JP6660811B2 - Trigger type liquid ejector - Google Patents

Description

  The present invention relates to a trigger type liquid ejector.

BACKGROUND ART Conventionally, a trigger type liquid ejector as disclosed in Patent Document 1 below has been known. This trigger-type liquid ejector is a nozzle provided with an ejector body mounted on a container body containing a liquid, and an ejection hole disposed on the front side of the ejector body and ejecting the liquid forward. And a unit. The ejector body extends vertically, and has a vertical supply cylinder for sucking up liquid in the container, and an injection extending from the vertical supply cylinder toward the front and communicating with the inside of the vertical supply cylinder. A cylindrical portion. The ejector body further includes a trigger mechanism. The trigger mechanism has a trigger portion movably arranged rearward in a forward biased state. The trigger mechanism causes the liquid to be introduced from the inside of the vertical supply cylinder into the injection cylinder by being moved rearward of the trigger, and to be ejected from the inside of the injection cylinder toward the ejection hole side.
Furthermore, in this trigger type liquid ejector, a pressure accumulating valve that opens and closes an ejection hole is provided in the nozzle portion. When the pressure in the pressure accumulating chamber becomes equal to or higher than a predetermined pressure, the pressure accumulating valve opens the ejection hole and ejects the content from the ejection hole.

JP 2011-177630 A

In the configuration described in Patent Literature 1, since the pressure accumulating valve is provided in the nozzle, the structure of the nozzle is complicated and large.
In addition, since the pressure accumulating chamber communicates with the inside of the injection cylinder having a relatively large internal volume, the number of times of operation of the trigger portion (hereinafter, referred to as priming frequency) necessary to increase the pressure in the pressure accumulating chamber to open the ejection hole is reduced. There was a problem that it was difficult to reduce.

  The present invention has been made in view of such circumstances, and it is an object of the present invention to provide a trigger-type liquid ejector capable of easily reducing the number of times of priming while reducing the size of the nozzle portion and simplifying the structure. I do.

  In order to solve the above-mentioned problem, a trigger type liquid ejector of the present invention is provided on an ejector main body mounted on a container body containing a liquid, and is disposed on a front side of the ejector main body to eject the liquid. A nozzle portion having an ejection hole formed therein, wherein the ejector main body extends in a vertical direction, and a vertical supply cylinder portion that sucks up liquid in the container body, and extends forward from the vertical supply cylinder portion. An injection cylinder portion that is extended and has an inner side communicating with the inside of the vertical supply cylinder portion, and a trigger portion that is disposed movably rearward in a forward biased state in front of the vertical supply cylinder portion, A trigger mechanism for causing the liquid to be introduced from inside the vertical supply cylinder into the injection cylinder by backward movement of the trigger, and to be ejected from the front end opening of the injection cylinder toward the ejection hole side. Liquid ejector, wherein in the injection cylinder portion Movably disposed rearwardly forward forcing state, the accumulator valve for closing open freely to the front end opening of the injection tube portion is characterized in that it is arranged.

Since the trigger-type liquid ejector of the present invention is an accumulator-type trigger-type liquid ejector provided with an accumulator valve, it stabilizes the pressure of the liquid when it is ejected from the ejection hole through the inside of the injection cylinder, and stores the liquid. It can be ejected in an expected manner. Furthermore, since the pressure accumulator valve is disposed in the injection cylinder, the structure of the nozzle is simplified and the bulk of the nozzle in the front-rear direction and the vertical direction is reduced, for example, as compared with the case where the pressure accumulator is disposed in the nozzle. It can be easily suppressed.
Further, since the pressure accumulating valve is provided in the injection cylinder, the internal volume of the injection cylinder can be reduced without increasing the number of parts. Accordingly, when the trigger section is operated, the pressure in the injection cylinder section is quickly increased, and it is easy to reduce the number of times of priming. Further, since the internal volume of the injection cylinder portion is reduced, air is less likely to remain in the injection cylinder portion, and it is possible to suppress variations in the ejection amount caused by the remaining air and dripping from the ejection holes. .

  Here, the pressure accumulator valve may be provided over the entire length in the front-rear direction in the injection cylinder portion.

  In this case, since the pressure accumulating valve is disposed over the entire length in the front-rear direction in the injection cylinder, the internal volume of the injection cylinder is further reduced, thereby reducing the number of times of priming and suppressing the air remaining in the injection cylinder. Success can be achieved more reliably.

  Further, a rear part of the pressure accumulation valve and an upper end opening of the vertical supply cylinder part may be opposed to each other in a vertical direction.

  In this case, since the rear part of the pressure accumulation valve and the upper end opening of the vertical supply cylinder part are vertically opposed to each other, the liquid passing through the vertical supply cylinder part is immediately brought into contact with the pressure accumulation valve, and the liquid acting on the pressure accumulation valve is The pressure can be raised quickly.

  According to the present invention, it is possible to provide a trigger type liquid ejector capable of easily reducing the number of times of priming while reducing the size of the nozzle portion and simplifying the structure.

It is a longitudinal section of a trigger type liquid ejector concerning this embodiment.

Hereinafter, a first embodiment of a trigger type liquid ejector according to the present invention will be described with reference to FIG.
As shown in FIG. 1, a trigger type liquid ejector 1 of the present embodiment is mounted on a container A containing a liquid and has an ejector main body 2 having a vertical supply cylinder portion 10 for sucking up liquid, and an ejection hole 4. And a nozzle portion 3 mounted on the ejector main body 2.
Each component of the trigger type liquid ejector 1 is formed by injection molding using a synthetic resin unless otherwise specified.

  Here, in this embodiment, the central axis of the vertical supply cylinder 10 is defined as an axis O1, and a direction along this axis O1 is referred to as an up-down direction. Called the upper side. In addition, one direction orthogonal to the axis O1 is referred to as a front-rear direction, and a direction orthogonal to both the up-down direction and the front-rear direction is referred to as a left-right direction.

The ejector main body 2 includes the vertical supply cylinder 10 extending in the vertical direction, and an injection cylinder extending from the vertical supply cylinder 10 in the front-rear direction and having an inner side communicating with the inside of the vertical supply cylinder 10. 11, and is formed in an L-shape when viewed from the side when viewed from the left and right directions.
In the front-rear direction, the direction in which the injection cylinder 11 extends from the vertical supply cylinder 10 is referred to as front or front, and the opposite direction is referred to as rear or rear.

(Vertical supply cylinder)
The vertical supply cylinder 10 includes an outer cylinder 12 and an inner cylinder 13 fitted into the outer cylinder 12.
The outer cylinder 12 is disposed above the large-diameter portion 12a, the large-diameter portion 12a, and has a small-diameter portion 12b smaller in diameter than the large-diameter portion 12a, and is disposed above the small-diameter portion 12b. A connecting tube portion 12f having a diameter smaller than that of the connecting tube portion 12b, an annular connecting portion 12c connecting the upper end portion of the large-diameter portion 12a and the lower end portion of the small-diameter portion 12b, and an upper end portion of the small-diameter portion 12b and a lower end of the connecting tube portion 12f. And a top wall portion 12d that connects the two. The central axis of the connection cylinder 12f is eccentric to the front with respect to the axis O1. The top wall 12d covers an upper part of a suction valve 36 described later. The lower end of the small diameter portion 12b protrudes below the annular connecting portion 12c.

  The inner cylinder 13 includes a large-diameter portion 13a on which the large-diameter portion 12a of the outer cylinder 12 is fitted, a small-diameter portion 13b disposed above the large-diameter portion 13a, and having a smaller diameter than the large-diameter portion 13a. It has a flange portion 13c connecting the upper end portion of the diameter portion 13a and the lower end portion of the small diameter portion 13b, and is formed in a two-stage cylindrical shape whose diameter is reduced upward from below. At the upper end of the small diameter portion 13b, a reduced diameter portion 13g having a smaller outer diameter than the small diameter portion 13b is formed. A cutout portion 13f is formed in a front portion of the upper end opening edge 13e of the reduced diameter portion 13g. The cutout portion 13f is formed in a portion of the upper end opening edge 13e of the reduced diameter portion 13g that vertically opposes the space in the connection tube portion 12f of the outer tube 12.

An upper portion of a pipe 15 which is disposed in the container A and has a lower end opening at the bottom (not shown) of the container A is fitted into the small diameter portion 13b of the inner cylinder 13. The flange portion 13c of the inner cylinder 13 is located below the annular connection portion 12c of the outer cylinder 12, with a gap S1 secured between the flange portion 13c and the annular connection portion 12c of the outer cylinder 12. In the large-diameter portion 13a of the inner cylinder 13, a portion protruding downward from the large-diameter portion 12a of the outer cylinder 12 is formed with an annular flange portion 13d that protrudes outward in the radial direction. The flange 13d is provided in the upper end of the mounting cap 14 mounted (for example, screwed) on the mouth A1 of the container A, and locks the upper end of the mounting cap 14 rotatably around its axis. The flange 13d is vertically sandwiched between the mounting cap 14 and the upper edge of the opening A1 of the container A.
Note that the axis O1 of the vertical supply cylinder portion 10 composed of the outer cylinder 12 and the inner cylinder 13 is eccentric to the rear with respect to the container axis of the container A.

(Injection cylinder)
The injection cylinder portion 11 has a front wall and is formed in a tubular shape with a rear end opened. The front wall of the injection cylinder portion 11 has a communication hole 11c penetrating the front wall in the front-rear direction. Have been. Behind the injection cylinder 11, a rear cylinder 11b disposed coaxially with the center axis O2 of the injection cylinder 11 is formed integrally with the injection cylinder 11. The rear cylindrical portion 11b has a front wall and is formed in a cylindrical shape with a rear end opened. The inner and outer diameters of the rear cylinder portion 11b are larger than the inner and outer diameters of the injection cylinder portion 11. A portion of the front wall of the rear cylinder portion 11b below the central axis of the rear cylinder portion 11b is integrated with a rear portion of the connection cylinder portion 12f of the outer cylinder 12. The inside of the injection cylinder 11 communicates with the inside of the vertical supply cylinder 10 through the inside of the connection cylinder 12 f and the reduced diameter portion 13 g of the inner cylinder 13.
A closing lid 99 for closing the rear end opening of the rear cylinder portion 11b is provided on the rear cylinder portion 11b. The closing lid 99 is fitted in the rear cylindrical portion 11b, and has a rear end closed, and has a cylindrical lid main body 99a that opens forward, and is disposed coaxially with the central axis O2. A cylindrical guide projection 99b protruding forward from the rear wall, and an upper end portion of the rear wall of the lid main body 99a, which extends forward and is locked to the front wall of the rear cylindrical portion 11b. And a portion 99c. The rear end of the compression spring 98 extending in the front-rear direction is fitted to the guide projection 99b.

(Accumulator)
A pressure accumulating valve 90 is provided in the injection cylinder portion 11 and extends over the entire length in the front-rear direction. The pressure accumulating valve 90 is disposed so as to be movable rearward in a forward biased state, and closes a front opening (hereinafter, referred to as a front end opening 11a) of the communication hole 11c of the injection cylinder portion 11 so as to be openable. The accumulator valve 90 includes a cylindrical valve body 91 extending in the front-rear direction, a guide cylinder 92 extending rearward from the rear end of the valve body 91, and an injection cylinder 11 extending from the rear edge of the guide cylinder 92. And a sliding portion 94 protruding forward from the front surface of the flange portion 93. A curved surface portion 91a protruding forward is formed at the front end of the valve body 91. The valve body 91, the guide cylinder 92, the flange 93, the sliding part 94, and the curved surface 91a are arranged coaxially with the central axis O2 of the injection cylinder 11. The rear end of the valve body 91 (rear part of the pressure accumulator valve 90) vertically opposes the upper end opening of the connecting tube part 12f of the outer tube 12 (the upper end opening of the vertical supply tube part 10). The front end of the curved surface portion 91a enters the communication hole 11c of the injection cylinder portion 11 from behind. The front end of the curved surface portion 91a is located inside the communication hole 11c.

  The outer diameter of the valve body 91 is smaller than the inner diameter of the injection cylinder 11. Thus, a gap S4 extending in the front-rear direction is formed between the outer peripheral surface of the valve body 91 and the inner peripheral surface of the injection cylinder 11. Since the diameter of the valve body 91 gradually decreases toward the front, the flow path cross-sectional area of the gap S4 gradually increases toward the front. The sliding portion 94 gradually extends outward in the radial direction of the injection cylinder portion 11 as it goes forward. The sliding portion 94 is formed so as to be elastically deformable, and the front end of the sliding portion 94 is in contact with the inner peripheral surface of the rear tubular portion 11b by its restoring force. When the accumulator valve 90 moves in the front-rear direction, the front end of the sliding portion 94 slides on the inner peripheral surface of the rear tubular portion 11b.

The rear part of the guide cylinder 92, the flange part 93, and the sliding part 94 are disposed in the rear cylinder part 11b of the injection cylinder part 11. A space surrounded by the guide cylinder 92, the flange portion 93, the sliding portion 94, and the rear cylinder portion 11b (hereinafter, referred to as a pressure accumulation chamber S5) communicates with the gap S4. At the center in the front-rear direction of the outer peripheral surface of the guide cylinder 92, a protruding portion is formed that protrudes outward in the radial direction of the guide cylinder 92. By contacting the rear end portion, rattling of the pressure accumulating valve 90 with respect to the injection cylinder 11 is reduced.
The front end of the compression spring 98 is fitted in the guide cylinder 92. The compression spring 98 is compressed between the closing lid 99 and the pressure accumulation valve 90 in the front-rear direction. The restoring force of the compression spring 98 acts as a forward biasing force of the pressure accumulating valve 90. Due to this forward urging force, the curved surface portion 91a of the pressure accumulating valve 90 is pressed against the rear end opening of the communication hole 11c of the injection cylinder 11, and the communication hole 11c is closed. A backward force acts on the accumulator valve 90 due to the pressure of the liquid in the gap S4 and the accumulator S5. When the rearward force due to the hydraulic pressure exceeds the forward urging force by the compression spring 98, the pressure accumulating valve 90 is displaced rearward, and the closed of the communication hole 11c by the curved surface portion 91a is released.

A portion of the inner peripheral surface of the inner cylinder 13 located above the upper end of the pipe 15 is formed with an annular tapered cylindrical portion 35 protruding inward.
The diameter of the tapered tube portion 35 gradually decreases as it goes downward. Inside the tapered tube portion 35, a spherical suction valve 36 that is separably seated on the inner peripheral surface of the tapered tube portion 35 is provided. The suction valve 36 communicates and shuts off a space located above the tapered tube portion 35 and a space located below the tapered tube portion 35 in the inner tube 13.

As shown in FIG. 1, a cylinder tube portion 40 protruding forward is formed integrally with the outer tube 12 in a portion located below the injection tube portion 11.
The cylinder portion 40 is opened forward and partially formed integrally with the annular connecting portion 12c of the outer tube 12.

(Trigger mechanism)
The ejector main body 2 extends downward from the injection cylinder portion 11, and is provided with a trigger portion 51 which is arranged to be swingable rearward in a forward biased state, and in the front-rear direction in conjunction with the swing of the trigger portion 51. A piston 52 that moves, a cylinder 53 whose inside is pressurized and depressurized with the movement of the piston 52, an elastic plate portion 54 that urges the trigger portion 51 forward, a vertical supply cylinder portion 10, and an injection cylinder portion 11. A cover body 55 that covers the whole at least from above and from the left and right.

  The above-described suction valve 36, trigger portion 51, piston 52, cylinder 53, and elastic plate portion 54 cause the liquid in the container A to flow from the vertical supply cylinder portion 10 into the injection cylinder portion by swinging the trigger portion 51 backward. The trigger mechanism 50 is configured to be introduced into the inside 11 and to be ejected from the inside of the injection cylinder 11 to the ejection hole 4 side.

  The cylinder 53 projects forward from the vertical supply cylinder 10 and communicates with the inside of the vertical supply cylinder 10 through a through hole 66 described later. The cylinder 53 includes an outer cylinder portion 60 that opens forward, a rear wall portion 61 that closes a rear opening of the outer cylinder portion 60, and a front end that projects forward from a central portion of the rear wall portion 61. The piston guide 62 is closed.

  The inside of the piston guide 62 is opened rearward, and a fitting tube portion 41 projecting forward from a rear wall (small diameter portion 12b of the outer tube 12) of the cylinder tube portion 40 is provided in the opening. Mated. The front end wall of the piston guide 62 is provided with a guide hole 62a penetrating the front end wall. An annular concave portion 62b is formed at the rear end of the outer peripheral surface of the piston guide 62.

  The outer cylinder 60 is fitted inside the cylinder cylinder 40. The inner peripheral surface of the cylinder tube portion 40 and the outer peripheral surface of the outer tube portion 60 are in close contact at both ends in the front-rear direction. On the other hand, between the inner peripheral surface of the cylinder tube portion 40 and the outer peripheral surface of the outer cylinder portion 60, an annular gap S2 is secured at an intermediate portion located between both ends in the front-rear direction. .

  A first ventilation hole 63 that connects the inside of the outer cylinder 60 and the gap S2 is formed in the outer cylinder 60. A second passage for communicating the gap S2 with the annular connecting portion 12c of the outer cylinder 12 and a gap S1 defined between the annular connecting portion 12c of the outer cylinder 12 and the flange portion 13c of the inner cylinder 13. Pores 64 are formed. Further, a third ventilation hole 65 is formed in the flange portion 13c of the inner cylinder 13 to allow the gap S1 to communicate with the large-diameter portion 13a of the inner cylinder 13 and the inside of the mounting cap 14.

  A through hole 66 is formed in the rear wall portion 61 of the cylinder 53 at a position above the piston guide 62 so as to penetrate in the front-rear direction. In the illustrated example, a projecting cylinder 67 projecting rearward is formed on the peripheral edge of the opening of the through hole 66 in the rear wall 61, and the projecting cylinder 67 is attached to the small-diameter portion 12 b of the outer cylinder 12. Are fitted in the through holes formed in the holes. A gap S3 is formed between the rear end of the protruding tube 67 and the outer peripheral surface of the reduced diameter portion 13g of the inner tube 13. The through hole 66 communicates with the gap S4 in the injection cylinder 11 through the gap S3 and the connection cylinder 12f. The suction valve 36 switches the communication between the inside of the container A and the inside of the cylinder 53 and the cutoff thereof.

The piston 52 is slidably fitted in the cylinder 53 back and forth, and moves rearward with the rearward movement of the trigger portion 51 to supply the liquid in the cylinder 53 to the gap S3 and the connection tube portion 12f. I do. The piston 52 includes a columnar connecting portion 70 connected to the trigger portion 51, and a piston cylinder 71 located rearward of the connecting portion 70 and having a larger diameter than the connecting portion 70. It is formed in a tubular shape that is open to the outside.
Note that the cylinder 53 and the piston 52 are disposed on a common axis (not shown) extending in the front-rear direction.

  The piston cylinder 71 is opened rearward and has a piston body 72 into which the piston guide 62 is inserted. The piston cylinder 71 projects radially outward from the rear end of the piston body 72 and A sliding cylindrical portion 73 that comes into close sliding contact with the inner peripheral surface of the portion 60.

  The piston main body 72 is closely fitted to the piston guide 62. In the illustrated example, the rear end of the piston main body 72 is slidably fitted to the piston guide 62 in the front-rear direction. Thus, the liquid flowing in the vertical supply cylinder 10 is introduced into the storage chamber 53a located behind the sliding cylinder 73 in the cylinder 53.

By the way, when the trigger part 51 is operated first, it is necessary to discharge the air in the storage chamber 53a. However, when the pressure accumulation valve 90 is retracted to discharge the air from the front end opening 11a of the injection cylinder part 11, When the pressure of the rearward air acting on the pressure accumulating valve 90 falls below the forward biasing force of the compression spring 98, the front end opening 11a is closed and the discharge of the air is stopped, so that air is stored in the storage chamber 53a. Easy to survive. Therefore, in the present embodiment, the inside of the storage chamber 53a and the inside of the container body A are communicated as described below, and the air remaining in the storage chamber 53a can be discharged into the container body A.
In a state where the trigger portion 51 is located at the rearmost swinging position and the piston 52 is moved to the rearward movement position, the rear end of the piston main body 72 is located at a position equivalent to the recess 62b of the piston guide 62 in the front-rear direction. To position. At this time, the inside of the storage chamber 53a and the inside of the piston main body 72 communicate with each other through the space between the inner peripheral surface of the piston 52 and the concave portion 62b. The inside of the piston main body 72 communicates with the inside of the fitting cylinder 41 through the inside of the guide hole 62 a and the inside of the piston guide 62. The inside of the fitting tube portion 41 communicates with the inside of the container body A through a recovery passage 41 a provided in the ejector main body 2. The recovery passage 41a is provided in the vertical supply cylinder 10. The recovery passage 41 a is provided between the inner peripheral surface of the small diameter portion 12 b of the outer cylinder 12 and the outer peripheral surface of the small diameter portion 13 b of the inner cylinder 13. The recovery passage 41a communicates with the inside of the container body A through the third ventilation hole 65 and the large diameter portion 13a of the inner cylinder 13. Thereby, the inside of the storage chamber 53a passes between the inner peripheral surface of the piston 52 and the concave portion 62b, the inside of the piston main body 72, the guide hole 62a, the inside of the piston guide 62, the inside of the fitting cylinder 41, and the collection passage 41a. Communicate inside A. As described above, when the trigger section 51 is operated first, the air in the storage chamber 53a can be efficiently discharged into the container A.
If the storage chamber 53a is full of contents, a residual pressure is generated in the storage chamber 53a when the trigger portion 51 is swung to the rearmost swing position, and the residual pressure causes ejection. A “drip” in which the contents are unexpectedly discharged from the holes 4 may occur. According to the present embodiment, even if a residual pressure is generated in the storage chamber 53a, the residual pressure is generated between the inner peripheral surface of the piston 52 and the recess 62b, in the piston main body 72, in the guide hole 62a, and in the piston guide 62. Since the liquid can be collected into the container body A through the fitting cylindrical portion 41 and the collection passage 41a, dripping of the liquid from the ejection hole 4 due to the residual pressure can be suppressed, and the liquid can be easily drained.

  The sliding cylindrical portion 73 is formed in a tapered shape that gradually increases in diameter from the center in the front-rear direction toward the front and the rear, and lip portions 73 a located at both ends in the front-rear direction are provided on the inner peripheral surface of the outer cylindrical portion 60. Slide against

  The connecting portion 70 of the piston 52 is connected to the trigger portion 51 via a connecting shaft 86 described later. As a result, the piston 52 is urged forward by the urging force of the elastic plate portion 54 together with the trigger portion 51, and moves rearward as the trigger portion 51 moves backward and is pushed into the cylinder 53. .

  Further, when the trigger portion 51 is at the foremost swing position (most forward position), the sliding cylinder portion 73 of the piston 52 closes the first ventilation hole 63. Then, when the piston 52 moves backward by a predetermined amount due to the swing of the trigger portion 51 backward, the sliding cylinder portion 73 opens the first ventilation hole 63. Thereby, the inside of the container body A communicates with the outside through the third ventilation hole 65, the second ventilation hole 64, and the first ventilation hole 63.

  The trigger portion 51 includes a main plate member 80 having a front surface that is concavely curved rearward in a side view when viewed from the left and right, and a pair of side plate members 81 that stand rearward from left and right side edges of the main plate member 80. And

At the upper ends of the pair of side plate members 81, a pair of connecting plates 82 extending upward to the side of the injection cylinder 11 and sandwiching the injection cylinder 11 from the left and right are formed. The pair of connecting plates 82 is provided with a rotation shaft 83 projecting outward in the left-right direction. These rotary shafts 83 are rotatably supported by bearings provided on an upper plate member 84 that covers the upper part of the injection cylinder 11.
Thus, the trigger portion 51 can swing in the front-rear direction about the rotation shaft portion 83.

The trigger portion 51 has an opening 51 a penetrating the main plate member 80 in the front-rear direction, and a connecting cylinder 85 extending rearward from a peripheral edge of the opening 51 a.
A pair of connecting shafts 86 protruding toward the inside of the connecting tube 85 along the left-right direction is formed in a portion located on the rear side of the inner peripheral surface of the connecting tube 85. These connecting shafts 86 are inserted into connecting holes formed in the connecting portion 70 of the piston 52. Thereby, the trigger part 51 and the piston 52 are mutually connected.

  The connecting portion 70 of the piston 52 is rotatable around the axis with respect to the connecting shaft 86, and is connected to be movable by a predetermined amount in the vertical direction. This allows the piston 52 to move back and forth with the swing of the trigger portion 51 in the front and rear direction.

The upper plate member 84 in the form of a horizontal plate is attached to the upper surface of the injection cylinder 11.
On the left and right sides of the upper plate member 84, the elastic plate portions 54 are formed integrally with each other, and are formed in an arc shape that protrudes forward in a side view when viewed from the left and right and extend below the injection cylinder 11. I have. The elastic plate portion 54 is formed in a circular arc shape concentric with each other in a side view as viewed from the left and right directions, and includes a pair of leaf springs arranged in front and rear.

Of the pair of leaf springs, the leaf spring located on the front side is the main leaf spring 54a, and the leaf spring located on the rear side is the sub leaf spring 54b.
The lower ends of the main leaf spring 54a and the sub leaf spring 54b are integrally connected via an arc-shaped folded portion 54c. A locking piece 54d projects downward from the folded portion 54c, and the locking piece 54d is inserted from above into a pocket portion 81a formed in the side plate member 81 of the trigger portion 51 to engage therewith. ing.
Accordingly, the elastic plate portion 54 urges the trigger portion 51 forward through the locking piece 54d and the pocket portion 81a.

The upper end portion of the main plate member 80 of the trigger portion 51 is in contact with the lower end portion of the connection wall 123 described later from behind by the bias of the elastic plate portion 54. Thereby, the trigger portion 51 is positioned at the foremost swing position.
When the trigger portion 51 is pulled backward from the foremost swing position, the elastic plate portion 54 is elastically deformed so as to move the folded portion 54c backward via the locking piece 54d. At this time, the sub leaf spring 54b of the elastic plate portion 54 is elastically deformed to be larger than the main leaf spring 54a.

  Even when the trigger portion 51 is pulled rearward, the locking piece 54d keeps coming out of the pocket portion 81a and at the same time until the trigger portion 51 reaches the rearmost swing position (rearmost movement position). The engagement with the pocket portion 81a is maintained.

The ejector main body 2 further includes a closing member 20 mounted on the injection cylinder portion 11 from the front side. The closing member 20 is located on the front side of the front end opening 11a of the injection cylinder portion 11, is provided with an opposing plate portion 21 disposed to face the front opening portion, extends rearward from the opposing plate portion 21, and A first tubular portion 22 fitted externally to the tubular portion 11, a second tubular portion 23 extending forward from the opposing plate portion 21, and located inside the second tubular portion 23 and forward from the opposing plate portion 21. And a connecting wall 123 protruding downward at a connecting portion between the opposing plate portion 21 and the first cylindrical portion 22.
The lower end portion of the connection wall 123 contacts the upper end portion of the main plate member 80 of the trigger portion 51 from the front, thereby positioning the trigger portion 51 at the foremost swing position.

  The support shaft portion 182 is formed so as to fit inside the second cylindrical portion 23 without protruding forward from the second cylindrical portion 23. The second cylindrical portion 23 and the support shaft portion 182 are disposed at positions eccentric downward with respect to the center axis O2 of the injection cylindrical portion 11. An injection hole 25 communicating with the front end opening 11a of the injection cylinder 11 is formed in a portion of the opposing plate 21 located above the support shaft 182 and inside the second cylinder 23. I have. Thereby, the inside of the second cylindrical portion 23 communicates with the inside of the injection cylindrical portion 11 through the injection hole 25 and the front end opening 11a.

(Nozzle part)
The nozzle unit 3 is disposed in front of the ejector main body 2. The nozzle part 3 is mounted on the second cylindrical part 23 of the ejector main body 2. The nozzle portion 3 is disposed in front of the opposing plate portion 21 of the closing member 20, and has a nozzle wall portion 170 in which the ejection hole 4 is formed, extends rearward from the nozzle wall portion 170, and has a second cylindrical portion 23. And an external fitting tube portion 221 that externally fits from the front. The nozzle portion 3 and the ejector main body 2 are connected by attaching the outer fitting tube portion 221 to the second tube portion 23.
The outer fitting tube portion 221 is rotatably attached to the second tube portion 23 in a state where the outer fitting tube portion 221 is prevented from falling out. That is, the nozzle portion 3 is rotatable around the central axis of the second cylindrical portion 23.

A supported cylindrical portion 172 rotatably fitted to the support shaft portion 182 is protruded rearward from a portion of the nozzle wall portion 170 located inside the outer fitted cylindrical portion 221. A first concave groove 172a extending in the front-rear direction is formed on the inner peripheral surface of the supported cylindrical portion 172.
On the front side of the nozzle portion 3, a nozzle plate 175 for switching the jetting form of the liquid into a mist state, a foam state, and the like is attached to be openable and closable around a shaft 176 extending in the left-right direction. In a portion of the rear surface of the nozzle wall portion 170 located inside the supported cylinder portion 172, the spiral circuit 12e is formed in a concave shape.

At the front end of the outer peripheral surface of the support shaft portion 182, a second concave groove 182a that can communicate the first concave groove 172a and the spiral circuit 12e is formed. The first concave groove 172a and the second concave groove 182a communicate with each other at a predetermined rotation position of the nozzle portion 3 along the periphery of the support shaft portion 182, and are in a non-communication state at other rotation positions. That is, the nozzle portion 3 is rotatably mounted on the ejector main body 2, and is configured to switch whether or not to eject the liquid ejected from the ejection hole 4 as the nozzle portion 3 rotates.
Note that, between the supported tubular portion 172 and the outer fitting tubular portion 221, a seal tubular portion 178 that is in close contact with the inside of the second tubular portion 23 is provided.

Between the second tubular portion 23 and the supported tubular portion 172 of the nozzle portion 3, a tubular passing space 183 to which the injection hole 25 communicates from the rear is formed. The passage space 183 communicates with the ejection hole 4 through the first groove 172a, the second groove 182a, and the turning circuit 12e when the first groove 172a and the second groove 182a communicate with each other. Thus, the communication hole 11c and the front end opening 11a, the injection hole 25, the passage space 183, the first concave groove 172a, the second concave groove 182a, and the turning It communicates through the road 12e.
The cross-sectional area of each of the flow paths of the injection hole 25 and the passage space 183 may be larger than the cross-sectional area of the flow path of the introduction path 186 formed by the first concave groove 172a and the second concave groove 182a.

(Operation of trigger type liquid ejector)
Next, a case where the trigger type liquid ejector 1 configured as described above is used will be described.
In addition, it is assumed that the liquid is filled in each part of the trigger type liquid ejector 1 by a plurality of operations of the trigger part 51, and the liquid can be sucked up from the vertical supply cylinder part 10.

  When the trigger portion 51 is pulled backward against the urging force of the elastic plate portion 54, the piston 52 retreats as the trigger portion 51 moves backward, so that the liquid in the cylinder 53 (in the storage chamber 53a) penetrates. It can be introduced into the gap S4 and the accumulator S5 through the hole 66, the gap S3, and the connection cylinder 12f. At this time, the liquid introduced into the reduced diameter portion 13g of the inner cylinder 13 pushes down the suction valve 36 to close it. Thereby, the pressure in the gap S4 and the pressure in the accumulator S5 are increased. When the pressure becomes equal to or higher than a predetermined pressure, the pressure accumulating valve 90 retreats against the forward biasing force of the compression spring 98, and the curved surface portion 91a of the pressure accumulating valve 90 separates from the rear end opening of the communication hole 11c of the injection cylinder portion 11. . This allows the liquid that has passed through the inside of the injection cylinder 11 to be jetted forward from the ejection hole 4 through the front end opening 11a, the ejection hole 25, the passage space 183, the introduction path 186, and the swirling circuit 12e.

When the operation of pulling the trigger 51 is stopped, the supply of the liquid from the inside of the cylinder 53 (the inside of the storage chamber 53a) to the inside of the injection cylinder 11 through the inside of the vertical supply cylinder 10 is stopped. At this time, the pressure accumulating valve 90 advances due to the forward biasing force of the compression spring 98, and the curved surface portion 91a of the pressure accumulating valve 90 closes the communication hole 11c of the injection cylinder portion 11 again. Then, the trigger portion 51 is urged forward by the elastic restoring force of the elastic plate portion 54 to return to the original position, and accordingly, the piston 52 moves forward. Therefore, a negative pressure is generated in the cylinder 53 (in the storage chamber 53a), and the liquid in the container body A can be sucked up into the vertical supply cylinder 10 through the pipe 15 by the negative pressure.
Then, the newly sucked up liquid pushes up the suction valve 36 to open the valve, and is introduced into the cylinder 53 (in the storage chamber 53a). This makes it possible to prepare for the next injection. The rise of the suction valve 36 by a predetermined amount or more is regulated by the top wall 12 d of the outer cylinder 12 that covers the upper part of the suction valve 36.

As described above, according to the trigger-type liquid ejector 1 according to the present embodiment, since the accumulator-type trigger-type liquid ejector 1 includes the accumulator valve 90, for example, the ejection from the ejection hole 4 through the injection cylinder 11 is performed. By stabilizing the pressure of the liquid to be supplied, the liquid can be ejected in a suitable form.
Further, since the pressure accumulating valve 90 is disposed in the injection cylinder portion 11, the structure of the nozzle portion 3 is simplified as compared with a case where the pressure accumulating valve 90 is disposed in the nozzle portion 3, for example. Bulging in the front-rear direction and the vertical direction can be easily suppressed. Further, by arranging the pressure accumulating valve 90 in the injection cylinder portion 11 instead of in the nozzle portion 3 as described above, the degree of freedom of the structure of the nozzle portion 3 can be increased. Accordingly, as the trigger type liquid ejector 1, for example, as in the present embodiment, the nozzle portion 3 is rotatably mounted on the ejector main body 2, and the liquid ejected from the ejection hole 4 with the rotation of the nozzle portion 3. It is possible to easily adopt a configuration or the like for switching whether or not injection is possible.

  Further, since the pressure accumulating valve 90 is provided in the injection cylinder 11, the internal volume of the injection cylinder 11 can be reduced without increasing the number of parts. Thereby, when the trigger portion 51 is operated, the pressure of the liquid in the injection cylinder portion 11 (in the gap S4 and in the pressure accumulating chamber S5) is quickly increased, and the pressure accumulating valve 90 is immediately retracted against the forward urging force. Can be done. Therefore, the liquid can be quickly ejected while the number of priming is suppressed, so that the operability can be improved. Further, since the internal volume of the injection cylinder 11 is reduced, it is difficult for air to remain in the injection cylinder 11, and variations in the ejection amount caused by the remaining air and dripping from the ejection holes 4 are suppressed. can do.

Further, since the pressure accumulating valve 90 is disposed over the entire length in the front-rear direction in the injection cylinder 11, the internal volume of the injection cylinder 11 is further reduced, the number of priming times is reduced, and the air remaining in the injection cylinder 11 is reduced. The effect of suppressing the above can be more reliably achieved.
Further, since the rear part of the pressure accumulating valve 90 and the upper end opening of the vertical supply cylinder 10 are vertically opposed, the liquid that has passed through the vertical supply cylinder 10 is immediately introduced into the gap S4 and the pressure accumulation chamber S5. Thus, the pressure of the liquid acting on the pressure accumulating valve 90 can be quickly increased.

  Note that the technical scope of the present invention is not limited to the above embodiment, and various changes can be made without departing from the spirit of the present invention.

For example, in the above-described embodiment, the pressure accumulator valve 90 is disposed over the entire length in the injection cylinder portion 11, but is not limited thereto. For example, the pressure accumulator valve 90 is disposed only in a part of the injection cylinder portion 11 in the front-rear direction. May be.
Further, in the above-described embodiment, the rear part of the pressure accumulation valve 90 and the upper end opening of the vertical supply cylinder part 10 are described to be opposed to each other in the vertical direction. However, the present invention is not limited to this. It may be located further forward.
In the above-described embodiment, the trigger mechanism 50 including the cylinder 53 and the piston 52 is used. However, the present invention is not limited to this. A configuration in which the liquid in the container body A flows toward the ejection hole 4 through the inside of the portion 11 may be adopted.
Further, in the above-described embodiment, the trigger type liquid ejector 1 that ejects the liquid forward from the ejection hole 4 has been described. However, the present invention is not limited to this, and may be directed to a direction other than forward, such as upward or leftward. A trigger type liquid ejector that ejects liquid may be employed.

  In addition, without departing from the spirit of the present invention, it is possible to appropriately replace the components in the above-described embodiment with known components, and the above-described modifications may be appropriately combined.

DESCRIPTION OF SYMBOLS 1 ... Trigger type liquid ejector, 2 ... ejector main body, 3 ... nozzle part, 4 ... ejection hole, 10 ... vertical supply cylinder part, 11 ... injection cylinder part, 11a ... front end opening, 50 ... trigger mechanism, 51 ... trigger Part, 52: piston, 53: cylinder, 90: pressure accumulator, A: container

Claims (4)

An ejector body attached to the container body containing the liquid,
A nozzle unit provided on the front side of the ejector main body and having an ejection hole for ejecting liquid,
The ejector body,
A vertical supply cylinder extending vertically and sucking up the liquid in the container,
An injection tube portion extending forward from the vertical supply tube portion and having an inner side communicating with the inside of the vertical supply tube portion,
A trigger portion disposed in front of the vertical supply cylinder portion so as to be movable rearward in a forward biased state, and by moving the trigger portion rearward, liquid is transferred from the inside of the vertical supply cylinder portion to the inside of the injection cylinder portion. And a trigger mechanism for injecting from the front end opening of the injection cylinder toward the ejection hole side, and a trigger type liquid ejection device,
In the injection cylinder portion, a pressure accumulating valve that is disposed movably rearward in a forward biased state and that closes the front end opening of the injection cylinder portion in an openable manner is disposed .
A closing lid is provided at the rear of the pressure accumulating valve, and a compression spring separate from the pressure accumulating valve and the closing lid is compressed between the pressure accumulating valve and the closing lid. Trigger-type liquid ejector characterized in that is biased forward .   The trigger type liquid ejector according to claim 1, wherein the pressure accumulating valve is disposed over the entire length in the front-rear direction in the injection cylinder portion.   The trigger type liquid ejector according to claim 1, wherein a rear part of the pressure accumulating valve and an upper end opening of the vertical supply cylinder part are vertically opposed to each other. A piston that moves in the front-rear direction in conjunction with the swing of the trigger portion,
A cylinder whose inside is pressurized and depressurized with the movement of the piston,
The cylinder has a through-hole for introducing liquid into the cylinder when the piston moves forward, and discharging liquid in the cylinder when the piston moves backward,
4. The vertical supply cylinder portion according to claim 1, wherein a recovery passage that connects the inside of the cylinder and the container body when the piston moves to the rearmost movement position is formed. 5. Item 4. The trigger type liquid ejector according to the above item.

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