the gas-liquid ejection guide part The flow state in the gas-liquid ejection guide portion can be adjusted by the arrangement pattern, the opening area thereof, and the like.
[0008]
  The suction washer according to claim 2 is the invention according to claim 1, wherein the body axis or the body is provided on the rear wall of the body.The tip of the water flow is formed in the center of the swirl flow and the tip extends toward the gas-liquid jet hole to form a rod-like air.It has a gas self-priming hole formed to open at a position eccentric from the gas axis.
  With this configuration, in addition to the operation of the first aspect, the following operation can be obtained.
(1) The gas shaft formed in the central part of the container body generates fine bubbles due to the shearing force of the water flow at the rod-shaped tip and periphery, and the skin surface and the gas-liquid ejection guide part together with the water flow connecting the skin surface. The skin surface can be washed out from the gap with the edge.
(2) Fine bubbles are mixed in the swirling flow that collides with the skin surface, and the fine bubbles adhere to the skin surface and burst, thereby stimulating and activating the skin surface and obtaining a high massage effect. it can.
(3) Since the gas can be directly sucked into the hollow portion from the gas self-priming hole, it can be easily used without using a pump or the like by connecting it to a water supply port or the like.
(4) By including fine bubbles in the water stream, the fine bubbles can be made to reach near the hair root. The fine bubbles are brought into impact contact with the skin surface, and this frictional action and action at the time of bursting of the fine bubbles. Can clean the oxidized sebum and old keratin on the skin surface.
(5) Due to the swirling motion of the water flow in the container, a low pressure part is formed at the center of the swirling flow, that is, the axial center of the container, and air is sucked from the gas self-priming hole toward the low pressure part, A gas shaft extending in a rod shape toward the center is formed in the vessel. At this time, by arranging the gas self-priming hole at a position deviated from the body axis, the tip of the gas axis can be vibrated to generate fine bubbles more effectively. By adjusting the amount of eccentricity, the shape and size of the gas shaft can be subtly changed to obtain a water flow containing predetermined fine bubbles with optimized cleaning and massage effects.
[0009]
The flow rate of the liquid flowing into the container, the diameter of the liquid introduction pipe, the volume of the container, the diameter of the gas self-priming hole, etc. are appropriately selected according to the form of the suction force by the water flow, the amount of fine bubbles, the particle size, etc. . That is, when the opening diameter of the gas self-priming hole is increased, the amount of gas sucked from the gas self-priming hole is large, and the force for sucking the skin surface is reduced. The amount of gas sucked from the skin is small, and the force for sucking the skin surface is increased.
The diameter of the gas self-priming hole varies depending on the pressure of water supplied from the liquid introduction pipe, the flow rate, the size and shape of the vessel, but is 0.01 to 0.5 mm, preferably 0.03 to 0.3 mm. A range of 1 mm is desirable. This is because the amount of air that can be supplied into the vessel tends to be insufficient as the diameter of the gas self-priming holes becomes smaller than 0.03 mm, and conversely, the diameter of the bubbles that diffuse into the water flow increases as the diameter exceeds 0.1 mm. There is a tendency that the cleaning effect and the massage effect due to fine bubbles are impaired, particularly when the inner diameter is 40 to 60 mm, the axial length is 40 to 60 mm, and the diameter of the gas-liquid ejection hole is less than 0.01 mm. This is because these tendencies become more prominent when it becomes larger than 0.5 mm.
[0010]
  The suction washer according to claim 3 is attached to the invention according to claim 2 by being screwed or fitted to a screw part or a fitting part formed to open in the rear wall of the container body,SaidFormed in the body axis or in the bodySaidA rotating member is provided so as to be rotatable about a position eccentric from the gas axis, and the gas self-priming hole is formed at a position eccentric from the rotating axis of the rotating member. .
  With this configuration, in addition to the operation of the second aspect, the following operation can be obtained.
(1) The rotating member is provided on the rear wall of the container so as to be rotatable around the position eccentric from the central axis of the container, and the gas self-priming hole is eccentric from the rotational axis of the rotating member. Since it is formed, by rotating or rotating the rotating member, it is possible to adjust the area of the portion where the cross section projected onto the rear wall of the gas shaft formed in the body and the gas self-priming hole overlap. it can. By adjusting the area of the overlapping portion to increase or decrease, the suction resistance of the gas self-priming holes can be changed to adjust the amount of gas sucked from the gas self-priming holes.
(2) When liquid is supplied in the tangential direction of the container body from the liquid introduction hole of the container body, a swirling flow is formed, the central part of the container body is decompressed, and gas is released from the gas self-priming holes arranged on the rear wall of the container body. Is sucked. In this way, a gas shaft made of the sucked air can be formed at the center of the body. The form of this gas shaft also changes depending on the pressure, flow rate, temperature, etc. of the water supplied from the liquid introduction pipe, but by rotating the rotating member at a predetermined angle, the gas axis itself and the central axis of the vessel 2 It can be adjusted by changing the relative position to the suction hole 5.
(3) Since the amount of gas sucked into the hollow portion can be adjusted by rotating the rotating member, the amount of fine bubbles ejected, the suction force on the skin surface, etc., can be changed subtly. Excellent in properties.
  Here, the rotation member is a lid-like member that is covered with the rear wall of the container body through a screw part or a fitting part, and a rotation shaft provided on the rear wall of the container body. Can be rotated at a predetermined angle.
  The position of the rotation shaft of the rotation member is preferably set at a position that is decentered in a range of 1 to 10% of the body radius with respect to the body axis or the gas axis formed in the body. . This depends on the diameter of the gas self-priming hole to be applied and the size of the container, but if the amount of eccentricity is less than 1%, the amount of air sucked from the gas self-priming hole by adjusting the rotation angle of the rotating member. On the contrary, if it exceeds 10%, the space for rotating the rotating member on the rear wall of the container body is reduced, and it becomes difficult to perform a predetermined rotating operation. Appears, which is not preferable.
  The gas axis is a gas gathering part formed in the central part of the vessel by the swirling water flow in the vessel, and the shape of the vessel formed in the position of the liquid introduction pipe, the ellipse, etc., and the gas-liquid ejection The position where the hole is formed may vary depending on the position of the hole.
[0011]
A suction cleaner according to claim 4 is the invention according to claim 2 or 3, wherein gas is supplied through the gas self-suction hole, which is covered with the rear wall of the container or the rotating member. It has a tank part and a gas introduction hole provided in the tank part.
According to this configuration, in addition to the operation of the second or third aspect, the following operation can be obtained.
(1) Since the tank portion is provided, the outside air does not flow directly from the gas self-suction holes, and the suction resistance of the sucked air can be increased, so the diameter of the gas self-suction holes is increased. Even if a large amount of gas is not sucked in, the gas-liquid jet guide part can maintain the force of sucking the skin surface, and a high massage effect can be obtained.
(2) Since the external pressure fluctuation is eased by providing a tank with a large capacity, the control of the size, form, amount, etc. of the fine bubbles generated in the water flow can be stabilized and facilitated, and the operability is improved. Excellent.
(3) Since the diameter of the gas self-priming hole can be increased, it is difficult to cause malfunction due to clogging with dust or scale, and the maintenance is excellent.
Here, a cylindrical shape, a hemispherical shape, or the like is used as the shape of the tank portion.
The size and quantity of the tank holes are appropriately selected according to the required suction force, the speed of the swirling flow, the quantity and the particle size of the fine bubbles.
[0012]
According to a fifth aspect of the present invention, in the first aspect of the present invention, the distal end side of the container body is reduced in diameter from the rear wall side of the container body, and the distal end opening is disposed inside the gas-liquid ejection hole. A water flow jet nozzle portion, a plug-like, conical or inverted conical water flow adjusting member disposed in the vicinity of the nozzle tip via a rod-like support member inserted into the water jet nozzle portion, and the support member And a position adjustment fixing portion provided on the rear wall side of the container body that supports the base end side of the container body so that the base end side can be moved forward and backward.
With this configuration, in addition to the operation of the first aspect, the following operation is provided.
(1) A part of tap water or hot water supplied from the liquid introduction pipe or tap water or hot water supplied from a separate pipe is supplied near the inside of the gas-liquid jet hole through the water jet nozzle. It can be ejected directly in a high state, and it has excellent cleaning and massage properties.
(2) Since the water flow adjusting member is provided inside the tip of the water jet nozzle part, the water flow jetting angle and the gas-liquid dispersion state are properly maintained by advancing and retreating the member and fixing it at a predetermined position. be able to. For example, when the water flow adjusting portion is formed in an inverted conical shape whose diameter is enlarged, the water flow is jetted in a reverse 8-shaped direction toward the nozzle outlet, so this water flow is converted into a cone of the water jet nozzle portion. It can be combined with the swirl flow that swirls and converges from the outer periphery of the shape. Therefore, both jetting forces can be suppressed and ejected in the form of large water droplets, or both can be synergized and ejected in the form of fine water droplets, which can be adjusted according to the conditions of cleaning and massage.
(3) Especially when the water supplied to the flow jet nozzle is heated to warm water, the dissolved amount of gas that can be dissolved in water decreases according to Henry's law, resulting in a supersaturated state. By passing it through the pressure part (low pressure part), a large amount of dissolved gas can be released, thereby obtaining a cleaning liquid or a massage liquid containing a large amount of fine bubbles.
Here, the water jet nozzle part is installed with the tip side inserted from the rear wall side of the container, and tap water and hot water are supplied at a predetermined flow rate via a branch pipe branched from the liquid introduction pipe and another piping system. It has become so. The flow rate ratio (A / B) between the flow rate A supplied from the water jet nozzle and the flow rate B supplied from the liquid introduction pipe connected to the vessel wall to form a swirling flow is 0.1 to 0.8. Preferably, it is desired to be in the range of 0.2 to 0.5. This depends on the amount of dissolved gas in tap water and its temperature, but as the flow rate ratio (A / B) becomes smaller than 0.2, the flow rate directly supplied to the skin surface decreases, The tendency of the pressure massage effect to worsen appears, and conversely, as it exceeds 0.5, the tendency of the friction massage effect due to the swirling flow to appear decreases. When these tendencies are less than 0.1 or exceed 0.8 This is because it becomes more prominent.
The tip of the water flow adjusting member is formed in an inverted conical shape, etc., and the tip position is moved forward and backward to a predetermined position, or fixed, thereby defining the distance from the nozzle tip and cleaning discharged from the gas-liquid ejection hole Subtle adjustments such as the flow rate of water and the like, the ejection angle, and the foaming state can be made.
[0013]
A suction cleaner according to a sixth aspect of the present invention provides the suction cleaning device according to any one of the first to fifth aspects, wherein the inclined portion expands at a predetermined angle toward the ejection side on the inner peripheral wall of the gas-liquid ejection hole. And a flat portion formed to be connected in front of the inclined portion.
According to this configuration, in addition to the operation of any one of claims 1 to 5, the following operation can be obtained.
(1) Since the inner wall of the gas-liquid jet hole has an inclined portion that expands at a predetermined angle toward the jet side, the range in which the water flow including the microbubbles and the bubble nuclei before becoming microbubbles diffuses The inside of the water flow can be depressurized only within a predetermined angle, and this partial depressurization can effectively promote the growth from bubble nuclei to fine bubbles.
(2) When used as a shower, it has a flat portion formed in front of the inclined portion, so that water droplets ejected at the flat portion can be prepared and contains a large amount of fine bubbles. Water droplets can be supplied stably, and the water droplets can be concentrated at the center in the ejection direction.
(3) The angle θ in the inclined portion, the length A in the ejection direction, and the length B in the ejection direction in the flat portion are adjusted in combination depending on the water quality, pressure, flow rate, temperature, and the like of the supplied water. Thus, the size of the fine bubbles to be diffused in the water flow, the aggregate form of the bubbles, and the like can be slightly changed. Since the cleaning effect and the massage effect due to the fine bubbles vary depending on factors such as the form of the fine bubbles, a combination (θ, A, B) of values optimized for these can be set based on experiments.
[0014]
Here, the angle θ of the inclined portion varies depending on the size of the vessel used, the flow rate and pressure of the water to be supplied, and the lengths A and B, but it should be in the range of 50 to 120 degrees, preferably 73 to 79 degrees. Is desirable. This is because as the angle θ of the inclined portion becomes smaller than 73 degrees, the distance to the skin surface tends to increase and the suction force tends to decrease. Conversely, as the angle exceeds 79 degrees, the water flow spreads over a wide area and the ejection direction is changed. This is because the tendency to be unable to concentrate on the central part becomes stronger. Further, these tendencies are not preferable because the angle θ of the inclined portion becomes smaller than 50 degrees or exceeds 120 degrees, since it becomes more remarkable.
The lengths A and B in the ejection direction in the inclined part and the flat part are preferably in the range of 0.5 to 1.2 times the diameter d of the smallest diameter part of the gas-liquid ejection hole. This is because if the lengths A and B of the inclined portion and the flat portion are smaller than 0.5 times the diameter d of the minimum diameter portion, the effect of suppressing the direction of water flow is reduced, and if it exceeds 1.2 times, the suction force is reduced. Because it falls.
That is, when the suction washer is used as a shower, the water droplets ejected from the gas-liquid ejection holes are ejected in a swirling state, so that the central portion of the water flow tends to be hollowed. By providing the flat portion and the inclined portion set to the height, the water droplets to be ejected can be concentrated on the central portion, so that the water droplets can be applied to the skin surface in an averaged state.
[0016]
  Claim 7The suction washer described inClaims 1 to 6In any one of these, it is comprised including the scattering prevention part provided in the front side edge part of the said gas-liquid ejection guide part toward the back.
  With this configuration,Claims 1 to 6In addition to the action of any one of the following, the following action is obtained.
(1) Since the liquid flowing out from the outflow part moves to the rear side opposite to the skin surface side, it is possible to prevent the water flow from splashing on the face or the like.
(2) When a liquid recovery pipe is attached to the splash prevention part, it can be used without polluting the bathroom or washroom.
  Here, the scattering prevention part is a wall-like part provided to protrude rearward along the peripheral edge of the gas-liquid ejection guide part, and thereby the liquid that has flowed out from the outflow part opened in the gas-liquid ejection guide part It has the function which guide | induces to the back side rather than the front-end part of a gas-liquid ejection guide part.
[0017]
  Claim 8The suction washer described inClaim 1In the invention described in (1), a water flow recovery unit that recovers the water flow discharged from the outflow part of the gas-liquid jet guide part is provided.
  With this configuration,Claim 1In addition to the functions described in (1), the following functions are provided.
(1) Since the water flow recovery unit is provided, the washing water or the like is not greatly scattered around, so that the surroundings can be prevented from being soiled and is hygienic.
(2) Since a gas-liquid jet guide part is brought into contact with the skin surface to form a sealed system through which water flows when hot water is jetted, the pressure on the skin surface due to the jet flow is increased, and a good cleaning effect is achieved. A massage effect is obtained.
[0018]
  Claim 9The suction washer described inClaim 8The base end of the gas-liquid jet guide part is pivotally disposed via a hinge, and the substantially hemispherical peripheral part shields the outflow part of the gas-liquid jet guide part. The spill control part which comprises is comprised.
  With this configuration,Claim 8In addition to the above actions, it has the following actions.
(1) Since the outflow restricting portion is rotatably provided at the peripheral portion of the gas-liquid ejection guide portion, the outflow portion communicating with the water flow collecting portion is shielded depending on the use situation such as a bathroom or a washroom. It can be used in the open state. As a result, it can be used as a shower in which fine bubbles are mixed by fitting the outflow regulating part to the gas-liquid jet guide part, or it can be used as a suction washer in an open state, which is excellent in operability and versatility. ing.
(2) Since the outflow restricting portion is attached via a hinge, the outflow restricting portion can be stored compactly in a state where the outflow restricting portion is fitted to the gas-liquid jet guide portion, and it is convenient without fear of disappearing.
(3) When fitted to the gas-liquid ejection guide part and used as a carry, the tip of the gas shaft formed inside the suction washer hits the negative pressure application plate arranged in the center of the outflow restricting part. The external gas is not sucked, and a shower containing fine bubbles can be obtained.
  The spill regulation department. It is formed in a substantially hemispherical shape with plastic or the like, a negative pressure application plate is formed at the front center thereof, and the rear center is opened so as to communicate with the gas-liquid ejection hole when mounted on the gas-liquid ejection guide part. .
[0019]
  Claim 10The cleaning device described inClaims 1 to 9And a pump for supplying a cleaning liquid to the liquid introduction pipe of the suction cleaner.
  With this configuration, the following effects can be obtained.
(1) The cleaning device can be configured only with a suction cleaner and pump having a simple structure, and the number of parts can be reduced.
(2) Since the liquid is merely sent to the suction washer by the pump, the cleaning device can be easily installed and used not only indoors but also outdoors such as campsites.
(3) When gas is mixed in the liquid supplied to the pump in advance, the bubbles in the gas-liquid mixed fluid are diffused by the impeller rotating in the pump, so that finer bubbles can be generated.
  Here, as a pump, a centrifugal pump of a type that rotates an impeller (impeller) in a container having a suction pipe and a discharge pipe, a turbo pump such as an axial flow pump, a mixed flow pump, etc., or a space volume is changed periodically. A positive displacement pump such as a reciprocating pump, a vane pump, a gear pump or the like that performs the suction and discharge of liquid can be applied. Also, the impeller mounted on the outer periphery of the disk is rotated at high speed to allow the liquid sandwiched between the outer casing and the outer periphery of the impeller to flow on the periphery by the rotation of the impeller, and the suction port A centrifugal pump that moves from the nozzle to the discharge port, or a jet that sucks water from the lower pipe using high-pressure water ejected from a small nozzle hole at high speed and the pressure at the nozzle outlet dropping to a vacuum state A special pump such as a pump or a bubble pump that blows compressed air into the lower end of a pumping pipe inserted into water and moves it upward along with the water by raising the bubbles can also be applied.
[0020]
  Claim 11The cleaning device described inClaim 10The pump gas self-suction hole for sucking gas is provided in the suction pipe for supplying the cleaning liquid attached to the suction side of the pump.
  With this configuration,Claim 10In addition to the above action, the following action is obtained.
(1) Since a pump gas self-priming hole for sucking gas is provided in the suction pipe of the pump that supplies the cleaning liquid, it is not necessary to suck the gas on the suction cleaner side, and a predetermined amount of gas can be stabilized. It is easy to supply to the battery and is excellent in operability and convenience.
(2) Since the control of the mixing ratio between the gas and the liquid in the gas-liquid mixed fluid can be easily performed, an appropriate cleaning state can be maintained according to the use situation.
(3) It is easy to keep the state of the gas-liquid mixed fluid in use constant and excellent in stability in operation.
  Here, the pump gas self-priming hole is a branch pipe that is branched and attached to the suction pipe of the pump and has a diameter smaller than the diameter of the suction pipe. The suction amount can be adjusted via a valve, a needle valve, or the like. Through this pump gas self-priming hole, ambient air or the like can be sucked and mixed into the water flow by the ejector effect of the water flow flowing through the suction pipe.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
(Embodiment 1)
The suction cleaner according to Embodiment 1 of the present invention will be described with reference to the drawings.
1 (a) is a perspective view of a main part of the suction cleaner in Embodiment 1, FIG. 1 (b) is a side sectional view of the main part, and FIG. 2 (a) is a front view of the main part. FIG. 2B is a rear view of the main part.
1 and 2, 1 is a suction cleaner in the first embodiment, 2 is a container formed of a synthetic resin or the like having a bullet-shaped hollow portion 2 a that converges from the rear side toward the front side, 3 is a gas-liquid jet hole formed at the front end of the central axis of the vessel body 2, 4 is a liquid introduction pipe tangentially connected to the peripheral wall on the rear side of the vessel body 5, 5 is on the rear wall of the vessel body 2 A gas self-suction hole 6, which is disposed and is formed at a position eccentric from the center position of the rear wall, 6 is disposed around the gas-liquid ejection hole 3 and is expanded from the gas-liquid ejection hole 3 toward the ejection direction. The formed umbrella-shaped gas-liquid ejection guide part 7 is a plurality of outflow parts perforated on the front side of the gas-liquid ejection guide part 6.
In the first embodiment, the outflow part 7 is formed by opening a hole on the front side of the gas-liquid ejection guide part 6, but is formed by notching the front end part of the gas-liquid ejection guide part 6. It may be a notch.
[0022]
The operation of the suction cleaner in the first embodiment configured as described above will be described with reference to the drawings.
FIG. 3 is a side sectional view of an essential part showing a use state of the suction cleaner in the first embodiment.
In FIG. 3, 1 is a suction cleaner in the first embodiment, 2 is a container, 2a is a hollow portion, 3 is a gas / liquid ejection hole, 4 is a liquid introduction pipe, 5 is a gas self-priming hole, and 6 is a gas / liquid ejection. The guide part 7 is an outflow part, and these are the same as those shown in FIGS.
H is the skin surface of the user of the suction cleaner 1, W is air sucked into the hollow portion 2 a from the gas self-priming hole 5, and the tip extends toward the gas-liquid ejection hole 3 and is formed in a rod shape. Gas shaft (low pressure part).
The form of the gas shaft W formed in the vessel body 2 varies depending on the pressure, flow rate, temperature, etc. of the water supplied from the liquid introduction pipe 4, but the size of the opening of the gas self-priming hole 5 and the vessel body It can be greatly varied depending on the relationship between the central axis of the gas 2 and the position where the gas self-priming holes 5 are arranged.
In the first embodiment, the gas self-priming hole 5 has an opening diameter of about 0.01 to 0.1 mm, and is decentered by about 1 to 5 mm from the center position of the rear wall of the container body 2 (center axis of the container body). The gas self-priming holes 5 are arranged at the positions so that the gas shaft is formed in the hollow portion 2a.
Further, the form and size of the gas shaft can be slightly changed by the amount of eccentricity, and a water flow containing predetermined fine bubbles that can optimize the cleaning effect and the massage effect can be obtained.
First, the liquid introduction tube 4 of the suction cleaner 1 is connected to the water supply port of the home, the discharge port side of the pump, etc. via a hose, etc. Let it flow. Thus, the liquid flowing into the hollow portion 2a turns along the wall surface of the hollow portion 2a and becomes a gas-liquid mixed fluid while sucking air from the gas self-priming holes 5 and from the gas-liquid jet holes 3 to the gas-liquid jet guide. Move to part 6. This gas-liquid mixed liquid collides with the skin surface H while turning along the inner wall surface of the gas-liquid jet guide part 6 and flows out of the suction washer 1 from the outflow part 7.
At this time, centrifugal force is exerted on the liquid due to the swirling motion, and the central portion of the swirling flow becomes negative pressure (low pressure). Is formed, and the skin surface H on the front side of the gas-liquid jet guide portion 6 is sucked.
Since the tip of the gas shaft W is eccentric to the position of the gas self-priming hole 5, it is torn off by shearing in front of the skin surface H while turning, and diffuses into the swirling water stream as fine bubbles.
In this way, the water flow containing fine bubbles passes through the skin surface H, reverses in the direction of the gas axis W at the edge of the gas-liquid jet guide portion 6, further reverses around the gas axis W, and flows out from the outflow portion 7 to the outside. By effectively performing such a reversal motion of the water flow, the generation of fine bubbles in the liquid can be promoted, and the skin surface H can be suction-washed strongly and continuously in a wide range.
In addition, due to the interaction between the fine bubbles contained in the water flow and dirt such as old keratin on the skin surface, the skin surface can be effectively cleaned by peeling the dirt from the skin surface.
[0023]
Since the suction washer of the first embodiment is configured as described above, the following operation can be obtained.
(1) Since the skin surface H can be covered by the gas-liquid ejection guide portion 6 and the swirling flow of the gas-liquid mixed fluid containing fine bubbles can be maintained on the skin surface H, the low-pressure portion is the skin surface H. The skin surface H formed most recently can be effectively sucked, and a high massage effect and a cleaning effect can be obtained.
(2) Since the gas-liquid mixed fluid containing fine bubbles hits the skin, it is possible to obtain a comfortable feeling by mildly hitting the water flow.
(3) A gas shaft is formed in the vessel body 2 by the air sucked through the gas self-priming holes 5, and a predetermined amount in the water flow is obtained by the interaction between the gas shaft and the swirling flow in the hollow portion 2a. It is possible to effectively generate fine bubbles of the form and has excellent cleaning properties.
(4) Fine bubbles are mixed in the swirling flow that collides with the skin surface H, and the fine bubbles adhere to the skin surface H and burst, thereby providing a low-frequency massage effect and making the skin surface effective. Can be massaged.
(5) Since the suction washer 1 does not include extra components in the hollow portion 2a and has a small number of parts and a simple structure, it is excellent in productivity and maintainability.
(6) When the tip of the gas-liquid ejection guide part 6 is separated from the skin surface H, the swirling flow flies as water droplets, so that it can be used as a shower containing fine bubbles and is excellent in convenience.
[0024]
(Embodiment 2)
A cleaning apparatus according to Embodiment 2 of the present invention that includes the suction cleaner of Embodiment 1 of the present invention will be described below with reference to the drawings.
FIG. 4 is a schematic view of the cleaning apparatus according to the second embodiment including the suction cleaner according to the first embodiment.
In FIG. 4, 1 is a suction cleaner, 2 is a container, 4 is a liquid introduction pipe, and 6 is a gas-liquid jet guide part, which are the same as those in the first embodiment, and are therefore given the same reference numerals. Therefore, the description is omitted.
11 is a cleaning apparatus in the second embodiment, 12 is a pump such as a turbo pump or a positive displacement pump having a suction port 12a and a discharge port 12b, 13 is a suction pipe whose downstream side is connected to the suction port 12a of the pump 12, and 14 Is a discharge pipe whose upstream side is connected to the discharge port 12 b of the pump 12 and whose downstream side is connected to the liquid introduction pipe 4 of the suction cleaner 1, 15 is a strainer connected to the opening on the upstream side of the suction pipe 13, and 16 is a strainer. A liquid tank such as a water tank or a bathtub in which 15 is immersed and a cleaning liquid is placed.
In the second embodiment of the present invention, the case where the suction washer 1 is connected to the discharge side of the pump 12 has been described, but the same is true if the suction washer 1 is connected to the outflow side of a water supply or the like via a hose. Can be implemented.
[0025]
The operation of the cleaning apparatus according to Embodiment 2 configured as described above will be described with reference to the drawings.
By driving the pump 12, the liquid in the liquid tank 16 is supplied to the liquid introduction pipe 4 of the suction cleaner 1 through the strainer 15, the suction pipe 13, the pump 12, and the discharge pipe 14.
A swirl flow is formed in the hollow portion 2 a by the liquid supplied from the liquid introduction tube 4, whereby the shaft portion in the hollow portion 2 a is depressurized, and the gas self-priming holes 5 provided on the rear wall of the vessel body 2. Air is sucked from. A gas shaft is formed by the sucked air, and the tip of the gas shaft extending around the gas shaft and toward the gas-liquid ejection hole 3 is torn off and dispersed in the water flow to form fine bubbles. Can be generated.
At this time, by increasing or decreasing the output of the pump 12 to adjust the state of fine bubbles generated in the suction cleaner 1, or by mixing bubbles in the liquid fed to the pump 12 in advance, the cleaning effect or the like is further enhanced. It may be. In addition, detergents and other surfactants are mixed in the liquid to change the interfacial tension of the generated bubble surface, enabling shampoo cleaning, and controlling the state of fine bubbles more appropriately. Is also possible.
In this way, a water flow containing such fine bubbles is discharged from the gas-liquid jet hole 3 and swivels between the gas-liquid jet guide portion 6 and the skin surface H or blown onto the skin surface when used as a shower. By doing so, cleaning of the skin surface H and massage can be performed simultaneously.
[0026]
According to the cleaning device in the second embodiment of the present invention including the suction cleaner of the first embodiment configured as described above, the following operation is obtained in addition to the operation obtained in the first embodiment. It is done.
(1) The cleaning device 11 can be composed of the suction cleaner 1 and the pump 12 having a simple structure, and the number of parts can be reduced, so that the productivity is excellent and the maintainability is excellent.
(2) Since the liquid is only sent to the suction cleaner 1 by the pump 12, the cleaning device 11 can be easily installed and used not only indoors but also outdoors such as a campsite.
(3) When an air introduction means such as an air introduction hole is formed on the suction side of the pump 12, the bubbles of the gas-liquid mixed fluid come into contact with the impeller rotating in the pump and are diffused in a finely dispersed state. Therefore, finer bubbles can be generated.
(4) The liquid that has flowed into the hollow portion 2a from the liquid introduction pipe via the pump 12 turns toward the gas-liquid ejection hole 3 while turning along the peripheral wall surface converging toward the front side in the hollow portion 2a. The low-pressure part is formed in the central part of the gas-liquid jet hole 3, whereby air can be sucked from the gas self-suction hole 5.
(5) The skin from the front of the gas-liquid jet guide part 6 decompressed by the swirling flow of the gas-liquid mixed liquid by bringing the edge of the gas-liquid jet guide part 6 into contact with the skin surface H to be cleaned and massaged A massage effect is obtained by sucking the surface. In addition, a fine bubble is generated by tearing at the tip and periphery of the gas shaft formed in a rod shape at the center of the vessel body 2, and the skin surface and the edge of the gas-liquid ejection guide part 6 together with the water flow connecting the skin surface The skin surface can be washed out from the gap.
(6) The skin surface can be effectively covered by the gas-liquid jet guide unit 6 and the skin surface is cleaned while holding the swirling flow containing fine bubbles, and the low pressure portion generated by the swirling flow is in the immediate vicinity of the skin surface. Since the skin surface is sucked in a wide range, blood circulation can be improved.
(7) When the fine bubbles of the swirling flow that collide with the skin surface adhere to the skin surface and burst, the skin surface is stimulated and activated, and a high massage effect can be obtained.
(8) By including fine bubbles in the water flow, the fine bubbles can reach close to the hair root, so that these fine bubbles are brought into impact contact with the skin surface, and the frictional action and the action when the fine bubbles are ruptured. Can clean the oxidized sebum and old keratin on the skin surface.
[0027]
(Embodiment 3)
A suction cleaner according to Embodiment 3 of the present invention will be described below with reference to the drawings.
FIG. 5 (a) is a perspective view of a main part of a suction cleaner in Embodiment 3, FIG. 5 (b) is a side sectional view of the main part, and FIG. 6 (a) is a front view of the main part. FIG. 6B is a rear view of the main part.
5 and 6, 2 is a container body, 2 a is a hollow portion, 3 is a gas / liquid ejection hole, 4 is a liquid introduction pipe, 6 is a gas / liquid ejection guide portion, and 7 is an outflow portion. 1 are denoted by the same reference numerals and the description thereof is omitted.
5 ′ is a gas self-priming hole that is opened larger than the gas self-priming hole 5 of the first embodiment, 21 is a suction cleaner in the third embodiment, and 22 is rearward from the edge of the gas-liquid ejection guide portion 6. A scatter prevention part 23 provided around the tank part 24 having a tank side hollow part 23a which is disposed on the rear wall of the container body 2 and communicates with the hollow part 2a of the container body 2 through a gas self-priming hole 5 '. Is a tank hole opened on the upper side of the tank portion 23.
The suction cleaner 21 of the third embodiment is different from the suction cleaner 1 of the first embodiment in that it has a tank portion 23 and a tank hole 24, a point having a scattering prevention portion 22, and a gas self-priming hole 5 ′. This is a point formed larger than the gas self-priming holes 5 of the first embodiment.
If the hole diameter of the tank hole 24 is larger than the hole diameter of the gas self-priming hole 5 ′ to reduce the resistance when air is sucked from the outside, this reduces fluctuations such as breathing and the air. Can be stably supplied to tap water or hot water.
[0028]
The operation of the suction cleaner 21 according to Embodiment 3 of the present invention configured as described above will be described below with reference to the drawings.
FIG. 7 is an explanatory view showing a use state of the suction cleaner in the third embodiment of the present invention.
In FIG. 7, 2 is a vessel body, 2a is a hollow portion, 3 is a gas-liquid ejection hole, 4 is a liquid introduction pipe, 5 'is a gas self-priming hole having a diameter of about 2.5 to 3.5 mm, 6 Is a gas-liquid ejection guide part, 7 is an outflow part, 21 is a suction cleaner in the second embodiment, 22 is a splash prevention part, 23 is a tank part, 23a is a tank side hollow part, and 24 is a tank hole. Since it is the same as that of FIG.5 and FIG.6, the same code | symbol is attached | subjected and the description is abbreviate | omitted. Moreover, H is a skin surface, and since this is the same as that of FIG. 3, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
The tank part 23 is a liquid storage part formed in a cylindrical shape or the like so as to be covered with the rear wall of the container body 2 and communicated with the hollow part 2a through a gas self-priming hole 5 ′ formed in the rear wall. ing. The tank part 23 is formed to have substantially the same diameter as the container body 12 and has a volume of about 1/20 to 1/4 with respect to the volume of the container body 2. The tank portion 23 is bonded to the rear wall of the container body 2 with an adhesive or the like, but can be formed integrally with the container body.
The tank hole 24 is formed in the upper part of the tank part 23, has a hole diameter of about 0.5 to 5 mm, and can suck external air or the like through the water stored in the tank part 23.
X is a gas shaft formed in the hollow portion 2 a of the vessel body 2 from the gas self-priming hole 5 ′ to the gas-liquid ejection hole 3 and the skin surface H.
First, the liquid introduction pipe 4 of the suction cleaner 1 is connected to the faucet of the water supply or the discharge outlet side of the pump, and the liquid is allowed to flow from the liquid introduction pipe 4 into the hollow portion 2a of the vessel body 2 from the tangential direction.
The liquid that has flowed into the hollow portion 2a moves from the gas-liquid jet hole 3 to the gas-liquid jet guide portion 6 while turning along the wall surface of the hollow portion 2a, and turns along the inner wall surface of the gas-liquid jet guide portion 6. While colliding with the skin surface H, it flows out of the suction washer 21 from the outflow part 7 through the inner wall surface of the scattering prevention part 22.
At this time, the liquid swirls along the peripheral wall of the container body 2 to exert a centrifugal force, and the vicinity of the center of the swirling flow has a low pressure. Therefore, the gas self-suction holes 5 ′ disposed at the substantially central position of the rear wall. As a result, the gas is continuously sucked to form the gas axis X in the hollow portion 2a and the skin surface H on the front side of the gas-liquid jet guide portion 6 is sucked.
The gas collected on the gas axis X is torn apart by the shearing force of the swirling flow between the tip portion and the skin surface H and diffuses as fine bubbles, and passes through the skin surface H from the outflow part 7 together with the swirling flow. leak.
Here, the suction washer 21 is different from the suction washer 1 of the first embodiment, and the hollow portion 2a is not in direct communication with the outside air through the gas self-suction holes, and the tank-side hollow portion 23a of the tank portion 23 is not provided. Since the tank-side hollow portion 23a communicates with the outside air through the tank hole 24, the suction resistance is increased.
For this reason, the gas self-priming hole 5 ′ is formed larger than that of the first embodiment, but the flow rate of the gas sucked into the hollow portion 2a is substantially the same as that of the first embodiment.
Further, by storing the liquid in the tank-side hollow portion 23a, the suction resistance of the gas self-priming hole 5 ′ can be further increased, and the flow rate of the gas sucked into the hollow portion 2a can be reduced.
[0029]
According to the suction cleaner of the third embodiment configured as described above, in addition to the action obtained in the first embodiment, the following action is obtained.
(1) By providing the tank part 23, water pressure can be applied to the gas self-suction hole 5 ′ by water stored in the tank part 23, and the suction resistance of the gas self-suction hole 5 ′ can be increased. Therefore, even if the diameter of the gas self-priming hole 5 ′ is increased, a large amount of gas is not sucked, and the flow of the gas-liquid mixed liquid can be stably maintained. In this way, a reduction in suction force due to a large amount of gas suction is prevented, and a high massage effect is obtained.
(2) Even if the diameter of the gas self-priming hole 5 'is increased, a large amount of gas is not sucked in, and the bubbles to be ejected do not become large, and fine bubbles can be ejected stably over time, which is high A cleaning effect and a massage effect can be obtained.
(3) Since the diameter of the gas self-priming hole 5 'can be formed large, malfunctions due to clogging with dust and scales are unlikely to occur, and the maintenance is excellent.
(4) Since the scattering prevention part 22 is provided, the liquid that has flowed out from the outflow part 7 does not scatter forward and is excellent in usability.
[0030]
(Embodiment 4)
A suction washer according to Embodiment 4 of the present invention will be described below with reference to the drawings.
FIG. 8 is a side sectional view of a main part of the suction cleaner in the fourth embodiment.
In FIG. 8, 3 is a gas-liquid ejection hole, 4 is a liquid introduction pipe, 6 is a gas-liquid ejection guide part, 7 is an outflow part, and 22 is a scattering prevention part, which are the same as those in the third embodiment. Therefore, the same reference numerals are given and the description thereof is omitted.
31 is a suction washer in the fourth embodiment, 32 is a container having a hollow portion 32a having a shape converging from the rear portion toward the front end portion, and having an opening portion 32b on the rear wall, and 32c is at the edge of the opening portion 32b. A female screw portion 33 erected along the rotation member 33 is a rotation member in which the male screw portion 33 a is screwed into the female screw portion 32 c and is rotatably covered in the opening portion 32 b, and 34 is opened in the rotation member 33. 35 is a tank part having a tank-side hollow part 35a which is disposed on the rear wall of the rotating member 33 and communicates with the hollow part 32a of the container body 32 through the gas self-suction hole 34; It is a tank hole opened on the upper side of the portion 35.
The suction cleaner 31 in the fourth embodiment is different from the suction cleaner 21 in the third embodiment in that the rotating member 33 is provided so as to be screwed into the opening 32b of the container body 32, and the tank portion 35 is provided. This is a point provided on the rotating member 33.
In addition, although the step part is formed in the rear wall side of the container body 2 by the female screw part 32c, by shortening the length of the female screw part 32c to about 1/10 or less of the axial length of the container body 2, The bubble generation state can be satisfactorily maintained without disturbing the swirling water flow in the vessel body 2.
[0031]
The operation of the suction cleaner in the fourth embodiment configured as described above will be described below with reference to the drawings.
FIG. 9 is a main part rear cross-sectional view for explaining the overlap between the gas self-priming holes and the gas shaft in the fourth embodiment.
In FIG. 9, 32 is a container, 33 is a rotation member, and 34 is a gas self-priming hole, and these are the same as those in FIG.
Reference numeral 33 b denotes a rotation center of the rotation member 33, and Y denotes a gas shaft formed in the hollow portion 2 a of the container body 2 from the gas self-priming hole 5 to the gas-liquid ejection hole 3 and the skin surface H. The gas self-priming hole 34 is formed with a slight shift from the rotation shaft 33b. Thereby, the area of the overlapping part when the gas shaft Y and the gas self-suction hole 34 formed in the container 3 are viewed from the axial direction can be adjusted by rotating the rotating member 33. By adjusting this overlapping portion, the suction resistance of the gas self-suction holes 34 can be adjusted, and the amount of gas sucked from the gas self-suction holes 34 and the form thereof can be adjusted.
The operations other than the adjustment of the overlap between the gas self-priming hole and the gas shaft are the same as those in the third embodiment, and the description thereof is omitted.
[0032]
Since the suction washer of the fourth embodiment is configured as described above, the following actions are obtained in addition to the actions obtained in the first embodiment.
(1) The rotating member 33 is provided on the rear wall of the container body 2 so as to cover the rotating shaft at a position eccentric from the center of the container body 2, and the gas self-priming hole 34 is formed at an eccentric position with respect to the rotating shaft. Therefore, by rotating or rotating the rotating member 33, the area of the portion where the gas cross section projected onto the rear wall of the gas axis Y formed in the vessel 2 and the gas self-priming hole 34 overlap is obtained. The amount of gas sucked from the gas self-suction hole 34 can be adjusted by changing the suction resistance or the like from the gas self-suction hole 34.
(2) The central part of the container body 2 is depressurized by a swirling flow of liquid, the gas is sucked from the gas self-priming holes 34 arranged on the rear wall of the container body 2, and the gas shaft is placed in the central part of the container body 2. Can be formed. Since the configuration of the gas shaft Y can be adjusted by rotating the rotating member to a predetermined angle, the operability is excellent.
[0033]
(Embodiment 5)
A cleaning apparatus provided with the suction cleaner of the fifth embodiment will be described below with reference to the drawings.
FIG. 10 is an explanatory view showing a use state of the suction cleaner in the fifth embodiment.
In FIG. 10, reference numeral 40 denotes a suction cleaner according to the fifth embodiment, and reference numeral 41 denotes a vessel body formed by bending the rear wall. Therefore, the water flow hits the curved rear wall and reverses, and it can be ejected outward while rotating at a high speed in the immediate vicinity of the center, and the rotational axis portion is maintained in a reduced pressure state by this high speed rotation, A gas dissolved to the maximum extent in a liquid such as tap water is released to form a gas axis. In addition, the same code | symbol is attached | subjected about the thing similar to Embodiment 1, and the description is abbreviate | omitted.
Z is a gas shaft formed by concentrating air in the liquid (underwater) of the liquid fed through the liquid introduction pipe 4 at the center of the hollow portion 2a.
It should be noted that the rear wall of the container body 41 can be applied to a shape that bulges outwardly or a flat vertical wall.
[0034]
Here, FIG. 11 is a schematic view of a cleaning apparatus provided with a suction cleaner.
In FIG. 11, 4 is a liquid introduction pipe, 6 is a gas-liquid ejection guide part, 12 is a pump, 12a is a suction port of the pump 12, 12b is a discharge port of the pump 12, 13 is a suction pipe connected to the suction port 12a, 14 is a discharge pipe connecting the liquid introduction pipe 4 and the discharge port 12b, 15 is a strainer provided at the opening of the suction pipe 13, 16 is a liquid tank in which the strainer 15 is immersed to store a cleaning liquid, 41 These are the suction cleaners in the fifth embodiment, and these are the same as those in the second and fifth embodiments, so the same reference numerals are given and the description thereof is omitted.
51 is a cleaning device provided with the suction cleaner 40 in the fifth embodiment, 52 is a pump gas self-priming hole drilled in a predetermined portion of the suction pipe 13, and 53 is one end connected to the pump gas self-suction hole 52. It is a gas self-priming pipe that is provided with a needle valve, a pressure-bonding type valve, and the like so that the amount of intake air can be adjusted.
[0035]
About the washing | cleaning apparatus 51 comprised as mentioned above, the operation | movement is demonstrated referring drawings.
By driving the pump 12, the liquid in the liquid tank 16 is sucked into the suction pipe 13 through the strainer 15. When the liquid passes through the suction pipe 13, the gas is sucked from the gas self-priming pipe 53 into the suction pipe 13 as an accompanying flow of the liquid, and the liquid mixed with the gas (gas-liquid mixed fluid) is sent from the suction port 12 a to the pump 12. Inhaled. Bubbles are diffused by an impeller or the like in the pump 12 and supplied to the liquid introduction tube 4 of the suction cleaner 40 through the discharge tube 14.
When the gas-liquid mixed fluid is caused to flow from the liquid introduction tube 4 into the hollow portion 2a of the container body 2 in the tangential direction, the gas-liquid mixed fluid that has flowed into the hollow portion 2a is swirled along the wall surface of the hollow portion 2a. It moves from the liquid ejection hole 3 to the gas-liquid ejection guide part 6, collides with the skin surface H while turning along the inner wall surface of the gas-liquid ejection guide part 6, and flows out of the suction washer 40 from the outflow part 7.
At this time, since the central portion of the swirling flow is decompressed, the gas mixed in the liquid in advance gathers in the central portion of the swirling flow, the gas axis Z is formed, and the skin surface H is opened from the front of the gas-liquid ejection guide portion 6. Sucked. The gas collected on the gas axis Z is torn between the skin surface H and the swirling flow to form fine bubbles, flows out from the outflow portion 7 along with the swirling flow along the skin surface H.
Even if the valve of the gas self-priming pipe 53 is closed, the air in the liquid can be released from the liquid under the reduced pressure as described above to create a gas shaft. Can be generated automatically.
[0036]
Since the cleaning device 51 including the suction cleaner 40 according to the fifth embodiment is configured as described above, the following operation is obtained.
(1) Since there are no pores such as gas self-priming holes, it is excellent in maintainability without causing malfunction due to clogging with dust or scales.
(2) When a liquid in which a predetermined amount of gas is dissolved is used, the gas shaft formed in the hollow portion can be stably held, and a water flow always containing fine bubbles of a constant form is used. Cleaning and massage can be performed in a stable state.
(3) Since the swirl flow formed in the hollow portion 2a of the vessel body 2 can interact with the vessel wall, the gas-liquid jet guide portion 6 and the like, the bubble nuclei in the liquid can be grown and expanded. Even if there is no suction hole, the gas axis Z can be formed effectively. It is to be noted that the growth of bubble nuclei tends to become remarkable as the temperature increases, and the temperature of the applied water is preferably around 40 ° C., preferably about 40 ° C. to 45 ° C. Further, when the liquid is at a low temperature, a deficient gas can be replenished into the liquid from here through the gas self-priming tube 53.
(5) Since the bubbles in the gas-liquid mixed fluid are diffused by the impeller in the pump 12, even finer bubbles can be generated.
(6) When passing the liquid through the suction pipe 13, the gas is sucked from the gas self-priming pipe 53 into the suction pipe 13 as an accompanying flow of the liquid, so that the gas can be mixed into the liquid in a more controlled environment. It has excellent operability and controllability.
[0037]
(Embodiment 6)
A suction cleaner according to Embodiment 6 of the present invention will be described with reference to the drawings.
FIG. 12 is a schematic view showing a usage pattern of the suction cleaner in the sixth embodiment.
In FIG. 12, 60 is a suction washer of the sixth embodiment, 61 is formed of a synthetic resin or the like having a bullet-shaped hollow portion 62 having a maximum inner diameter D of 30 to 90 mm that converges from the rear side to the front side. 63 is a gas-liquid ejection hole having a minimum diameter d of 5 to 10 mm having an inclined portion 63a formed at the front end of the vessel body 61 and a flat portion 63b connected to the inclined portion 63a. 61 is a liquid introduction pipe connected in a tangential direction to the peripheral wall on the rear side of 61, 65 is a gas self-priming hole which is arranged on the rear wall of the vessel body 61 and is drilled at a position eccentric from the center position of the rear wall, and 66 is a gas An umbrella-like gas-liquid jet guide portion disposed around the liquid jet hole 63 and expanded in the jet direction from the gas-liquid jet hole 63, P is a low pressure on the skin surface H due to the flow of the gas-liquid mixed fluid. Pressure distribution of p1 to p3 formed by alternately and continuously forming belts and high pressure belts in an annular shape, Q The direction of flow of the gas-liquid mixed fluid.
The inclined portion 63a is a portion of the gas-liquid jet hole 63 whose diameter θ is enlarged by 60 to 85 degrees and the length A is 1 to 10 mm toward the gas-liquid jet guide portion 66, and the flat portion 63b is the gas-liquid jet guide. This is a portion of the gas-liquid jet hole 63 that is extended toward the portion 66 by a length B of 1 to 10 mm.
Note that the optimum values of the angle θ, the length A, and the length B are also determined by the liquid flowing in from the liquid introduction pipe 4 and the inner diameter D of the vessel body 61 and the axial length L (axial length). In this embodiment, the inner diameter D = 40 mm, the shaft length L = 50 mm, the minimum diameter d of the gas / liquid ejection holes d = 7.5 mm, the gas self-priming hole diameter db = 0.5 mm, the length A = 3.2 mm, and the length B = 2.6 mm, water pressure P = 3 × 10^FivePa (about 3 kgf / cm²)
The suction cleaner 60 in the sixth embodiment is different from the suction cleaner 1 in the first embodiment in that the gas-liquid jet hole 63 has an inclined portion 63a and a flat portion 63b connected to the inclined portion 63a. There is in point.
[0038]
The operation of the suction washer 60 configured as described above will be described.
A liquid having a predetermined flow rate and pressure is supplied from the liquid introduction pipe 64 to the hollow portion 62 of the container body 61 in the tangential direction. At this time, the liquid flowing into the hollow portion 62 swirls along the wall surface of the hollow portion 62, and a low-pressure portion is formed at the central portion of the vessel body.
By this low pressure portion, air is sucked from the gas self-priming hole 65 disposed near the center of the rear wall of the vessel body 61, and a gas shaft is formed in the low pressure portion in the hollow portion 62. Fine bubbles are generated in the liquid by the mutual movement of the gas axis and the swirling flow.
Thus, the water flow containing fine bubbles moves along the gas-liquid jet guide part 66 via the inclined part 63a and the flat part 63b formed on the inner wall of the gas-liquid jet hole 63, and the peripheral edge of the gas-liquid jet guide part 66 And the skin surface.
In addition, when the outflow part 7 which formed the notch part and opening part in the gas-liquid ejection guide part 66 is provided, even if the front-end part of a gas-liquid ejection guide part is strongly pressed on the skin surface, a swirl flow is made into an outflow part 7 can flow out of the gas-liquid jet guide part 66. In addition, the water flow can be continued and flowed to the skin surface, and the flow state in the gas-liquid ejection guide portion can be adjusted by the arrangement pattern of the outflow portion, the opening area, and the like.
The gas-liquid mixed fluid ejected from the gas-liquid ejection holes 63 flows in a space sandwiched between the skin surface H and the gas-liquid ejection guide portion 66, and has p1 to p3 having an annular low-pressure zone and high-pressure zone. The gas-liquid mixed fluid flow Q is discharged from the outflow part 7 while forming the pressure distribution P. Since such a low-pressure zone and a high-pressure zone can be alternately formed on the skin surface H, this promotes the blood circulation state of the skin and effectively removes dirt on the skin surface.
[0039]
Since the suction washer 60 of the sixth embodiment is configured as described above, the following actions are obtained in addition to the actions obtained in the first embodiment.
(1) Since the inclined portion 63a whose diameter is enlarged at a predetermined angle toward the ejection side is provided on the inner peripheral wall of the gas-liquid ejection hole 63, the water flow including microbubbles and bubble nuclei before becoming microbubbles diffuses. The range can be limited to a predetermined angle to reduce the pressure in the water flow, and the partial pressure reduction can effectively promote the growth from bubble nuclei to fine bubbles.
(2) When used as a shower, since it has a flat part 63b formed in front of the inclined part 63a, water droplets ejected by the flat part 63b can be prepared, and fine bubbles can be formed. A large amount of water droplets can be stably supplied. Moreover, the water droplets ejected can be collected in the center.
(3) Use conditions such as water quality, pressure, flow rate, temperature, and the like of the supplied water, such as the angle θ in the inclined portion 63a and the length A in the ejection direction, and the length B in the ejection direction in the flat portion 63b, for example, a bathtub and a pool Depending on the usage conditions such as the side, each can be combined and adjusted to an appropriate range, the size of the fine bubbles and the aggregated form of the bubbles can be changed slightly, and the cleaning effect and massage effect of the fine bubbles can be enhanced. .
(4) By the flow Q of the gas-liquid mixed fluid through the outflow part 7, the pressure distribution P in which the low-pressure zone and the high-pressure zone are alternately and continuously formed on the skin surface H can be formed. Can promote the blood circulation state and effectively remove the dirt on the skin surface.
[0040]
(Embodiment 7)
A suction cleaner according to a seventh embodiment of the present invention will be described with reference to the drawings.
FIG. 13 is a cross-sectional view of the suction cleaner in the seventh embodiment.
In FIG. 13, 70 is a suction washer according to the seventh embodiment, 71 is a container having a hollow portion 72 which is converged from the rear side to the front side and is curved in the rear side to be formed in a substantially egg shape, 73 is a gas-liquid jet hole formed at the front end of the vessel body 71, 74 is a water jet nozzle portion formed by constricting the tip portion inserted into the rear wall of the vessel body 71, and 74a is a water jet nozzle portion. 74 is an inverted conical water flow adjusting member disposed at the front part of 74, 74b is a rod-shaped support member having the water flow adjusting member 74a disposed at the front part, and 74c is a flowing water that supports the support member 74b at the nozzle intermediate part. An intermediate support member provided with a path, 74d is a position adjustment fixing unit that supports the support member 74b in a state where the support member 74b is sealed through an O-ring or the like at the base end side, and is supported so as to be able to advance and retreat. 75 is a peripheral wall of the body 71 Is connected with the introduction port 75a in the tangential direction along The liquid introduction pipe 76 is disposed around the gas-liquid ejection hole 73 and is expanded in a hemispherical form. The gas-liquid ejection guide part 77 is formed by opening a plurality of openings in the gas-liquid ejection guide part 76. An outflow part for the cleaning liquid, 78 is a water flow recovery part having a flow path for recovering the cleaning liquid in communication with the outflow part 77, and 79 is formed by branching on the vessel 71 wall side of the liquid introduction pipe 75. This is a water supply pipe for supplying tap water or hot water to the nozzle portion 74.
[0041]
A method of using the suction cleaner 70 configured as described above will be described.
First, hot water of 30 to 60 ° C. is supplied from the liquid introduction pipe 75. As a result, the hot water is distributed to the flow toward the water supply pipe 79 and the introduction port 75a at the branch portion of the liquid introduction pipe 75 to form a swirl flow in the vessel 71 and a part thereof is supplied to the water jet nozzle section 74. The
A water flow adjusting member is disposed in the vicinity of the tip of the water jet nozzle portion 74, and the mixed water flow formed by mixing the swirling flow and the nozzle jet flow flowing along the vessel wall by adjusting the interval between these portions. The negative pressure portion and the like can be generated effectively by controlling the state of In this way, a large amount of dissolved gas can be released by changing the supersaturated warm water to a low pressure state, and a water flow containing fine bubbles can be ejected from the gas-liquid ejection hole 73.
Further, by bringing the gas-liquid ejection guide part 76 into close contact with the skin surface, a concentric pressure distribution in which the levels of pressure are alternately different can be formed on the skin surface, and the skin surface is stimulated and activated. Further, the massage effect and the cleaning effect can be further enhanced.
[0042]
Since the suction cleaner 70 of the seventh embodiment is configured as described above, it has the following operation.
(1) A part of tap water or hot water supplied from the liquid introduction pipe 75 can be directly jetted in the vicinity of the inside of the gas-liquid jet hole 73 through the water jet nozzle part 74 in a high pressure state. Excellent in massage.
(2) Since the water flow recovery unit 78 is provided, the washing water or the like is not greatly scattered around the surroundings, thereby preventing the surroundings from being soiled.
(3) Since a gas-liquid jet guide portion 76 is brought into contact with the skin surface to form a sealed system through which water flows when hot water is jetted, a concentric low-pressure zone and a high-pressure zone are formed on the skin surface by the jet flow. Can be activated alternately by stimulating them.
(4) Since the water flow adjusting member 74a is provided on the inner side of the tip of the water jet nozzle portion 74, the water flow jetting angle and the gas-liquid dispersion state can be appropriately adjusted by advancing and retracting the water flow adjusting member 74a. Can be maintained.
(5) When the water supplied to the water jet nozzle 74 is heated hot water, the dissolved amount of gas that can be dissolved in the water is reduced to a supersaturated state, and this water flow is brought to the low pressure state of the vessel body. A large amount of dissolved gas is released to enhance the massage effect.
(6) The nozzle jet flow jetted forward from the tip of the water jet nozzle portion 74 and the vessel wall swirl flow flowing along the vessel wall from the introduction port 75a are merged at the nozzle port, and fine bubbles in the liquid Can be further finely dispersed into a cleaning liquid or a massage liquid having a mild water flow.
[0043]
(Embodiment 8)
The suction cleaner according to the eighth embodiment of the present invention will be described with reference to the drawings.
FIG. 14 is a cross-sectional view of the suction cleaner in the eighth embodiment.
In FIG. 14, reference numeral 80 denotes a suction washer according to the eighth embodiment, 81 is a substantially hemispherical outflow restricting portion attached to the gas-liquid ejection guide portion 76 from the front side, and 82 is a peripheral portion of the gas-liquid ejection guide portion 76. The hinge 83 is provided at the center and rotatably supports the outflow restricting portion 81, and 83 is opened at the center of the hemispherical outflow restricting portion 81 so as to substantially match the gas / liquid ejection hole 73 when the gas / liquid ejection guide portion 76 is attached. The formed opening part 84 is a disk part (gas shaft abutting plate) which is formed in a substantially disk shape so as to close the front side center of the outflow restricting part 81 and is disposed at the tip end position of the gas axis in the vessel body, and 85 is a mist It is a large number of small holes for spraying a hot water on the front side.
The suction cleaner 80 according to the eighth embodiment has an outflow restricting portion 81 attached to the front side of the suction cleaner 70 according to the seventh embodiment, and the main body is the same as that of the seventh embodiment. These are denoted by the same reference numerals and description thereof is omitted.
[0044]
A method of using the outflow restricting portion 81 in the suction cleaner 80 will be described.
First, hot water is supplied from the liquid introduction pipe 75 in a state where the outflow restricting portion 81 is attached to the gas-liquid jet guide portion 76, and hot water in a water droplet state is jetted from the gas-liquid jet hole 73. At this time, the opening of the outflow part 77 is shielded by the outflow restricting part 81, and the hot water to be sprayed is sprayed in a mist form through a small hole 85 provided in the front surface of the outflow restricting part 81, so that a normal shower is provided. Used as
Further, when the suction cleaner 80 is used as a shower, a gas shaft can be effectively formed up to the gas shaft contact plate 84 in a low pressure (negative pressure) state. It is possible to prevent the mixing of gas, and it becomes a shower containing fine bubbles.
Further, the outflow regulating portion 81 can be rotated by the hinge 82 and removed from the gas-liquid ejection guide portion 76 and used as a washer or a massager as in the case of the seventh embodiment.
[0045]
Since the suction cleaner 80 of the eighth embodiment is configured as described above, it has the following action in addition to the suction cleaner 70 of the seventh embodiment.
(1) Since the outflow restricting portion 81 is rotatably provided at the peripheral portion of the gas-liquid jet guide portion 76 via the hinge 82, the outflow restricting portion 81 is set according to the use situation such as a bathroom or a washroom. It can be fitted to the gas-liquid jet guide part 76 and used as a shower, or can be opened and used as a cleaning device or a massage device, and is excellent in versatility.
(2) The outflow restricting portion 81 can be stored compactly in a state in which the outflow restricting portion 81 is fitted to the gas-liquid jet guide portion 76, and the storage property is excellent.
[0046]
【The invention's effect】
  According to the suction washer according to claim 1 of the present invention, the following effects can be obtained.
(1) A liquid introduction pipe of a suction cleaning device is connected to a water supply port such as a water supply or a discharge outlet side of a pump, etc., and the liquid is allowed to flow from the liquid introduction tube into the hollow portion of the vessel body from the tangential direction of the peripheral wall. it can. The liquid that has flowed into the hollow portion moves toward the gas-liquid ejection hole while turning along the peripheral wall surface converged toward the front side of the hollow portion, and can be ejected from the gas-liquid ejection hole. The liquid flow (water flow) collides with the skin surface or the like disposed on the entire surface of the gas-liquid ejection guide part while turning along the inner wall surface of the gas-liquid ejection guide part connected to the gas-liquid ejection hole. The center part of the swirling flow becomes a low pressure by the swirling motion, and the skin surface and the like can be cleaned and massaged.
(2) By bringing the edge of the gas-liquid jet guide part into contact with the skin surface to be cleaned or massaged, the skin surface is sucked from the front of the gas-liquid jet guide part decompressed by the swirling flow, and the massage effect is obtained. can get. Further, when air or the like is mixed in the liquid supplied to the liquid introduction hole in advance, a gas shaft made of mixed air is formed in the hollow portion at the center of the vessel body, and the tip and periphery of the gas shaft are formed. The part is diffused as fine bubbles in the water flow due to the shearing force of the water flow suction force, and flows out from the gap between the skin surface and the edge of the gas-liquid ejection guide part together with the water flow through the skin surface to clean the skin surface Can be performed more effectively.
(3) Since the gas-liquid jet guide portion can maintain the swirling flow of the gas-liquid mixed fluid up to the edge of the gas-liquid jet guide portion where the water flow contacts the skin surface, The skin surface can be effectively sucked in a wide range, and a high massage effect can be obtained.
(4) Since the suction washer has no obstacle to the water flow in the inside thereof, desired fine bubbles can be generated very efficiently.
(5) Since the structure is simple and the number of parts is small, the productivity is excellent and the maintenance is excellent.
(6) When using the gas-liquid jet guide part away from the skin surface, the suction cleaner can be used effectively as a shower without restricting the diffusion of the water flow jetted by the air-flow jet guide part.
(7) When the front edge of the gas-liquid ejection guide part is ejected against the skin surface, the swirling liquid hitting the skin is closer to the gas axis of the central negative pressure part than the outflow part side. Invert to. The reversed negative pressure portion and the central negative pressure skin can be sucked in a wide range.
(8) Even if the front end of the gas-liquid jet guide part is strongly pressed against the skin surface, the swirling flow can be made to flow out of the gas-liquid jet guide part from the outflow part. It can flow.
(9) Since a plurality of outflow portions can be provided with respect to the gas-liquid ejection guide portion, it is possible to effectively generate a swirling flow or complicate the flow to enhance the massage effect.
[0047]
According to the suction washer according to claim 2, in addition to the effect of claim 1, the following effect can be obtained.
(1) The gas shaft formed in the central part of the container body generates fine bubbles due to the shearing force of the water flow at the rod-shaped tip and periphery, and the skin surface and the gas-liquid ejection guide part together with the water flow connecting the skin surface. The skin surface can be washed out from the gap with the edge.
(2) Fine bubbles are mixed in the swirling flow that collides with the skin surface, and the fine bubbles adhere to the skin surface and burst, thereby stimulating and activating the skin surface and obtaining a high massage effect. it can.
(3) Since the gas can be directly sucked into the hollow portion from the gas self-priming hole, it can be easily used without using a pump or the like by connecting it to a water supply port or the like.
(4) By including fine bubbles in the water stream, the fine bubbles can be made to reach near the hair root. The fine bubbles are brought into impact contact with the skin surface, and this frictional effect and action when the fine bubbles are ruptured. Can clean the oxidized sebum and old keratin on the skin surface.
(5) Due to the swirling motion of the water flow in the container, a low pressure part is formed at the center of the swirling flow, that is, the axial center of the container, and air is sucked from the gas self-priming hole toward the low pressure part, A gas shaft extending in a rod shape toward the center is formed in the vessel. At this time, by arranging the gas self-priming hole at a position deviated from the body axis, the tip of the gas axis can be vibrated to generate fine bubbles more effectively. By adjusting the amount of eccentricity, the shape and size of the gas shaft can be subtly changed to obtain a water flow containing predetermined fine bubbles with optimized cleaning and massage effects.
[0048]
According to the suction washer according to claim 3, in addition to the effect of claim 2, the following effect can be obtained.
(1) The rotating member is provided on the rear wall of the container so as to be rotatable around the position eccentric from the central axis of the container, and the gas self-priming hole is eccentric from the rotational axis of the rotating member. Since it is formed, by rotating or rotating the rotating member, it is possible to adjust the area of the portion where the cross section projected onto the rear wall of the gas shaft formed in the body and the gas self-priming hole overlap. it can. By adjusting the area of the overlapping portion to increase or decrease, the suction resistance of the gas self-priming holes can be changed to adjust the amount of gas sucked from the gas self-priming holes.
(2) When liquid is supplied in the tangential direction of the container body from the liquid introduction hole of the container body, a swirling flow is formed, the central part of the container body is decompressed, and gas is released from the gas self-priming holes arranged on the rear wall of the container body. Is sucked. In this way, a gas shaft made of the sucked air can be formed at the center of the body. The form of this gas shaft also changes depending on the pressure, flow rate, temperature, etc. of the water supplied from the liquid introduction pipe, but by rotating the rotating member at a predetermined angle, the gas axis itself and the central axis of the vessel 2 It can be adjusted by changing the relative position to the suction hole 5.
(3) Since the amount of gas sucked into the hollow portion can be adjusted by rotating the rotating member, the amount of fine bubbles ejected, the suction force on the skin surface, etc., can be changed subtly. Excellent in properties.
[0049]
According to the suction washer according to claim 4, in addition to the effect according to claim 2 or 3, the following effect is obtained.
(1) Since the tank portion is provided, the outside air does not flow directly from the gas self-suction holes, and the suction resistance of the sucked air can be increased, so the diameter of the gas self-suction holes is increased. Even if a large amount of gas is not sucked in, the gas-liquid jet guide part can maintain the force of sucking the skin surface, and a high massage effect can be obtained.
(2) Since the external pressure fluctuation is eased by providing a tank with a large capacity, the control of the size, form, amount, etc. of the fine bubbles generated in the water flow can be stabilized and facilitated, and the operability is improved. Excellent.
(3) Since the diameter of the gas self-priming hole can be increased, it is difficult to cause malfunction due to clogging with dust or scale, and the maintenance is excellent.
[0050]
According to the suction washer according to claim 5, in addition to the effect of claim 1, it has the following effect.
(1) A part of tap water or hot water supplied from the liquid introduction pipe or tap water or hot water supplied from a separate pipe is supplied near the inside of the gas-liquid jet hole through the water jet nozzle. It can be ejected directly in a high state, and it has excellent cleaning and massage properties.
(2) Since the water flow adjusting member is provided inside the tip of the water jet nozzle part, the water flow jetting angle and the gas-liquid dispersion state are properly maintained by advancing and retreating the member and fixing it at a predetermined position. be able to. For example, when the water flow adjusting portion is formed in an inverted conical shape whose diameter is enlarged, the water flow is jetted in a reverse 8-shaped direction toward the nozzle outlet, so this water flow is converted into a cone of the water jet nozzle portion. It can be combined with the swirl flow that swirls and converges from the outer periphery of the shape. Therefore, both jetting forces can be suppressed and ejected in the form of large water droplets, or both can be synergized and ejected in the form of fine water droplets, which can be adjusted according to the conditions of cleaning and massage.
(3) Especially when the water supplied to the flow jet nozzle is heated to warm water, the dissolved amount of gas that can be dissolved in water decreases according to Henry's law, resulting in a supersaturated state. A large amount of dissolved gas can be released by passing through the pressure part (low pressure part), and a cleaning liquid and a massage liquid containing a large amount of fine bubbles can be obtained.
[0051]
According to the suction washer according to claim 6, in addition to the effect of any one of claims 1 to 5, the following effect can be obtained.
(1) Since the inner wall of the gas-liquid jet hole has an inclined portion that expands at a predetermined angle toward the jet side, the range in which the water flow including the microbubbles and the bubble nuclei before becoming microbubbles diffuses The inside of the water flow can be depressurized only within a predetermined angle, and this partial depressurization can effectively promote the growth from bubble nuclei to fine bubbles.
(2) When used as a shower, it has a flat portion formed in front of the inclined portion, so that water droplets ejected at the flat portion can be prepared and contains a large amount of fine bubbles. Water droplets can be supplied stably, and the water droplets can be concentrated at the center in the ejection direction.
(3) The angle θ in the inclined portion, the length A in the ejection direction, and the length B in the ejection direction in the flat portion are adjusted in combination depending on the water quality, pressure, flow rate, temperature, and the like of the supplied water. Thus, the size of the fine bubbles to be diffused in the water flow, the aggregate form of the bubbles, and the like can be slightly changed. Since the cleaning effect and the massage effect due to the fine bubbles vary depending on factors such as the form of the fine bubbles, a combination (θ, A, B) of values optimized for these can be set based on experiments.
[0053]
  Claim 7According to the suction washer described inClaims 1 to 6In addition to the effect of any one of the following effects, the following effects can be obtained.
(1) Since the liquid flowing out from the outflow part moves to the rear side opposite to the skin surface side, it is possible to prevent the water flow from splashing on the face or the like.
(2) When a liquid recovery pipe is attached to the splash prevention part, it can be used without polluting the bathroom or washroom.
[0054]
  Claim 8According to the suction washer described inClaim 1In addition to the effects described above, the following effects are obtained.
(1) Since the water flow recovery unit is provided, the washing water or the like is not greatly scattered around the surroundings, and the surroundings can be prevented from being polluted and is hygienic.
(2) Since a gas-liquid jet guide part is brought into contact with the skin surface to form a sealed system through which water flows when hot water is jetted, the pressure on the skin surface due to the jet flow is increased, and a good cleaning effect is achieved. A massage effect is obtained.
[0055]
  Claim 9According to the suction washer described inClaim 8In addition to the above effects, the following effects are obtained.
(1) Since the outflow restricting portion is rotatably provided at the peripheral portion of the gas-liquid ejection guide portion, the outflow portion communicating with the water flow collecting portion is shielded depending on the use situation such as a bathroom or a washroom. It can be used in the open state. It can be used as a shower in which fine gas bubbles are mixed by fitting the outflow restricting part to the gas-liquid jetting guide part, or it can be used as a suction washer in an open state, which is excellent in operability and versatility.
(2) Since the running water shielding part is attached via a hinge, the running water shielding part can be stored compactly in a state in which the running water shielding part is fitted to the gas-liquid ejection guide part, and it is convenient without fear of disappearing.
[0056]
  Claim 10According to the cleaning apparatus described in (1), the following effects can be obtained.
(1) The cleaning device can be configured only with a suction cleaner and pump having a simple structure, and the number of parts can be reduced.
(2) Since the liquid is merely sent to the suction washer by the pump, the cleaning device can be easily installed and used not only indoors but also outdoors such as campsites.
(3) When gas is mixed in the liquid supplied to the pump in advance, the bubbles in the gas-liquid mixed fluid are diffused by the impeller rotating in the pump, so that finer bubbles can be generated.
[0057]
  Claim 11According to the cleaning device described inClaim 10In addition to the above effects, the following effects can be obtained.
(1) Since a pump gas self-priming hole for sucking gas is provided in the suction pipe of the pump that supplies the cleaning liquid, it is not necessary to suck the gas on the suction cleaner side, and a predetermined amount of gas can be stabilized. It is easy to supply to the battery and is excellent in operability and convenience.
(2) Since the control of the mixing ratio between the gas and the liquid in the gas-liquid mixed fluid can be easily performed, an appropriate cleaning state can be maintained according to the use situation.
(3) It is easy to keep the state of the gas-liquid mixed fluid in use constant and excellent in stability in operation.
[Brief description of the drawings]
FIG. 1A is a perspective view of main parts of a suction cleaner in Embodiment 1. FIG.
(B) Side sectional view of the main part of the suction cleaner in the first embodiment.
FIG. 2A is a front view of a main part of the suction cleaner in the first embodiment.
(B) Main part rear view of suction cleaner in embodiment 1.
FIG. 3 is a side cross-sectional view of a main part showing a use state of the suction cleaner in the first embodiment.
FIG. 4 is a schematic diagram of a cleaning apparatus in Embodiment 2.
5A is a perspective view of a main part of a suction cleaner in Embodiment 3. FIG.
(B) Main part side surface sectional drawing of the suction washer in Embodiment 3
FIG. 6A is a front view of a main part of the suction cleaner in the third embodiment.
(B) Main part rear view of suction cleaner in embodiment 3
FIG. 7 is an explanatory diagram showing a use state of a suction cleaner in Embodiment 3.
FIG. 8 is a side cross-sectional view of a main part of a suction cleaner in Embodiment 4.
FIG. 9 is a rear cross-sectional view of the main part for explaining the overlap between a gas self-priming hole and a gas shaft in the fourth embodiment.
FIG. 10 is an explanatory diagram showing a use state of a suction cleaner in Embodiment 5.
FIG. 11 is a schematic view of a cleaning apparatus in a fifth embodiment.
FIG. 12 is a schematic diagram of a usage pattern of a suction cleaner in the sixth embodiment.
13 is a cross-sectional view of a suction cleaner in Embodiment 7. FIG.
14 is a cross-sectional view of a suction cleaner in Embodiment 8. FIG.
[Explanation of symbols]
1 Suction washer
2 body
2a Hollow part
3 Gas-liquid ejection holes
4 Liquid introduction pipe
5, 5 'gas self-priming hole
6 Gas-liquid ejection guide part
7 Outflow part
11 Suction washer
12 Pump
12a inlet
12b Discharge port
13 Suction pipe
14 Discharge pipe
15 Strainer
16 liquid tank
21 Suction washer
22 Spattering prevention part
23 Tank
23a Tank side hollow
24 Tank hole
31 Suction washer
32 body
32a Hollow part
32b opening
32c Female thread
33 Rotating member
33a Male screw part
33b Rotating shaft
34 Gas self-priming holes
35 Tank part
35a Tank side hollow
36 Tank hole
40 Suction washer
41 Suction washer
51 Cleaning device
52 Pump gas self-priming hole
53 Gas self-priming pipe
60 Suction washer
61 body
62 Hollow part
63 Gas-liquid jet hole
63a Inclined part
63b Flat part
64 Liquid introduction pipe
65 Gas self-priming holes
66 Gas-liquid ejection guide
70 Suction washer
71 body
72 Hollow part
73 Gas / Liquid Injection Hole
74 Water jet nozzle
74a Water flow adjusting member
74b Support member
74c Intermediate support member
74d Position adjustment fixing part
75 Liquid inlet tube
75a inlet
76 Gas-liquid ejection guide
77 Outflow part
78 Water recovery section
79 Water supply pipe
80 Suction washer
81 Outflow Control Department
82 Hinge
83 opening
84 Gas shaft contact plate
85 small holes
P Pressure distribution
Q Direction of flow

Claims (11)

a. A container having a hollow portion shaped to converge from the rear side toward the front side;
b. A gas-liquid ejection hole provided at the front end of the vessel, c. A liquid introduction pipe connected tangentially to the peripheral wall on the rear side of the vessel body; d. A gas-liquid jet guide portion disposed on an outer peripheral portion of the gas-liquid jet hole and expanded from the gas-liquid jet hole in the jet direction, and a front edge of the gas-liquid jet guide portion is cut away. Or a suction washer provided with an outflow part formed by opening a hole on the front side of the gas-liquid ejection guide part . From the air formed on the rear wall of the vessel body at the center of the vessel axis or by the swirling motion of the water flow in the vessel body , the tip extending toward the gas-liquid ejection hole and formed in a rod shape suction cleaner of claim 1, characterized in that it comprises an open gas self吸孔formed by the composed gas axis position eccentric. Said device body wall opening and attached screwed or fitted to the threaded portion and the engaging portion formed to the end of a, offset from the device body axis or the unit wherein the gas axis formed in the body position 3. A rotating member that is pivotably covered about the rotating member, and the gas self-priming hole is formed at a position eccentric from a rotating shaft of the rotating member. Suction washer. A tank part that covers the rear wall of the container or the rotating member and supplies gas through the gas self-priming hole, and a gas introduction hole provided in the tank part are provided. The suction washer according to claim 2 or 3. A water flow jet nozzle portion whose front end side projects from the rear wall side of the vessel body with a reduced diameter and whose front end opening portion is disposed inside the gas-liquid jet hole, and a rod-like support inserted into the water flow jet nozzle portion. A plug-like, conical, or inverted conical water flow adjusting member disposed near the nozzle tip via a member, and a rear wall side of the vessel body that supports the base end side of the support member so as to be movable forward and backward or fixed. The suction washer according to claim 1, further comprising a position adjustment fixing portion provided. The inner peripheral wall of the gas-liquid ejection hole has an inclined portion that expands at a predetermined angle toward the ejection side, and a flat portion that is formed to be connected to the front of the inclined portion. The suction washer according to any one of claims 1 to 5. The suction washer according to any one of claims 1 to 6 , further comprising a splash prevention portion provided around the front edge of the gas-liquid jet guide portion toward the rear. The suction cleaner according to claim 1 , further comprising a water flow recovery unit that recovers a water flow discharged from an outflow part of the gas-liquid jet guide part. A base end of the gas-liquid jet guide part is rotatably disposed via a hinge, and a substantially hemispherical peripheral part includes an outflow restriction part that shields the outflow part of the gas-liquid jet guide part. The suction washer according to claim 8 . A cleaning apparatus comprising: the suction cleaner according to any one of claims 1 to 9 ; and a pump that supplies a cleaning liquid to the liquid introduction pipe of the suction cleaner. . The cleaning apparatus according to claim 10 , wherein a pump gas self-priming hole for sucking a gas is provided in a suction pipe that supplies a cleaning liquid attached to a suction side of the pump.

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