JP2014200737A - Fluid ejection gun - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate maintenance, and change an ejection form of a fluid significantly.SOLUTION: A fluid ejection device includes: a gun main body 11 having a first male screw 16, a liquid discharge port 27 which communicates with a tank, is opened in a center of a tip end part 15, and has a second male screw 29 formed on an outer circumference, and a gas discharge port 31 which communicates with a connection part connected to a gas supply source and is opened around the liquid discharge port 27 on the tip end part 15; and a cylindrical cover 71 which is screwed with the first male screw 16 by a first female screw 74 on a one end inner circumference side, passes gas discharged from the gas discharge port 31, and includes a second female screw 75 on an inner circumference side of the other end and a third male screw 76 formed on an outer circumference side of the other end. A liquid nozzle 85 or a dispersion nozzle can be alternatively screwed with the second male screw 29. A gas nozzle 105, in which the liquid nozzle 85 is inserted inside, can be screwed with the second female screw 75 of the cover 71. A cylindrical guide member 115 or a foam emitting member can be alternatively screwed with the third male screw 76 of the cover 71.

Description

  The present invention relates to a fluid ejection gun.

  A flexible jet nozzle composed of a gas nozzle and a liquid nozzle inside the gas nozzle is provided, and gas is jetted to the outside from between the gas nozzle and the liquid nozzle. There is a fluid ejection gun that swirls along and injects a liquid in a tank provided in the gun from a liquid nozzle with a negative pressure generated by the gas ejection and mixes it with the gas (see, for example, Patent Document 1).

JP 2012-30162 A

  By the way, in the above-described fluid ejection gun, the inner nozzle through which the liquid passes may be clogged, and when clogging occurs, maintenance for solving this is not easy. Moreover, the ejection form of the fluid could not be changed greatly.

  Accordingly, an object of the present invention is to provide a fluid ejection gun that is easy to maintain and can greatly change the fluid ejection mode.

  In order to achieve the above object, the invention according to claim 1 includes a grip portion, a first male screw formed on an outer periphery of a tip portion on the opposite side of the grip portion, and the first male screw side of the grip portion. A lever that is arranged in parallel, a tank that stores liquid, a connecting portion that is connected to a gas supply source, a liquid that communicates with the tank and that opens to the center of the tip and has a second male screw formed on the outer periphery. The exhaust port, a gas exhaust port communicating with the connection portion and opening around the liquid discharge port at the tip portion, and the lever being operated, the communication between the connection portion and the gas exhaust port. A gun body having a gas supply switching unit that switches between shut-off, a liquid supply switching unit that switches communication / blocking between the tank and the liquid discharge port by operating the lever, and a first inner peripheral side 1 female screw Therefore, a cylindrical cover in which a gas screwed into the first male screw and discharged from the gas discharge port is passed, a second female screw is formed on the inner peripheral side of the other end, and a third male screw is formed on the outer peripheral side of the other end, The second male screw has a flexible tubular liquid nozzle through which the liquid discharged from the liquid discharge port can be screwed at a third female screw on the inner peripheral side, and the liquid discharge port A dispersion nozzle that disperses the liquid discharged from the first end can be screwed into a fourth female screw on the inner peripheral side of the one end. The second female screw of the cover is inserted into the liquid nozzle and is connected to the liquid nozzle. A flexible tubular gas nozzle through which the gas discharged from the gas discharge port passes can be screwed into the fourth male screw on the outer peripheral end, and the third male screw of the cover has a Rotation of the gas nozzle A cylindrical guide member that guides the liquid can be screwed into the fifth female screw on the inner peripheral side of one end, and a detergent as a liquid discharged from the liquid discharge port and dispersed by the dispersion nozzle is foamed from the discharge port. It is characterized in that the foaming discharge member to be discharged can be screwed into the sixth female screw on the inner peripheral side at one end.

  According to a second aspect of the present invention, a seventh female screw is formed at the discharge port of the foam discharge member, and the seventh female screw has a cylindrical opening formed with a flat opening that is wider toward the tip at one end side. The discharge nozzle can be screwed into the fifth male screw on the outer peripheral side of the other end.

  According to the first aspect of the present invention, the flexible tubular liquid nozzle that allows the liquid discharged from the liquid discharge port to pass through the second male screw formed on the outer periphery of the liquid discharge port of the gun body has an inner peripheral end. Since the third female screw on the side can be screwed, the liquid nozzle can be easily removed from the gun body by releasing this screwing. Therefore, when the liquid nozzle is clogged, it can be replaced with a liquid nozzle without clogging or removed and cleaned, so that maintenance is facilitated.

  In addition, the liquid nozzle is screwed to the second male screw of the liquid discharge port of the gun body at the third female screw, and the gas nozzle is screwed to the second female screw of the cover at the fourth male screw, so that the liquid is placed inside the cover and the gas nozzle. While the nozzle is inserted, the cover is screwed into the first male screw of the gun body at the first female screw. Then, the fifth female screw of the guide member is screwed into the third male screw of the cover. Then, by operating the lever, gas is ejected from the gas discharge port of the gun body through the gap between the gas nozzle and the liquid nozzle to the outside. The liquid in the tank can be sucked and mixed with the gas from the liquid discharge port of the gun body through the liquid nozzle by the negative pressure generated by the gas ejection. On the other hand, the dispersion nozzle is screwed into the second male screw of the liquid discharge port of the gun body with the fourth female screw, and the cover is screwed into the first male screw of the gun main body with the first female screw. Then, the sixth female screw of the foam discharge member is screwed into the third male screw of the cover. Then, the detergent as a tank liquid is sucked from the liquid discharge port of the gun body through the dispersion nozzle by the negative pressure generated by flowing the gas from the gas discharge port of the gun body to the inside of the cover by operating the lever. After being dispersed, it can be mixed with gas and introduced into the foam release member. And after making a detergent foam with a foam discharge | release member, it can be made to eject in a foaming state from the discharge port of a foam discharge | release member. Therefore, it is possible to easily change the ejection form of the fluid easily by exchanging the parts attached by screwing to the common gun body.

  According to the invention of claim 2, when the fifth male screw of the cylindrical discharge nozzle is screwed into the seventh female screw of the discharge port of the foam discharge member, from the flat opening that becomes wider at the tip of the discharge nozzle, The foamed detergent can be ejected in a flat state.

It is a side view showing a gun body of a fluid ejection gun concerning one embodiment of the present invention. It is a front view showing a gun body of a fluid ejection gun concerning one embodiment of the present invention. It is a sectional side view of the principal part showing the state where a liquid nozzle, a gas nozzle, and a guide member were provided as a fluid ejection gun concerning one embodiment of the present invention. It is a sectional side view of the principal part showing the state where a liquid nozzle, a gas nozzle, and a brush and guide member are provided as a fluid ejection gun according to an embodiment of the present invention. It is a sectional side view of the principal part showing the state where a dispersion nozzle, a foam discharge member, and a discharge nozzle are provided as a fluid ejection gun concerning one embodiment of the present invention. It is a plane sectional view showing two kinds of discharge nozzles of a fluid ejection gun concerning one embodiment of the present invention.

  A fluid ejection gun according to an embodiment of the present invention will be described below with reference to the drawings.

  The fluid ejection gun according to the present embodiment has a gun body 11 shown in FIGS. 1 and 2. As shown in FIG. 1, the gun body 11 includes a grip portion 12 that is gripped by an operator's hand when in use, and a body portion that is inclined from the one end side of the grip portion 12 and extends forward. 13. A male screw (first male screw) 16 is formed on the outer periphery of the tip 15 of the body 13 opposite to the grip 12.

  The gun body 11 is provided with a connection portion 20 connected to, for example, an air compressor 19 as a gas supply source at the end of the grip portion 12 opposite to the body portion 13. Further, as shown in FIG. 2, the gun body 11 is attached to the side portion of the body portion 13 via a connecting pipe 23 and stores a liquid, and is attached to the lower portion of the body portion 13 so as to be bifurcated. And a stand portion 25 that extends. The fluid ejection gun is placed in a standing posture on a work table or the like with three-point support of the stand portion 25 and the connection portion 20.

  A liquid discharge port 27 is provided at the front end portion 15 of the body portion 13 so as to open at the center thereof. As shown in FIG. 1, the liquid discharge port 27 is formed so as to protrude forward from the periphery thereof. The internal flow path 28 shown in FIG. 2 inside the liquid discharge port 27 passes through the body portion 13 and communicates with the tank 22 through the connecting pipe 23, and the liquid supplied from the tank 22 is supplied to the liquid discharge port. Flow up to 27. As shown in FIG. 1, a male screw (second male screw) 29 is formed on the outer periphery of the liquid discharge port 27, and an O-ring 30 is mounted on the outer periphery on the base end side.

  As shown in FIG. 2, a plurality (specifically, four locations) of gas discharge ports 31 are formed at equal intervals in the circumferential direction at the distal end portion 15 of the body portion 13 so as to open around the liquid discharge port 27. Has been. The internal flow paths 32 inside the gas discharge ports 31 communicate with the connection unit 20 after joining, and flow compressed air supplied from the air compressor 19 connected to the connection unit 20 to the gas discharge port 31. At the end of the grip portion 12 opposite to the body portion 13, a flow path adjustment section 35 that has a screw member 34 and adjusts the flow area of the internal flow path 32 according to the screwing position of the screw member 34 is a connection section. 20 side by side.

  As shown in FIG. 1, the gun body 11 has a lever 39 that rotates around a rotation shaft 38 provided at a position rearward of the connecting pipe 23 of the body portion 13. It is arranged in parallel so as to be along the grip portion 12 in front of the grip portion 12, that is, on the male screw 16 side of the grip portion 12. A rod 40 that extends in the direction of the lever 39 and contacts the lever 39 is provided in the grip portion 12 so as to be movable in the extending direction. This rod 40 opens and closes the gas supply switching part 41 built in the grip part 12, and is biased so as to protrude toward the lever 39 by a spring (not shown).

  When the lever 39 is operated so that the lever 39 swings toward the grip part 12 and the rod 40 is pushed into the grip part 12 from the most protruding position, the gas supply switching part 41 moves the internal flow path by moving the rod 40. 32 is opened, and discharge of compressed air from the air compressor 19 from the gas discharge port 31 is allowed. On the other hand, when the gas supply switching unit 41 is released from the swinging operation of the lever 39 toward the grip unit 12 and the rod 40 is positioned at the protruding position by a spring (not shown), the connection unit 20 and the gas discharge port 31 are connected. The internal flow path 32 to be connected is closed, and the discharge of the compressed air from the air compressor 19 from the gas discharge port 31 is regulated. That is, the gas supply switching unit 41 of the gun body 11 switches communication / blocking of the connection unit 20 and the gas discharge port 31 via the internal flow path 32 by operating the lever 39.

  As shown in FIG. 1, a concave portion 44 that is recessed upward is formed in the body portion 13 below the rotation shaft 38, and a needle 45 is disposed in the front-rear direction so as to cross the concave portion 44. A sliding body 46 that slides along the needle 45 is provided outside the needle 45, and the sliding body 46 is engaged with an intermediate position of the lever 39. The needle 45 opens and closes the liquid supply switching unit 48 built in the body unit 13 and is urged so as to be positioned at the front end position by a spring (not shown).

  The liquid supply switching portion 48 is operated so that the lever 39 swings toward the grip portion 12 side, and when the sliding body 46 is pressed and the needle 45 is pulled backward, the internal flow path 28 is opened, and the tank 22 liquids are allowed to be discharged from the liquid discharge port 27. On the other hand, when the operation of swinging the lever 39 toward the grip portion 12 is released and the needle 45 is positioned at the frontmost position of the front end by a spring (not shown), the liquid supply switching portion 48 is connected to the tank 22 and the liquid discharge port 27. , And the discharge of the liquid in the tank 22 from the liquid discharge port 27 is restricted. That is, the liquid supply switching unit 48 of the gun body 11 switches communication / blocking of the tank 22 and the liquid discharge port 27 via the internal flow path 28 by operating the lever 39.

  When the lever 39 is pulled toward the grip portion 12 side, only the rod 40 of the rod 40 and the needle 45 moves at the initial stage when the pulling margin is small. Only the internal flow path 32 is opened by the gas supply switching unit 41 while the path 28 is closed. That is, in this state, the gun body 11 enters a state in which the compressed air from the air compressor 19 is discharged from the gas discharge port 31 while restricting the discharge of the liquid in the tank 22 from the liquid discharge port 27. Further, when the pulling margin of the lever 39 becomes larger than the above, both the rod 40 and the needle 45 move, so that the internal flow path 28 is opened by the liquid supply switching section 48 and the internal flow path is opened by the gas supply switching section 41. 32 will be opened. That is, the gun body 11 is in a state in which the compressed air from the air compressor 19 is discharged from the gas discharge port 31 while the liquid in the tank 22 can be discharged from the liquid discharge port 27.

  As shown in FIG. 1, a restricting portion 53 having a screw member 52 is provided at the rear end portion of the body portion 13. This restricting portion 53 adjusts the retracted end position of the needle 45. When the screw member 52 is loosened and retracted, the needle 45 can be retracted, and when the screw member 52 is tightened and advanced, the needle 45 cannot be retracted. To do. Even if the restricting portion 53 makes the needle 45 not retractable, the rod 40 can be retracted by the lever 39, and the internal flow path 32 can be opened by the gas supply switching portion 41. That is, the restricting unit 53 forcibly closes only the liquid supply switching unit 48, and in this state, only the gas supply switching unit 41 can be opened and closed.

  The tank 22 has a container portion 55 whose one end is closed and the other end is opened, and a detachable lid portion 56 which closes the opening of the container portion 55. The connecting pipe 23 for allowing the liquid to flow out from the tank 22 is connected to an end portion of the container portion 55 opposite to the lid portion 56 which is one end of the tank 22. As shown in FIG. 2, the connecting pipe 23 is configured such that a pipe part 57 fixed to the tank 22 and a pipe part 58 fixed to the body part 13 are connected so as to be relatively rotatable. It is possible to rotate.

  As shown in FIG. 3, the fluid ejection gun according to the present embodiment has a cylindrical cover 71 that is detachably attached to the distal end portion 15 of the gun body 11 having the above-described configuration. The cover 71 includes a ring member 72 and a cylindrical member 73 that is rotatably engaged with one end side in the axial direction of the ring member 72 and extends from the ring member 72 in a tapered shape in the axial direction. Yes. A female thread (first female thread) 74 is formed on the inner peripheral side of the ring member 72 constituting one end of the cover 71. In addition, a female screw (second female screw) 75 is provided on the inner peripheral side and a male screw (third male screw) 76 is provided on the outer peripheral side at the end of the cylindrical member 73 that is the other end of the cover 71 opposite to the ring member 72. Are formed. A stepped portion 77 is formed on the ring member 72 side of the male member 76 of the cylindrical member 73, and an O-ring 78 is attached to the stepped portion 77. Further, an O-ring 79 is attached to the inner peripheral portion of the ring member 72 so as to contact the end portion of the tubular member 73.

  The cover 71 is screwed to the male screw 16 of the distal end portion 15 of the gun main body 11 by a female screw 74 on the inner peripheral side of one end. At this time, the cylindrical member 73 is connected to the distal end portion 15 of the gun main body 11 with O. The ring 79 is clamped. Thereby, the O-ring 79 seals the gap between the gun body 11 and the cover 71 and restricts the relative rotation between the ring member 72 and the cylindrical member 73. The cover 71 covers all the gas discharge ports 31 in a state where the cover 71 is attached to the distal end portion 15 of the gun body 11, and thus allows the gas discharged from all the gas discharge ports 31 to pass inside. .

  The fluid ejection gun according to the present embodiment is detachably attached to the male screw 29 of the liquid discharge port 27 of the gun body 11 described above and is alternatively attached to the liquid nozzle 85 shown in FIG. 3 and the dispersion nozzle shown in FIG. 86.

  The liquid nozzle 85 shown in FIG. 3 has a cylindrical mounting member 90 whose outer shape forms a hexagonal column shape, and a cylindrical tubular reinforcement that is bonded to one side in the axial direction of the inner peripheral surface of the mounting member 90 and extends from the mounting member 90. It has a member 92 and a long cylindrical tubular nozzle body 93 that is bonded to the inside of the reinforcing member 92 and further extends from the reinforcing member 92. A female screw (third female screw) 95 is formed on the inner peripheral surface on the other side in the axial direction of the mounting member 90 which is one end of the liquid nozzle 85. The nozzle main body 93 has a free end at the end opposite to the mounting member 90, and the whole is a tube made of a synthetic resin having flexibility such as nylon, Teflon (registered trademark), polyurethane, and polypropylene. Made of wood.

  The tubular liquid nozzle 85 having such a flexible nozzle main body 93 can be screwed into the male screw 29 of the liquid discharge port 27 of the gun main body 11 with a female screw 95 on the inner peripheral side of one end. When the liquid nozzle 85 is screwed into the liquid discharge port 27, the attachment member 90 sandwiches the O-ring 30 with the distal end portion 15 of the gun body 11. As a result, the O-ring 30 seals the gap between the liquid outlet 27 of the gun body 11 and the liquid nozzle 85. Inside the liquid nozzle 85 is an internal channel 96 that communicates with the internal channel 28 in the gun body 11. Therefore, the liquid in the tank 22 can be supplied to the internal flow path 96 in the liquid nozzle 85 via the internal flow path 28, and the internal flow path 96 is discharged to the outside through the liquid discharged from the liquid discharge port 27. To do. In order to adjust the amount of discharged liquid, a plurality of types of liquid nozzles 85 having different inner diameters of the nozzle main body 93 are prepared, and the liquid nozzle 85 is selectively attached to the liquid discharge port 27 of the gun main body 11 from these.

  The dispersion nozzle 86 shown in FIG. 5 is an integral part, and has a flow passage hole 98 drilled from one end to an intermediate position on the other end side along the axial direction, and a flow passage hole 98 at the bottom position of the flow passage hole 98. And a through hole 99 penetrating in a direction orthogonal to the. Therefore, the other end of the flow path hole 98 opens into the through hole 99. A female thread (fourth female thread) 100 is formed on the inner periphery of the flow path hole 98 that is one end of the dispersion nozzle 86 on the side opposite to the through hole 99. The dispersion nozzle 86 can be screwed into the male screw 29 of the liquid discharge port 27 of the gun body 11 at the female screw 100 on the inner peripheral side of one end. When the dispersion nozzle 86 is screwed into the liquid discharge port 27, the O-ring 30 is sandwiched between the distal end portion 15 of the gun body 11. Thereby, the O-ring 30 seals the gap between the liquid discharge port 27 of the gun body 11 and the dispersion nozzle 86.

  Inside the flow path hole 98 of the dispersion nozzle 86 is an internal flow path 101 that communicates with the internal flow path 28 of the gun body 11. Therefore, the liquid in the tank 22 can be supplied to the internal flow path 101 in the dispersion nozzle 86 via the internal flow path 28. Then, the liquid discharged from the liquid outlet 27 and supplied to the internal flow path 101 of the dispersion nozzle 86 is discharged from the internal flow path 101 into the through hole 99 and collides with the wall surface of the through hole 99 to be dispersed. Thereafter, the gas is ejected into the cover 71 from both sides of the through hole 99.

  As shown in FIG. 3, the fluid ejection gun according to the present embodiment includes a gas nozzle 105 that is detachably attached to the female screw 75 of the cover 71. The gas nozzle 105 includes a cylindrical holding member 106, a cylindrical tubular nozzle body 107 extending from the holding member 106 when the holding member 106 is fitted to one end side, and the nozzle body 107 connected to the holding member 106. A locking ring 108 to be stopped and a plurality of balancers 109 attached to the outer periphery of the nozzle body 107 are provided. One end of the holding member 106 is fitted into the nozzle body 107, and a male screw (fourth male screw) 111 is formed on the outer periphery of the other end. The end of the nozzle body 107 opposite to the holding member 106 is a free end. The entire nozzle body 107 is made of a flexible synthetic resin such as nylon, Teflon (registered trademark), polyurethane, or polypropylene. Made of tube material. The balancer 109 is also made of a synthetic resin tube material.

  The tubular gas nozzle 105 in which the nozzle body 107 has flexibility can be screwed into the female screw 75 of the cover 71 at the male screw 111 on the outer peripheral side of one end. In a state where the liquid nozzle 85 is attached to the liquid discharge port 27 and the cover 71 is attached to the gun body 11, the gas nozzle 105 attached to the cover 71 causes the liquid nozzle 85 to be inserted inside. As a result, the internal flow path 112 between the cover 71 and the liquid nozzle 85 communicates with the internal flow path 113 between the gas nozzle 105 and the liquid nozzle 85. Therefore, the gas nozzle 105 discharges the gas discharged from the gas discharge port 31 through the internal flow path 113 between the gas nozzle and the liquid nozzle 85 to the outside.

  The discharge of the gas generates a negative pressure at the tip of the liquid nozzle 85, and the liquid nozzle 85 sucks the liquid in the tank 22 into the internal flow path 96 due to the negative pressure, and the liquid is discharged from the internal flow path 96. The liquid is mixed with the gas discharged from the internal flow path 113 and ejected. That is, the liquid nozzle 85 and the gas nozzle 105 constitute an injection nozzle 114 that can mix and inject gas-liquid. The cover 71 is also used in a state where the gas nozzle 105 is not attached to the female screw 75 (that is, a state where nothing is attached).

  The fluid ejection gun according to the present embodiment is detachably attached to the male screw 76 of the cover 71 and is alternatively attached to the guide member 115 shown in FIG. 3, the brush / guide member 116 shown in FIG. And a foam releasing member 117.

  A guide member 115 shown in FIG. 3 has a cylindrical shape, and is made of a synthetic resin and includes a cylindrical portion 121 and a conical cylindrical portion 122 extending from one end of the cylindrical portion 121 in a diameter-enlarging shape. A cylindrical body 123 and a conical cylindrical reinforcing body 124 fitted and fixed inside the cylindrical body 123. A female screw (fifth female screw) 125 is formed on the inner peripheral side of the cylindrical portion 121 serving as one end of the guide member 115, and a plurality of through holes 126 are formed on the cylindrical portion 121 side in the conical cylindrical portion 122. ing. The guide member 115 can be screwed onto the male screw 76 of the cover 71 with an internal thread 125 on the inner peripheral side of one end, and while being attached to the cover 71, the guide member 115 mainly turns the injection nozzle 114 at the time of gas discharge and gas-liquid discharge. In the reinforcing body 124, it is guided. When the guide member 115 is attached to the cover 71, the O-ring 78 is sandwiched between the guide member 115 and the cover 71.

  The brush and guide member 116 shown in FIG. 4 has a cylindrical shape, and is made of a synthetic resin including a cylindrical portion 131 and a conical cylindrical portion 132 that extends from one end of the cylindrical portion 131 so as to expand in diameter. And a brush part 135 made up of a plurality of bristle members 134 planted on the opposite side of the cylindrical part 131 of the conical cylindrical part 132. The brush and guide member 116 also has a female screw (fifth female screw) 136 formed on the inner peripheral side of the cylindrical portion 131 serving as one end thereof, and a plurality of through holes 137 are formed in the cylindrical portion 131 in the conical cylindrical portion 132. Formed on the side. The brush and guide member 116 can be screwed onto the male screw 76 of the cover 71 at the internal thread 136 on the inner peripheral side of one end, and in a state where the brush and guide member 116 is attached to the cover 71, the spray nozzle 114 can be swung at the time of fluid discharge. Guide at 132. The brush and guide member 116 is sandwiched between the cover 71 and the O-ring 78 while being attached to the cover 71.

  The foam discharge member 117 shown in FIG. 5 has an attachment port 140 formed on one end side, a discharge port 141 formed on the other end side, and an expansion chamber 142 having a larger flow path area between them. A hollow case 143, a sponge 144 as a foam promoting member disposed in the expansion chamber 142 in the case 143, and a mechanism for forming a gap between the sponge 144 and the discharge port 141 by locking the sponge 144. And a stop member 145. A female screw (sixth female screw) 146 is formed on the inner peripheral side of the attachment port 140, and a female screw (seventh female screw) 147 is formed on the inner peripheral side of the discharge port 141. The foam discharge member 117 can be screwed into the male screw 76 of the cover 71 with a female screw 146 formed on the inner peripheral side of the attachment port 140 serving as one end of the foam discharge member 117, and is attached to the cover 71 from the liquid discharge port 27. The detergent as a liquid discharged through the dispersion nozzle 86 is foamed and discharged to the outside from the discharge port 141. The foam release member 117 is sandwiched between the O-ring 78 and the cover 71 while being attached to the cover 71. The O-ring 78 seals the gap between the cover 71 and the foam release member 117.

  The fluid ejection gun according to the present embodiment is detachably attached to the female screw 147 of the discharge port 141 of the foam discharge member 117 and is alternatively attached to both of the discharge nozzle 151 and the discharge nozzle 152 shown in FIG. And have. The discharge nozzle 151 is formed with a flat opening 153 that is wider at the one end side at the one end side, and a male screw (fifth male screw) 154 is formed at the outer peripheral side at the other end. The discharge nozzle 152 is formed with a flat opening 155 that is wider toward the tip at one end side, and a male screw (fifth male screw) 156 is formed at the outer peripheral side of the other end. The flat opening 153 of the discharge nozzle 151 has a wider opening end than the flat opening 155 of the discharge nozzle 152.

  As shown in FIG. 5, the discharge nozzle 151 can be screwed into the female screw 147 of the foam discharge member 117 at the male screw 154, and the foamed detergent is flattened from the flat opening 153 while being attached to the foam discharge member 117. Release in widened state. The discharge nozzle 152 can also be screwed into the female screw 147 of the foam discharge member 117 at the male screw 156, and discharges the foamed detergent from the flat opening 155 in a flat widened state while being attached to the foam discharge member 117.

Each usage pattern of the fluid ejection gun having the above configuration will be described.
For example, as shown in FIG. 3, an O-ring 30 is attached to the liquid discharge port 27 of the gun body 11, and a liquid screw 85 is attached to the liquid discharge port 27 by screwing a female screw 95 with its male screw 29. Further, the gas nozzle 105 is attached to the cover 71 by screwing the male screw 111 into the female screw 75. Then, an O-ring 79 is attached to the cover 71, and the gun body 11 is formed by screwing the cover 71 into the male screw 16 while inserting the liquid nozzle 85 inside the cover 71 and the gas nozzle 105. It attaches to the front-end | tip part 15. Then, the O-ring 78 is attached to the cover 71, and the guide member 115 is attached to the cover 71 by screwing the male screw 76 with the female screw 125.

  In this state, liquid such as water or detergent is injected into the tank 22, the connecting portion 20 is connected to the air compressor 19, and the air compressor 19 is driven. Then, the lever 39 is pulled toward the grip portion 12 side. At this time, if the lever 39 is pulled lightly, the lever 39 retracts only the rod 40, whereby the gas supply switching unit 41 is opened and the air compressor 19 and the gas discharge port 31 are brought into communication with each other. Air is ejected from the gas outlet 31 to the outside through the internal flow path 112 between the cover 71 and the liquid nozzle 85 and the internal flow path 113 between the gas nozzle 105 and the liquid nozzle 85.

  At this time, the gas nozzle 105 is formed of a flexible synthetic resin material together with the liquid nozzle 85, and the distal end portion is a free end. This swirling motion is restricted to a certain radial range by a guide member 115 provided radially outward of the gas nozzle 105, and the injection nozzle 114 comprising the liquid nozzle 85 and the gas nozzle 105 A regular swivel motion is performed along the inner surface of 115. In addition, the spray nozzle 114 is stabilized in the turning motion by the balancer 109 attached around the gas nozzle 105. As a result, only compressed air is ejected from the tip of the reciprocating spray nozzle 114 into a conical cylinder shape whose diameter is expanded while revolving the ejection position. Thereby, compressed air can be sprayed on the ejection target to perform dust removal, droplet removal, drying, and the like.

  Further, when the lever 39 is further pulled than the above, the lever 39 moves the needle 45 backward through the sliding body 46, whereby the liquid supply switching unit 48 is opened, and the tank 22, the liquid discharge port 27, Is in a communication state. Then, since compressed air is ejected from the internal flow path 113 between the gas nozzle 105 and the liquid nozzle 85 to cover the opening of the liquid nozzle 85, the vicinity of the opening of the liquid nozzle 85 is negative. With this negative pressure, the liquid nozzle 85 sucks the liquid in the tank 22 through the internal flow path 28 into the internal flow path 96 and discharges the liquid from the internal flow path 96 to the outside. Will be mixed with the compressed air from

  Also at this time, the injection nozzle 114 composed of the gas nozzle 105 and the liquid nozzle 85 performs a regular turning motion along the guide member 115 provided radially outward of the gas nozzle 105, A mixed fluid of compressed air and liquid becomes a mist state from the tip of the jet nozzle 114 that makes a swivel motion, and is ejected into a conical cylinder that expands in diameter while swirling the jet position. Thereby, the mixed fluid of compressed air and a liquid can be sprayed on the ejection target. At this time, the operator rotates the tank 22 so that the tank 22 is always located above the connecting pipe 23 in the vertical direction, so that the liquid in the tank 22 flows toward the liquid discharge port 27 even by gravity. Thus, the liquid nozzle 85 is efficiently discharged from the tip.

  In the above, when the brush and guide member 116 is attached as shown in FIG. 4 instead of the guide member 115, the lever 39 is pulled in the same manner as described above, and the air compressor 19 and the gas discharge port 31 are operated by the gas supply switching unit 41. And the tank 22 and the liquid discharge port 27 are in communication with each other in the liquid supply switching unit 48, the gas-liquid is mixed while the spray nozzle 114 is swung by the guide of the cylindrical body 133 of the brush and guide member 116. And will erupt. When the spray nozzle 114 turns, the brush part 135 is positioned in front of the jet direction of the gas and liquid of the spray nozzle 114. As a result, the mixed fluid of compressed air and liquid partially blows the brush part 135 radially outward. And the displacement position is continuously moved in the circumferential direction. In this state, when the brush part 135 is applied to the object to be cleaned, the brush part 135 automatically rubs the object to be cleaned while jetting a fluid mixture of compressed air and liquid toward the object to be cleaned. Work becomes easy.

  Further, for example, as shown in FIG. 5, an O-ring 30 is attached to the liquid discharge port 27 of the gun body 11, and a dispersion nozzle 86 is attached to the liquid discharge port 27 by screwing a female screw 100 to the male screw 29. In addition, the O-ring 79 is attached to the cover 71 without attaching anything to the female screw 75, and the cover 71 is screwed into the male screw 16 while the cover 71 is inserted inside, while the dispersion nozzle 86 is inserted inside. Attached to the tip 15 of the gun body 11. Then, an O-ring 78 is attached to the cover 71, and the foam release member 117 is attached to the cover 71 by screwing the male screw 76 with the female screw 146.

  In this state, a liquid made of a detergent is poured into the tank 22, the connecting portion 20 is connected to the air compressor 19, and the air compressor 19 is driven. Then, when the lever 39 is pulled in the same manner as described above, the gas supply switching unit 41 makes the air compressor 19 and the gas discharge port 31 communicate with each other, and the liquid supply switching unit 48 makes the tank 22 and the liquid discharge port 27 communicate with each other. Compressed air from the air compressor 19 is introduced into the foam discharge member 117 from the gas discharge port 31 through a gap between the cover 71 and the dispersion nozzle 86. At this time, since the compressed air flows so as to cover the openings at both ends of the through holes 99 of the dispersion nozzle 86, the vicinity of the openings at both ends of the through holes 99 of the dispersion nozzle 86 has a negative pressure. The dispersion nozzle 86 sucks the liquid through the internal flow path 28, collides with the through hole 99 from the flow path hole 98, disperses the liquid from the through hole 99, and discharges it. Then, the dispersed liquid is mixed with compressed air and introduced into the foam discharge member 117. Then, the mixed fluid of compressed air and liquid is foamed in a fine mousse shape by the rapid expansion of the flow path area by the expansion chamber 142 and the passage of the sponge 144, and is discharged from the discharge port 141 into a rod shape.

  In the above, if necessary, if the discharge nozzle 151 is attached by screwing the male screw 154 to the female screw 147 of the discharge port 141 to the foam discharge member 117, the foam shape to be discharged becomes a flat shape that becomes wider toward the end. Can be fan-shaped. Alternatively, if the discharge nozzle 152 is attached by screwing the male screw 156 to the female screw 147 of the discharge port 141 to the foam discharge member 117, the shape of the bubble to be discharged is narrower than when the discharge nozzle 151 is used. It can be made into a flat fan shape.

  According to the fluid ejection gun of the present embodiment described above, a flexible tube that allows liquid discharged from the liquid discharge port 27 to pass through the male screw 29 formed on the outer periphery of the liquid discharge port 27 of the gun body 11. Since the liquid nozzle 85 has a structure that can be screwed with the internal thread 95 on the inner peripheral side, the liquid nozzle 85 can be easily detached from the gun body 11 by releasing this screwing. Accordingly, when the liquid nozzle 85 is clogged, the liquid nozzle 85 can be replaced with a clogged liquid nozzle 85 or removed and cleaned, so that maintenance is facilitated.

  In addition, the liquid nozzle 85 is screwed to the male screw 29 of the liquid discharge port 27 of the gun body 11 with the female screw 95, and the gas nozzle 105 is screwed to the female screw 75 of the cover 71 with the male screw 111. The cover 71 is screwed onto the male screw 16 of the gun body 11 with the female screw 74 while the liquid nozzle 85 is inserted inside. Then, the female screw 136 of the guide member 115 is screwed into the male screw 76 of the cover 71. Then, by operating the lever 39, the gas nozzle 105 and the liquid nozzle 85 are respectively ejected from the gas discharge port 31 of the gun body 11 through the gap between the gas nozzle 105 and the liquid nozzle 85 to the outside. The liquid in the tank 22 is sucked from the liquid discharge port 27 of the gun body 11 through the liquid nozzle 85 and mixed with the gas by the negative pressure generated by the gas jetting while being swung along the outer guide member 115 due to the flexibility of the gas. Can be ejected. On the other hand, the dispersion nozzle 86 is screwed to the male screw 29 of the liquid discharge port 27 of the gun main body 11 with the female screw 100, and the cover 71 is screwed to the male screw 16 of the gun main body 11 with the female screw 74. Then, the female screw 146 of the foam discharge member 117 is screwed into the male screw 76 of the cover 71. Then, when the lever 39 is operated, the tank is discharged from the liquid discharge port 27 of the gun body 11 through the dispersion nozzle 86 by a negative pressure generated by flowing gas from the gas discharge port 31 of the gun body 11 to the inside of the cover 71. The liquid detergent 22 is sucked and collided with the wall surface of the through hole 99 of the dispersion nozzle 86, and then mixed with gas and introduced into the foam discharge member 117. Then, after the detergent is foamed by the foam releasing member 117, the detergent can be ejected from the outlet 141 of the foam releasing member 117 in a foamed state. Therefore, it is possible to easily change the ejection form of the fluid easily by exchanging parts attached by screwing to the common gun body 11.

  Further, when the male screw 154 of the cylindrical discharge nozzle 151 or the male screw 156 of the discharge nozzle 152 is screwed into the female screw 147 of the discharge port 141 of the foam discharge member 117, a flat opening that becomes wider at the tips of the discharge nozzles 151 and 152. From the parts 153 and 155, the foamed detergent can be ejected in a flat state.

  In addition, when using the injection nozzle 114 for a fluid ejection gun, as a liquid stored in the tank 22, various coating agents, such as water, a detergent, a disinfectant, a disinfectant, a fungicide, a photocatalyst, and a deodorant, for example A degreasing agent, an antistatic agent, or the like can be used.

11 Gun body 12 Grip part 15 Tip part 16 Male screw (first male screw)
19 Air compressor (gas supply source)
20 Connecting portion 22 Tank 27 Liquid outlet 29 Male screw (second male screw)
31 Gas exhaust port 39 Lever 41 Gas supply switching part 48 Liquid supply switching part 71 Cover 74 Female thread (first female thread)
75 female thread (second female thread)
76 male screw (third male screw)
85 Liquid nozzle 86 Dispersion nozzle 95 Female thread (3rd female thread)
100 female thread (4th female thread)
105 Gas nozzle 111 Male screw (4th male screw)
115 Guide Member 116 Brush and Guide Member 117 Foam Release Member 125,136 Female Screw (Fifth Female Screw)
141 Release port 146 Female thread (6th female thread)
147 female screw (7th female screw)
151,152 Discharge nozzle 153,155 Flat opening 154,156 Male screw (fifth male screw)

Claims (2)

A grip part;
A first male screw formed on the outer periphery of the tip portion opposite to the grip portion;
A lever arranged side by side on the first male screw side of the grip portion;
A tank for storing liquid;
A connection connected to a gas source;
A liquid discharge port that communicates with the tank and opens at the center of the tip and has a second male screw formed on the outer periphery;
A gas discharge port communicating with the connection portion and opening around the liquid discharge port of the tip portion;
By operating the lever, a gas supply switching unit that switches communication / blocking between the connection unit and the gas discharge port;
A gun body having a liquid supply switching unit that switches communication / blocking between the tank and the liquid discharge port by operating the lever;
The first female screw on the inner peripheral side of one end is screwed into the first male screw and allows the gas discharged from the gas discharge port to pass therethrough. A cylindrical cover, and
A flexible tubular liquid nozzle that allows liquid discharged from the liquid discharge port to pass through the second male screw can be screwed into a third female screw on the inner peripheral side of the second male screw, and is discharged from the liquid discharge port. A dispersion nozzle that disperses the liquid to be threaded can be screwed into the fourth female screw on the inner circumferential side at one end;
The second female screw of the cover has a flexible tubular gas nozzle that allows the gas discharged from the gas discharge port to pass between the liquid nozzle and the liquid nozzle. It can be screwed on the 4th male screw,
A cylindrical guide member that guides the turning of the gas nozzle at the time of gas discharge can be screwed onto the third male screw of the cover at the fifth female screw on the inner peripheral side and discharged from the liquid discharge port. A fluid ejection gun, wherein a foam releasing member that foams a detergent as a liquid dispersed by the dispersion nozzle and discharges it from a discharge port can be screwed into a sixth female screw on the inner peripheral side.   A seventh female screw is formed at the discharge port of the foam discharge member, and a cylindrical discharge nozzle having a flat opening that is wider toward one end is formed on the seventh female screw. The fluid ejection gun according to claim 1, wherein the fluid ejection gun can be screwed into a fifth male screw on the side.

Images