JP3889732B2 - Suction device and nozzle device - Google Patents

Description

  The present invention relates to a suction device that includes a nozzle that sucks outside air and can eject a fluid to an object, and a nozzle device that sucks outside air and can eject a fluid to the object.

  Conventionally, for example, it has adhered to objects to be cleaned such as walls, ceilings, floors, bathrooms, toilets, furniture, or equipment such as ventilation fans and air conditioners, various manufacturing machines, and vehicles such as automobiles, motorcycles, and bicycles. Dirt is relatively difficult to remove and difficult to clean. In particular, oil stains or the like stuck to these objects to be cleaned are difficult to wipe off or wash away with a normal cleaning fluid.

  Therefore, in recent years, a cleaning apparatus has been proposed in which a cleaning fluid is sprayed on dirt adhering to an object to be cleaned and the dirt is removed by the spraying force of the cleaning fluid. Further, dirt that cannot be removed by the cleaning device is removed by, for example, rubbing again with a rag, scrubber, mop or the like. However, this cleaning device, for example, when cleaning dirt adhering to a horizontal surface such as a floor, and the like, the cleaning fluid sprayed on the floor etc. and the dirt removed by this cleaning fluid (hereinafter referred to as “sprayed”). The “cleaning fluid” and “dirt removed by this cleaning fluid” are sometimes simply referred to as “sewage”), and remain on the floor or the like as they are.

  Also, when cleaning dirt attached to vertical surfaces such as walls and ceilings, the cleaning fluid sprayed on these and the dirt removed by this cleaning fluid dripping or dropping, and this dirty water is removed. For example, it is necessary to wipe off with a rag. Further, when the sewage is dripped or falls in a portion that has not been soiled, it is necessary to further clean this portion. Furthermore, if plants, furniture, electrical appliances, etc. are placed under walls or ceilings where dirt should be cleaned, if the dripping or falling cleaning fluid is applied to them, the plants will die, There are also problems such as damage or breakdown of electrical appliances. Therefore, in this case, it was necessary to clean the walls, ceilings, etc. by covering the trees, furniture, electrical appliances, etc. with a cover such as a vinyl sheet so that they are not directly exposed to sewage. .

  Recently, with the rapid increase of elderly people such as bedridden people and dementia, care for them, especially treatment of excreta has become a very important concern. Until now, diapers have been used to treat the excrement of such elderly people. In other words, after excretion is completed, excrement treatment is performed by exchanging diapers regularly. However, just exchanging the diaper will leave some of the excrement attached to the body, which is a sanitary problem. Therefore, when exchanging diapers, it is necessary to remove excrement still attached to the body.

  Until now, such operations have been performed manually using commercially available cleaning products, steamed towels, and the like. That is, the fact that the caregiver is directly wiping the dirty part of the elderly person's body, that is, wiping excrement attached to the body is the actual situation. However, the excrement attached to the body is often hardened by the time the diaper is changed (it is often in a fixed state), and it takes a lot of time and labor to remove it manually. Is required.

  In view of this, the present applicant has proposed a suction device capable of easily sucking and removing the object to be sucked such as dirt as described above. (For example, refer to Patent Document 1).

In addition, various nozzle structures that are connected to such a suction device and used to suck an object to be sucked have been proposed. (For example, refer to Patent Documents 2 to 6).
JP 2001-161762 A JP 2001-245952 A JP 2001-245953 A JP 2001-261968 A JP 2001-276172 A JP 2001-299903 A

  The nozzle structures described in Patent Documents 2 to 6 described above may cause the fluid to scatter to the surroundings even when the nozzle is separated from the surface to which the suction object is adhered in a state where the fluid is being ejected during the suction operation. It has the feature of not. However, in order to realize this feature, the structure is complicated.

  An object of the present invention is to improve such a conventional suction device and nozzle device, and has a simple structure. When performing a suction operation by bringing a nozzle close to or in contact with an object. The fluid is automatically ejected from the nozzle toward the object, and the fluid that hits the object can be sucked. When the nozzle is separated from the object, the fluid is outside the nozzle. It is an object of the present invention to provide a suction device and a nozzle device capable of automatically stopping injection.

  In order to achieve this object, the present invention is a suction device having a nozzle for sucking outside air, wherein a fluid nozzle for ejecting fluid toward the nozzle opening end is provided in the nozzle, and the opening of the nozzle is opened. In this case, the fluid ejected from the fluid nozzle is pushed back by the outside air sucked into the nozzle from the nozzle opening, and is sucked to the proximal end side of the nozzle without being ejected to the outside from the nozzle opening. When the amount of outside air sucked into the nozzle is reduced by bringing the nozzle opening close to or in contact with an object, the fluid ejected from the fluid nozzle overcomes the outside air, and The present invention provides a suction device which is configured to be jetted onto an object and sucked together with the outside air after hitting the object.

  The suction device having this configuration can automatically eject the fluid from the nozzle toward the object by a simple operation of bringing the nozzle close to or in contact with the object. It is possible to suck the fluid that hits. Further, the fluid can be automatically stopped from being ejected outside the nozzle simply by moving the nozzle away from the object.

  In the vicinity of the opening of the nozzle, at least one small hole capable of taking outside air into the nozzle can be formed.

  By forming such a small hole, even when the nozzle is brought into close contact with the object and the inside of the nozzle becomes a negative pressure, the outside air can be taken into the nozzle from the small hole. Accordingly, the nozzle can be moved smoothly with respect to the object, and the sewage can be collected smoothly.

  Moreover, the suction device according to the present invention can be configured such that the fluid ejection port of the fluid nozzle is located on the back side of the opening of the nozzle.

  In the suction device according to the present invention, when the opening of the nozzle is opened, the pressure of the outside air according to the amount of outside air sucked into the nozzle between the opening of the nozzle and the fluid ejection port. However, when the pressure of the fluid ejected from the fluid nozzle is overcome and the amount of outside air sucked into the nozzle is reduced, the fluid nozzle ejects between the nozzle opening and the fluid ejection port. It is possible to adjust at least one of the amount of outside air and the pressure of fluid so that the pressure of the fluid thus obtained exceeds the pressure of outside air according to the amount of outside air sucked into the nozzle.

  Furthermore, the suction device according to the present invention determines the cross-sectional area of the opening of the nozzle according to the pressure of the fluid ejected from the fluid nozzle, and controls the amount of outside air sucked into the nozzle. it can.

  The suction device according to the present invention may be configured such that the fluid ejection port is configured to open from the nozzle opening according to the pressure of the outside air according to the amount of outside air sucked into the nozzle and the pressure of the fluid ejected from the fluid nozzle. The distance to can also be determined.

  In addition, the suction device according to the present invention is configured to suck the fluid ejected from the fluid nozzle when the amount of outside air sucked into the nozzle is reduced and adhere to the object and the object. It can also be configured such that the object to be sucked can be sucked together with the outside air and the fluid that has hit the object and the object to be sucked.

  Furthermore, in the suction device according to the present invention, brush hairs can be detachably disposed at the opening side tip of the nozzle. In this way, by attaching brush bristles to the opening end of the nozzle, in addition to the above-mentioned advantages, when the fluid is ejected to the suction object such as dirt attached to the object, the suction object is removed. Further, the removal of the suction object can be promoted by scraping or rubbing the suction object.

  In the suction device according to the present invention, an elastic member may be detachably disposed at the opening-side tip of the nozzle.

  The present invention also includes a nozzle connected to a suction device, and a fluid nozzle that is provided in the nozzle and connected to the fluid ejecting device and ejects fluid toward the nozzle opening end. When the opening is opened, the fluid ejected from the fluid nozzle is pushed back by the outside air sucked into the nozzle from the nozzle opening, and the base end of the nozzle is not ejected to the outside from the nozzle opening. When the amount of outside air sucked into the nozzle is reduced by bringing the nozzle opening close to or in contact with an object and the amount of outside air sucked into the nozzle is reduced, the fluid nozzle overcomes the outside air. In addition, the present invention provides a nozzle device that is configured to be jetted onto the object and to be sucked together with the outside air after hitting the object.

  The nozzle device having this configuration can automatically inject fluid toward the object simply by bringing the nozzle close to or in contact with the object. Further, the fluid can be automatically stopped from being ejected outside the nozzle simply by moving the nozzle away from the object.

  In addition, the nozzle device according to the present invention can form at least one small hole in the vicinity of the nozzle opening that can take outside air into the nozzle.

  In addition, the nozzle device according to the present invention can be configured such that the fluid ejection port of the fluid nozzle is located on the back side of the opening of the nozzle.

  Furthermore, in the nozzle device according to the present invention, brush hairs can be detachably disposed at the opening side tip of the nozzle.

  Furthermore, in the nozzle device according to the present invention, an elastic member can be detachably disposed at the opening end of the nozzle.

  The suction device according to the present invention has a simple structure, and when performing a suction operation, the fluid is automatically directed from the nozzle to the object by a simple operation of bringing the nozzle close to or in contact with the object. And the fluid that has hit the object can be sucked. In addition, it is possible to automatically stop the fluid from being ejected outside the nozzle simply by moving the nozzle away from the object.

  Further, the nozzle device according to the present invention has a simple structure, and when performing a suction operation, the fluid is automatically directed to the object by a simple operation of bringing the nozzle close to or in contact with the object. And the fluid that has hit the object can be sucked. In addition, it is possible to automatically stop the fluid from being ejected outside the nozzle simply by moving the nozzle away from the object.

  Next, a suction device and a nozzle device according to a preferred embodiment of the present invention will be described with reference to the drawings. In addition, embodiment described below is the illustration for demonstrating this invention, and this invention is not limited only to these embodiment. Therefore, the present invention can be implemented in various forms without departing from the gist thereof.

  1 is a schematic view of a suction device to which a nozzle device according to a first embodiment is attached, FIG. 2 is a perspective view of the nozzle device shown in FIG. 1, and FIG. 3 is an enlarged cross-sectional view of a main part of the nozzle device shown in FIG. FIG. 4 is a diagram showing a state in which the suction device is operating and the opening of the nozzle device is released, and FIG. 4 is an enlarged cross-sectional view of the main part of the nozzle device shown in FIG. It is a figure which shows the state by which the opening of the nozzle apparatus is closed by the target object while is operating.

  In addition, Example 1 demonstrates the case where water is used as a fluid and a wall is used as a target object.

  As illustrated in FIGS. 1 to 4, the suction device 1 according to the first embodiment includes a suction device body 100 and a nozzle device 10 that is detachably attached to the suction device body 100.

  As shown in FIG. 1, the suction device main body 100 is connected to a main tank 120 capable of storing water 200 as a fluid therein, and the inside of the main tank 120, and filters the water 200 stored in the main tank 120. A filter 121 provided with a filter 127, a pump 132 connected to the filter 121 and pumping up the water 200 filtered by the filter 121, and a water 200 pumped up by the pump 132 connected to the pump 132 to the outside. The fluid supply tube 102 to be supplied and the main tank 120 are connected to the main tank 120 and the suction hose 101 for collecting the water 200 sprayed on the wall 150 together with the outside air 300 into the main tank 120. A fan motor 141 that sucks air in the tank 120 (outside air) and the main tank 120 The heater 160 that controls the temperature of the water 200 supplied from the main tank 120 via the filter 121, the control panel 170 that controls the operation of the suction device main body 100, and the base on which these are mounted and moved 180.

  The main tank 120 can be sealed, has a substantially cylindrical shape with a substantially central portion hollow, and has a strength that can withstand suction by the fan motor 141. On the upper surface (ceiling surface) of the main tank 120, a separator 143 that separates the gas-liquid mixed fluid introduced from the main tank 120 into a gas and a liquid according to a cyclone principle is disposed. The separated gas is sucked through the duct 130 by the fan motor 141. With this configuration, water droplets are prevented from entering the fan motor 141. Further, on the wall surface of the main tank 120, a liquid level gauge 123 capable of visually checking the amount of water 200 contained therein, a fluid supply tube 102, and a hook 124 capable of hooking the suction hose 101 are provided. .

  The filter 121 is communicated with the main tank 120 via a connection hose 128, a tank 126 to which water 200 accommodated in the main tank 120 is supplied via the connection hose 128, and accommodated in the tank 126, A filter 127 for filtering 200 is provided. The filter 121 is connected to the pump 132.

  The pump 132 pumps up the water 200 accommodated in the filter 121 and filtered by the filter 127 and supplies the water 200 from the tip of the fluid supply tube 102 to the fluid nozzle 12 of the nozzle device 10 described in detail later. A pressure control device 133 that controls the pressure (water pressure) of water 200 supplied to the fluid nozzle 12 is connected to the pump 132. The pressure control device 133 can arbitrarily control the pressure when the water 200 (hot water) is jetted onto the wall 150.

  For example, the pressure control device 133 may switch the pressure of the water 200 supplied to the fluid nozzle 12 to several stages such as strongest, strong, medium-strong, medium, medium-weak, weak, and weakest. It may be finely controlled. This set pressure can also be set to be maintained unless deliberately changed. Further, the operation of the pressure control device 133 may be performed by, for example, a changeover switch (not shown) provided on the control panel 170, or may be remotely operated by a controller or the like.

  The base end of the fluid supply tube 102 is connected to the filter 127 of the filter 121 via the heater 160 and the pump 132. The tip of the fluid supply tube 102 can be connected to the fluid nozzle 12 of the nozzle device 10 described in detail later. The fluid supply tube 102 is fixed to the suction hose 101 by a fastener 134.

  The suction hose 101 has a proximal end connected to the main tank 120 and is configured to suck the outside air 300 into the main tank 120 by suction by the fan motor 141. Moreover, the front-end | tip of the suction hose 101 can be connected to the nozzle 11 of the nozzle apparatus 10 explained in full detail later.

  The fan motor 141 is connected to a suction control device 142 that controls the suction vacuum degree (suction force). The suction control device 142 can arbitrarily control the suction amount (air volume) of the outside air 300 sucked from the opening 13 of the nozzle 11 attached to the tip of the suction hose 101, and by controlling the suction force, The pressure of the outside air 300 corresponding to the amount of outside air sucked from the tip of the nozzle 11 and the water pressure when the water 200 is jetted are balanced, and the water 200 is externally supplied from the opening 13 of the nozzle 11 by the pressure of the sucked outside air 300. It can play a role of preventing release.

  In the nozzle device 10, an opening 13 capable of sucking outside air 300 is formed at the tip, a nozzle 11 that can be connected to the suction hose 101 at a base end, and the nozzle 200 is disposed in the nozzle 11, and the water 200 is directed toward the opening end of the nozzle 11. And a fluid nozzle 12 that ejects the fluid.

  The nozzle 11 includes a large-diameter portion 14 having a substantially cylindrical shape that can be connected to the suction hose 101, and a substantially cylindrical small-diameter portion formed continuously from the large-diameter portion 14 and having a smaller diameter than the large-diameter portion 14. 15. The large diameter portion 14 has a hollow structure, and the fluid nozzle 12 is disposed in the hollow portion. The small-diameter portion 15 has a hollow shape communicating with the hollow portion of the large-diameter portion 14, and water 200 ejected from the fluid nozzle 12 can be ejected to the outside from the opening 13 formed at the tip.

  In Example 1, the inner diameter of the small diameter portion 15, that is, the diameter of the opening 13 (ID: see FIG. 3) was set to 10 mm, and the length (SL: see FIG. 3) was set to 110 mm. A small hole 16 through which the outside air 300 can be introduced into the nozzle 11 is formed at the tip of the small diameter portion 15 (in the vicinity of the opening 13). In Example 1, the diameter (SD: see FIG. 3) of the small hole 16 was set to 1.5 mm.

  The fluid nozzle 12 includes an ejection port 17 for ejecting water 200 at the distal end, and a proximal end can be connected to the fluid supply tube 102. The injection port 17 faces the hollow portion of the small diameter portion 16, and the water 200 injected from the injection port 17 is discharged from the opening 13 through the hollow portion of the small diameter portion 15.

  In Example 1, the disposition position of the fluid nozzle 12 is set so that the distance (ML: see FIG. 3) between the injection portion 17 and the boundary portion between the large diameter portion 14 and the small diameter portion 15 is 10 mm. Set. Moreover, the opening diameter of the injection part 17 was set to about 0.5 mm.

  Next, a specific operation of the suction device 1 according to the first embodiment will be described.

  First, the nozzle 11 of the nozzle device 10 is connected to the tip of the suction hose 101 of the suction device body 100, the fluid nozzle 12 of the nozzle device 10 is connected to the tip of the fluid supply tube 102, and the nozzle is connected to the suction device body 100. Install the device 10.

Next, after storing a predetermined amount of water 200 in the main tank 120, the fan motor 141 is driven by operating the control panel 170. In Example 1, the suction controller 142 was set so that the suction vacuum degree of the fan motor 141 was about 19 kPa. By driving the fan motor 141, the outside air 300 is sucked from the opening 13 of the nozzle 11 provided at the tip of the suction hose 101. At this time, the amount of outside air sucked from the opening 13 of the nozzle 11 was about 1.0 m ³ / min. By sucking the outside air 300, the air in the main tank 120 is introduced into the separator 143. Here, even if the water 200 is mixed in the air, the separator 143 is separated into gas (air) and liquid (water 200) by the cyclone principle, and the water 200 is sucked into the fan motor 141. It is supposed not to be. Outside air (air) sucked by the fan motor 141 passes through the fan motor 141 via the duct 130 and is discharged to the outside through a predetermined exhaust port.

  At the same time, the control panel 170 is operated to drive the pump 132. By driving the pump 132, the water 200 accommodated in the filter 121 is pumped up and kept at a desired temperature by the heater 160. The warmed water (warm water) 200 passes through the fluid supply tube 102. The fluid nozzle 12 is supplied. In Example 1, the pressure control device 133 was set so that the water pressure of the pump 132 was about 0.3 MPa. At this time, the flow rate of the water 200 ejected from the ejection port 17 of the fluid nozzle 12 was about 50 liters / hour.

  In a state where the opening 13 of the nozzle 11 is open (see FIG. 3), that is, a state where the opening 11 is separated from the wall 150, the outside air 300 sucked into the nozzle 11 from the opening 13 of the nozzle 11 and the fluid nozzle 12. The water 200 jetted from the water collides between the jet port 17 of the fluid nozzle 12 and the opening 13 of the nozzle 11, and the outside air 300 overcomes the water 200 jetted from the fluid nozzle 12, so that the water 200 flows into the nozzle 11. The water 200 is sucked together with the outside air 300 without being jetted to the outside through the opening 13 and is collected in the main tank 120. Therefore, in order to block the progress of the water 200 as in the past, for example, the water 200 injected from the fluid nozzle 12 without adding a complicated structure to the nozzle device 10 such as installing a blocking plate or the like, The progression of the water 200 can be blocked by the sucked outside air 300 so that it is not sprayed from the opening 13 of the nozzle 11 to the outside. For this reason, the configuration of the nozzle can be simplified, the failure rate can be reduced, and the nozzle can be manufactured at low cost.

Next, when the opening 13 of the nozzle 11 is brought close to or in contact with the wall 150 (see FIG. 4) while maintaining the suction vacuum level of the fan motor 141 and the pump water pressure of the pump 132 (see FIG. 4), the suction is performed in the nozzle 11. The amount of outside air to be reduced is smaller than when the opening 13 of the nozzle 11 is opened. At this time, the amount of outside air sucked into the nozzle 11 was about 0.05 m ³ / min. Here, even if the opening 13 is brought into close contact with the wall 150, the outside air 300 is introduced into the nozzle 11 from the small hole 16, so that the nozzle device 10 can be moved smoothly and the sewage can be collected smoothly. . Due to the decrease in the amount of outside air sucked into the nozzle 11, the water 200 ejected from the fluid nozzle 12 overcomes the outside air 300 sucked into the nozzle 11 and is ejected onto the wall 150. Then, the water 200 hitting the wall 150 is sucked and collected into the main tank 120 through the suction hose 101 together with the outside air 300.

  Further, when dirt or the like is attached to the wall 150, the dirt is peeled off by the water 200 sprayed on the wall 150, and is sucked into the main tank 120 through the suction hose 101 together with the water 200 and the outside air 300. Collected. Therefore, the water 200 sprayed onto the wall 150 can be easily and surely removed by suction without dripping or falling and wetting the user's clothes, bedding, or floor. it can.

  As a result of the above operation, the recovered liquid and the clean water 200 stored from the beginning coexist in the main tank 120. The water 200 stored in the main tank 120 and the water 200 collected in the main tank 120 are supplied to the filter 121 by the operation of the pump 132, and are filtered by the filter 127 from the fluid supply tube 102. The fluid nozzle 12 is supplied again.

  From this state, when the opening 13 of the nozzle 11 is separated from the wall 150 (opening the opening 13 of the nozzle 11), the amount of outside air sucked into the nozzle 11 again from the opening 13 increases, and the sucked outside air 300, The water 200 ejected from the fluid nozzle 12 collides between the ejection port 17 of the fluid nozzle 12 and the opening 13 of the nozzle 11, and the outside air 300 overcomes the water 200 ejected from the fluid nozzle 12, The air is sucked together with the outside air 300 without being jetted from the opening 13 of the nozzle 11, and these are collected in the main tank 120.

  In addition, although Example 1 demonstrated the case where water (warm water) was used as a fluid, it is not restricted to this, For example, as a fluid, water vapor | steam, alkaline washing | cleaning liquid, or more powerful strong alkaline washing | cleaning liquid, a bleaching agent, mold, etc. Chlorine-based cleaning liquid such as a remover, neutral detergent, alcohol-based disinfectant, lotion, beauty liquid, moisturizing liquid, aroma (aroma) agent-containing solution, steam, etc. Can do. Of course, the conditions such as the temperature and the injection amount of these fluids can also be appropriately selected according to the type of fluid and the purpose of use.

  In the first embodiment, the inner diameter (ID) of the small diameter portion 15, that is, the case where the inner diameter of the opening 13 is set to 10 mm and the length (SL) is set to 110 mm is not limited thereto. When the opening 13 of the nozzle 11 is opened, the outside air 300 sucked into the nozzle 11 from the opening 13 of the nozzle 11 is ejected from the fluid nozzle 12 with respect to the inner diameter (ID) and the length (SL). The water 200 can be sucked together with the outside air 300 without jetting the water 200 from the opening 13 of the nozzle 11 to the outside, and the nozzle 13 is brought close to or in contact with the wall 150. When the amount of outside air sucked in is reduced, the water 200 ejected from the fluid nozzle 12 overcomes the outside air 300 and is ejected to the wall 150, and the wall 150 Water 200 striking so as to be capable of sucking with the outside air 300 may be determined arbitrarily according to the water pressure of the water 200 sprayed from the fluid nozzle 12.

  In the present invention, the suction vacuum degree of the fan motor 141 is set to about 19 kPa, and the water pressure of the pump 132 is set to about 0.3 MPa. However, the present invention is not limited to this. The suction vacuum degree of the fan motor 141 and the pump water pressure of the pump 132 can suck the water 200 together with the outside air 300 without ejecting the water 200 from the opening 13 of the nozzle 11 when the opening 13 of the nozzle 11 is opened. When the opening 13 of the nozzle 11 is brought close to or in contact with the wall 150 to reduce the amount of outside air sucked into the nozzle 11, the water 200 injected from the fluid nozzle 12 is injected to the wall 150. As long as the water 200 hitting the wall 150 can be sucked, it can be arbitrarily determined.

  In the first embodiment, the case where the diameter of the small hole 16 is set to 1.5 mm has been described. However, the diameter is not limited to this, and the diameter of the small hole 16 is determined when the opening 13 of the nozzle 11 is brought into close contact with the wall 150. The nozzle 11 can be moved smoothly with respect to the wall 150, and when the opening 13 of the nozzle 11 is opened, the water 200 can be sucked together with the outside air 300 without being jetted outside from the opening 13 of the nozzle 11. When the opening 13 of the nozzle 11 is brought close to or in contact with the wall 150 to reduce the amount of outside air sucked into the nozzle 11, the water 200 ejected from the fluid nozzle 12 is against the wall 150. If the water 200 that has been sprayed and hits the wall 150 can be sucked, it can be arbitrarily determined. Similarly, the number of small holes 16 can be determined arbitrarily.

  In addition, for example, when an object such as a curtain that allows a certain amount of outside air to pass through or an object having an uneven surface is adopted as the object, even if the nozzle 11 is brought into close contact with the object, Since a certain amount of outside air is introduced, the small holes 16 are not necessarily provided.

  Moreover, in Example 1, although the case where the opening diameter of the injection part 17 was set to about 0.5 mm was demonstrated, not only this but the opening diameter of the injection part 17 is when the opening 13 of the nozzle 11 is open | released. The water 200 can be sucked together with the outside air 300 without being jetted outside from the opening 13 of the nozzle 11, and the amount of outside air sucked into the nozzle 11 by bringing the opening 13 of the nozzle 11 close to or in contact with the wall 150. Can be arbitrarily determined as long as the water 200 sprayed from the fluid nozzle 12 is sprayed to the wall 150 and the water 200 hitting the wall 150 can be sucked.

  Further, the shape and size of the nozzle 11 are not limited to those described in the first embodiment. For example, as shown in FIG. You may decide on. Also, the shape of the fluid nozzle 12 can be arbitrarily determined according to the shape of the nozzle 11 as shown in FIG.

  As another embodiment, as shown in FIG. 6, a small-diameter cylindrical convex portion 21 is formed at the tip of the small-diameter portion 15 of the nozzle 11, and the attachment 20 is detachably provided on the convex portion 21. May be. The attachment 20 has an attachment portion 22 on the base end side to which the projection 21 of the nozzle 11 is detachably attached. Brush hairs 23 are planted on the front end surface of the attachment portion 22, and a rubber sheet 24 is attached to the outer peripheral surface of the attachment portion 22 so as to surround the brush hairs 23.

  The brush bristles 23, for example, bring the nozzle 11 close to or in contact with the wall 150, and spray the water 200 onto an object to be sucked such as dirt adhering to the wall 150. This is for facilitating the removal of the suction object by scraping or rubbing the suction object.

  Further, the rubber sheet 24 plays a role of reducing the amount of outside air sucked into the nozzle 11 when the nozzle 11 is brought close to or in contact with the wall 150. That is, in the attachment in which only the brush hairs 23 are implanted, it is difficult to reduce the amount of the outside air that the outside air 300 enters freely between the brush hairs 23 and is sucked into the nozzle 11. Is surrounded by the rubber sheet 24, the amount of outside air sucked into the nozzle 11 can be easily reduced. Here, the rubber sheet 24 has an appropriate elastic force and flexibility and can follow the movement of the brush bristles 23. Therefore, the rubber sheet 24 can be used to scrape the sucked object with the bristles 23 or to rub it. There will be no hindrance.

  Next, Example 2 according to the present invention will be described with reference to the drawings.

  FIG. 7 is a cross-sectional view of the nozzle device according to the second embodiment, showing a state in which the suction device is operating and the opening of the nozzle device is released, and FIG. 8 is the nozzle shown in FIG. FIG. 9 is a cross-sectional view of the device, showing a state where the suction device is operating and the opening of the nozzle device is closed by an object, and FIG. 9 is a front view of the nozzle device shown in FIG.

  In the second embodiment, the same members as those described in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIGS. 7 to 9, the nozzle device 30 according to the second embodiment is different from the nozzle device 10 according to the first embodiment in the shape of the nozzle 31. The nozzle device 30 has an opening 33 capable of sucking the outside air 300 at the tip, a nozzle 31 that can be connected to the suction hose 101 at the base end, and the nozzle 31, and water 200 at the opening end of the nozzle 31. And a fluid nozzle 12 that injects the fluid.

  The nozzle 31 includes a cylindrical portion 34 having a substantially cylindrical shape that can be connected to the suction hose 101, and a substantially fan-shaped fan portion that is formed continuously with the cylindrical portion 34 and increases in diameter from the cylindrical portion 34 toward the tip. 35.

  The cylindrical portion 34 has a hollow structure, and the fluid nozzle 12 is disposed in the hollow portion. The tip of the fluid nozzle 12 extends to the base end of the fan portion 35. The fan portion 35 has a hollow shape communicating with the hollow portion of the cylindrical portion 34, and water 200 jetted from the extension of the tip of the fluid nozzle 12 can be jetted to the outside from the opening 33 formed at the tip. ing. As shown in FIG. 9, the opening 33 has a substantially rectangular shape. Further, two small holes 16 into which the outside air 300 can be introduced into the nozzle 11 are formed at the tip of the fan portion 35 (in the vicinity of the opening 33).

  In Example 2, the fan angle (α: see FIG. 7) of the fan part 35 is set to 115 degrees, the long side (LS: see FIG. 9) of the opening 33 is 100 mm, and the short side (SS: see FIG. 9). ) Was set to 4 mm. Moreover, the distance (FL: refer FIG. 7) from the injection port 17 of the fluid nozzle 12 to the opening 33 was set to 45 mm. The diameter of the small hole 16 (SD: see FIG. 7) was set to 1 mm.

  Next, a specific operation of the suction device 1 according to the second embodiment will be described.

  First, as in the first embodiment, the nozzle 31 of the nozzle device 30 is connected to the tip of the suction hose 101 of the suction device body 100, and the fluid nozzle 12 of the nozzle device 30 is connected to the tip of the fluid supply tube 102. The nozzle device 30 is attached to the suction device main body 100.

  Next, the fan motor 141 is driven under the same conditions as in the first embodiment, and the outside air 300 is sucked from the opening 33 of the nozzle 31 provided at the tip of the suction hose 101. At the same time, the pump 132 is driven to supply water (warm water) 200 to the fluid nozzle 12 via the fluid supply tube 102.

In Example 2, the water pressure of the pump 132 was set to about 3 kg / cm ² by the pressure control device 133. At this time, the water 200 injected from the injection port 17 of the fluid nozzle 12 had an injection angle of 115 degrees, and the injection amount was about 0.4 liters / minute.

  In the state where the opening 33 of the nozzle 31 is open (see FIG. 7), that is, the state where the opening is separated from the wall 150, the nozzle 31 is sucked into the nozzle 31 from the opening 33 of the nozzle 31 as in the first embodiment. The outside air 300 and the water 200 ejected from the fluid nozzle 12 collide between the ejection port 17 of the fluid nozzle 12 and the opening 33 of the nozzle 31, and the outside air 300 overcomes the water 200 ejected from the fluid nozzle 12. The water 200 is sucked together with the outside air 300 without being jetted from the opening 33 of the nozzle 31, and these are collected in the main tank 120.

  Next, when the suction vacuum degree of the fan motor 141 and the pump water pressure of the pump 132 are maintained, the opening 33 of the nozzle 31 is brought close to or in contact with the wall 150 (see FIG. 8). Further, the amount of outside air sucked into the nozzle 31 is smaller than when the opening 33 of the nozzle 31 is opened, and the water 200 ejected from the fluid nozzle 12 overcomes the outside air 300 sucked into the nozzle 31. And sprayed on the wall 150. Then, the water 200 hitting the wall 150 is sucked and collected into the main tank 120 through the suction hose 101 together with the outside air 300. When dirt or the like adheres to the wall 150, the dirt is peeled off by the water 200 sprayed on the wall 150 and, together with the water 200 and the outside air 300, through the suction hose 101 as in the first embodiment. It is sucked and collected in the main tank 120.

  From this state, when the opening 33 of the nozzle 31 is separated from the wall 150 (opening the opening 33 of the nozzle 31), the amount of outside air sucked into the nozzle 31 from the opening 33 increases again, and the sucked outside air 300, The water 200 ejected from the fluid nozzle 12 collides between the ejection port 17 of the fluid nozzle 12 and the opening 33 of the nozzle 31, and the outside air 300 overcomes the water 200 ejected from the fluid nozzle 12, The air is sucked together with the outside air 300 without being jetted from the opening 33 of the nozzle 11, and these are collected in the main tank 120.

  If the nozzle 31 provided with this configuration is used, the water 200 can be sprayed over a wide range of the wall 150, and an efficient suction operation can be performed.

  In the second embodiment, the fan angle 35 of the fan portion 35 is set to 115 degrees, the long side (LS: see FIG. 9) of the opening 33 is set to 100 mm, and the short side (SS: see FIG. 9) is set to 4 mm. However, the fan angle, the long side, and the short side are not limited thereto, and the outside air 300 sucked into the nozzle 31 from the opening 33 of the nozzle 31 when the opening 33 of the nozzle 31 is opened is a fluid nozzle. 12, the water 200 can be sucked together with the outside air 300 without being jetted outside through the opening 33 of the nozzle 31, and the opening 33 of the nozzle 31 is brought close to or in contact with the wall 150. When the amount of the outside air sucked into the nozzle 31 is reduced, the water 200 ejected from the fluid nozzle 12 overcomes the outside air 300 and is ejected to the wall 150 and the water 200 hitting the wall 150 The So as to be capable argument can be arbitrarily determined according to the water pressure of the water 200 sprayed from the fluid nozzle 12.

  Further, the nozzle device 30 according to the second embodiment can also be provided with an attachment as shown in FIG.

It is the schematic of the suction device with which the nozzle apparatus concerning Example 1 of this invention was attached. It is a perspective view of the nozzle apparatus shown in FIG. It is a principal part expanded sectional view of the nozzle apparatus shown in FIG. 1, Comprising: While the suction device is operating, it is a figure which shows the state by which the opening of a nozzle apparatus is open | released. It is a principal part expanded sectional view of the nozzle apparatus shown in FIG. 1, Comprising: While the suction device is operating, it is a figure which shows the state by which the opening of a nozzle apparatus is closed by the target object. It is a perspective view of the nozzle apparatus concerning the other Example of this invention. It is sectional drawing of the attachment attached to the front-end | tip of the nozzle apparatus concerning the other Example of this invention. It is sectional drawing of the nozzle apparatus concerning Example 2 of this invention, Comprising: While the suction device is act | operating, it is a figure which shows the state by which the opening of a nozzle apparatus is open | released. It is sectional drawing of the nozzle apparatus shown in FIG. 7, Comprising: While the suction device is operating, it is a figure which shows the state by which the opening of a nozzle apparatus is closed by the target object. It is a front view of the nozzle apparatus shown in FIG. It is sectional drawing along the XX line shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Suction device 11, 31 Nozzle 12 Fluid nozzle 13, 33 Opening 20 Attachment 100 Suction device 101 Suction hose 102 Fluid supply tube 120 Main tank 121 Filter 132 Pump 141 Fan motor

Claims (14)

A suction device having a nozzle for sucking outside air,
A fluid nozzle that ejects fluid toward the nozzle opening end is provided in the nozzle,
When the nozzle opening is opened, the fluid ejected from the fluid nozzle is pushed back by the outside air sucked into the nozzle from the nozzle opening, and the nozzle is not ejected to the outside from the nozzle opening. Is sucked to the base end side of
When the amount of outside air sucked into the nozzle is reduced by bringing the nozzle opening close to or in contact with the object, the fluid ejected from the fluid nozzle overcomes the outside air, and the object And a suction device configured to be sucked together with the outside air after hitting the object.   The suction device according to claim 1, wherein the nozzle is formed with at least one small hole capable of taking outside air into the nozzle in the vicinity of the opening.   The suction device according to claim 1, wherein the fluid ejection port of the fluid nozzle is located on the back side of the opening of the nozzle. When the opening of the nozzle is opened, the pressure of the outside air corresponding to the amount of outside air sucked into the nozzle between the opening of the nozzle and the fluid ejection port is the pressure of the fluid ejected from the fluid nozzle. Over pressure,
When the amount of outside air sucked into the nozzle is reduced, the pressure of the fluid ejected from the fluid nozzle between the nozzle opening and the fluid ejection port is the outside air sucked into the nozzle. To overcome the pressure of the outside air according to the amount,
The suction device according to claim 3, wherein at least one of the outside air amount and the fluid pressure is adjusted.   5. The method according to claim 1, wherein a cross-sectional area of the opening of the nozzle is determined in accordance with a pressure of the fluid ejected from the fluid nozzle, and the amount of outside air sucked into the nozzle is controlled. The suction device described.   The distance from the opening of the nozzle to the fluid ejection port is determined according to the pressure of the outside air according to the amount of outside air sucked into the nozzle and the pressure of the fluid ejected from the fluid nozzle. The suction device according to any one of claims 1 to 5.   When the amount of outside air sucked into the nozzle is reduced, the fluid jetted from the fluid nozzle is jetted onto the object and the suction object attached to the object, and the suction object is The suction device according to any one of claims 1 to 6, wherein the suction device can suck together with the outside air and a fluid that has hit the object and the suction target.   The suction device according to any one of claims 1 to 7, wherein brush hairs are detachably disposed at an opening-side tip of the nozzle.   The suction device according to any one of claims 1 to 8, wherein an elastic member is detachably disposed at an opening-side tip of the nozzle. A nozzle connected to a suction device;
A fluid nozzle that is provided in the nozzle and is connected to a fluid ejection device and ejects fluid toward the nozzle opening end;
With
When the nozzle opening is opened, the fluid ejected from the fluid nozzle is pushed back by the outside air sucked into the nozzle from the nozzle opening, and the nozzle is not ejected to the outside from the nozzle opening. Is sucked to the base end side of
When the amount of outside air sucked into the nozzle is reduced by bringing the nozzle opening close to or in contact with the object, the fluid ejected from the fluid nozzle overcomes the outside air, and the object And a nozzle device configured to be sucked together with the outside air after hitting the object.   The nozzle device according to claim 10, wherein the nozzle is formed with at least one small hole capable of taking outside air into the nozzle in the vicinity of the opening.   The nozzle device according to claim 10 or 11, wherein a fluid ejection port of the fluid nozzle is located on a deeper side than an opening of the nozzle.   The nozzle device according to any one of claims 10 to 12, wherein a brush bristle is detachably disposed at an opening-side tip of the nozzle.   The nozzle device according to any one of claims 10 to 13, wherein an elastic member is detachably disposed at an opening-side tip of the nozzle.