Trigger-type liquid jetting device

Abstract

Provided is a trigger-type liquid dispenser (1) including an operating lever (6) held swingably by a main body portion (3) in which a pump is disposed and including a spring member (7) that imparts restoring force to the operating lever (6). The trigger-type liquid dispenser (1) is configured to draw, pressurize, and force-feed a content liquid contained in a container (C) to dispense the content liquid through a nozzle (5), by actuating the pump in response to the operating lever (6) being pulled repeatedly. The spring member (7) is held swingably with respect to the main body portion (3), and, in response to the operating lever (6) being pulled, the spring member (7) undergoes elastic deformation and swings with respect to the main body portion (3).

Claims

1. A trigger-type liquid dispenser comprising: an operating lever held swingably by a main body portion in which a pump is disposed; and a spring member that imparts restoring force to the operating lever, the trigger-type liquid dispenser being configured to draw, pressurize, and force-feed a content liquid contained in a container to dispense the content liquid through a nozzle, by actuating the pump in response to the operating lever being pulled repeatedly, wherein the main body portion includes a bearing or a shaft portion, the spring member includes at least one arm including one end having a shaft or a bearing portion held swingably by the bearing or the shaft portion included in the main body portion, another end abutting against the operating lever, and a curved portion connecting the one end and the other end, in response to the operating lever being pulled, the pair of curved portions undergo elastic deformation and swing about the shaft portion of the main body portion or the spring member, the main body portion includes a longitudinal tube, a horizontal tube which extends toward a front of the main body and that is connected to the longitudinal tube, and a cylindrical fitting wall which extends toward the front from the longitudinal tube and holds a cylinder member below the horizontal tube, and the bearing or the shaft portion is disposed between the horizontal tube and the cylindrical fitting wall of the main body portion.

2. The trigger-type liquid dispenser of claim 1, wherein the spring member includes the shaft portion held swingably by the bearing portion included in the main body and a pair of arms, including the at least one arm, extending from both ends of the shaft portion of the spring member, and the shaft portion and the pair of arms are formed integrally.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the accompanying drawings:

(2) FIG. 1 is a side sectional view illustrating a trigger-type liquid dispenser according to one of embodiments of the present disclosure;

(3) FIG. 2A is a side view,

(4) FIG. 2B is a back view, and

(5) FIG. 2C is a plan view illustrating a spring member included in a trigger-type liquid dispenser of FIG. 1;

(6) FIG. 3 illustrates a pulled state in which an operating lever included in a trigger-type liquid dispenser of FIG. 1 is pulled; and

(7) FIG. 4 is a perspective view illustrating a portion of a conventional trigger-type liquid dispenser.

DETAILED DESCRIPTION

(8) The present disclosure will be described in more detail below with reference to the drawings. Note that, in the specification, the claims, the abstract, and the drawings of the present disclosure, the side (corresponding to the upper side in FIG. 1) on which a top wall of a cover which is later described is located is defined as upper direction, and the side (corresponding to the lower side in FIG. 1) on which a fitting cap is disposed is defined as lower direction. Furthermore, the side (corresponding to the left side in FIG. 1) on which a nozzle is disposed is defined as front direction, and the opposing side (corresponding to the right side in FIG. 1) is defined as rear direction. Moreover, the directions (corresponding to the directions that are orthogonal to the drawing in FIG. 1) that are orthogonal to the upper-lower direction and the front-rear direction are defined as side directions.

(9) In FIG. 1, reference numeral 1 denotes a trigger-type liquid dispenser according to one of embodiments. The trigger-type liquid dispenser 1 includes: a fitting cap 2 attached to a mouth of a container C; a main body portion 3 that holds the fitting cap 2 in a manner such that the fitting cap 2 is allowed to rotate and prevented from slipping off and that includes a pump configured to draw, pressurize, and force-feed a content liquid contained in the container C; a pipe 4 that is coupled to the main body portion 3, that extends toward a bottom of the container C, and that is configured to draw the content liquid contained in the container C by the pump being actuated; a nozzle 5 disposed in front of the main body portion 3 to dispense the content liquid to the outside; an operating lever 6 that is held swingably by the main body portion 3 and that actuates the pump by being pulled repeatedly; a spring member 7 that imparts restoring force to the operating lever 6; and a cover 8 that covers the upper and the side parts of the main body portion 3.

(10) The fitting cap 2 is provided, on an inner surface of a cylindrical side wall 2a thereof, a screw portion 2b configured to engage with a screw portion provided in the mouth of the container C. Above the side wall 2a, a ceiling wall 2d, which is provided in the middle thereof with an upper opening 2c, is disposed.

(11) In the present embodiment, the main body portion 3 is formed by a plurality of members, and the fitting cap 2 is attached to a body 10, which is one of the plurality of members. The body 10 includes a cylindrical coupling tubular portion 10a that is inserted through the upper opening 2c and a flange 10b that is disposed on an outer circumferential surface of the coupling tubular portion 10a and that extends to the outer side in the radial direction. Below the flange 10b, a packing is also disposed to be sandwiched between an upper end of the mouth of the container C and the flange 10b. Furthermore, the body 10 includes, above the coupling tubular portion 10a, a longitudinal tube 10c, whose diameter is smaller than that of the coupling tubular portion 10a, and also includes, above the longitudinal tube 10c, a horizontal tube 10d that extends toward the front and that is connected to the longitudinal tube 10c. The nozzle 5 is disposed in the front end portion of the horizontal tube 10d.

(12) The horizontal tube 10d is provided with groove portions 10e which each have a U-shape whose upper side is opened in a side view. Below the horizontal tube 10d, a cylindrical fitting wall 10f, which extends toward the front from the longitudinal tube 10c, is disposed.

(13) There is also disposed a tubular portion 11a of an intake 11 inside the longitudinal tube 10c. Furthermore, the tubular portion 11a of the intake 11 is provided, inside thereof, with the first check valve 11b and the second check valve 11c that prevent backflow of the content liquid drawn by the pump. The first check valve 11b is brought into an opened state when the content liquid is drawn by using a pump function and brought into a closed state when the drawn content liquid is pressurized and force-fed. On the other hand, the second check valve 11c is brought into a closed state when the content liquid is drawn by using the pump function and brought into a closed state when the drawn content liquid is pressurized and force-fed toward the nozzle 5.

(14) Herein, there is disposed an upright and invert dual mechanism X between the pipe 4 and the intake 11 in the present embodiment. The upright and invert dual mechanism X allows the content liquid contained in the container C to be supplied to the main body portion 3 both in an upright and an inverted position of the container C. The upright and invert dual mechanism X includes a valve-mounted tubular member 14 disposed inside the mouth of the container C and a pipe attachment member 15 disposed below the valve-mounted tubular member 14.

(15) The valve-mounted tubular member 14 is formed by a drawing member 16 including an inner tube 16a disposed inside the tubular portion 11a of the intake 11 and a valve member 17 including an outer tube 17a disposed on the outer side of a lower portion of the inner tube 16a. Between the drawing member 16 and the valve member 17, a valve chamber V, in which a valve body 18 is disposed, is formed. The drawing member 16 is provided with an inversion-time drawing hole 16b permitting the valve chamber V to communicate with the inside of the container C, and the valve member 17 is provided with a through hole 17b that is closed by the valve body 18 in the upright position of the container C and that is opened in the inverted position of the container C.

(16) The pipe attachment member 15, to which the pipe 4 is coupled, is fitted to the drawing member 16 from below with the valve member 17 being interposed therebetween, and an inversion-time flow path 19 is formed between the pipe attachment member 15 and the valve member 17. The inversion-time flow path 19 communicates with the tubular portion 11a of the intake 11 via the inner tube 16a.

(17) There is also provided a cylinder member 12 on the inner side of the fitting wall 10f of the body 10. The cylinder member 12 has a coaxial double-tube structure consisting of a cylindrical cylinder tube 12a that is fitted to and held by the fitting wall 10f and a cylindrical partition tube 12b that is disposed on the inner side of the cylinder tube 12a in the radial direction. The cylinder tube 12a and the partition tube 12b are connected to each other on the rear sides thereof via an inner wall 12c.

(18) The inner wall 12c is provided with a hole 12d that is fitted in a hole of the longitudinal tube 10c and that communicates with a hole 11d of the intake 11. Furthermore, although not illustrated, the cylinder tube 12a is provided, on the side thereof, with an ambient air inlet that permits the inside of the cylinder tube 12a to communicate with the outside and that communicates with a hole 10h provided in the fitting wall 10f via a gap formed between the fitting wall 10f and the cylinder tube 12a.

(19) Inside the cylinder member 12, a piston 13 is disposed. The piston 13 seals the inside of the cylinder member 12 and defines a cylinder chamber R. The piston 13 includes an annular slide portion 13a that slidably abuts against an inner circumferential surface of the cylinder tube 12a, and the slide portion 13a is provided with a circumferential wall portion 13b that extends toward the front and that has a closed front end. Additionally, the slide portion 13a closes the ambient air inlet provided in the cylinder member 12 in the state where the operating lever 6 is not pulled.

(20) Thus, in the present embodiment, the main body portion 3 having the pump function is formed by the body 10, the intake 11, the upright and invert dual mechanism X, the cylinder member 12, and the piston 13.

(21) The operating lever 6 in the present embodiment includes a front wall 6a and a pair of side walls 6b disposed on both sides of the front wall 6a. The operating lever 6 also includes a pair of columnar pivot shafts 6c that engages swingably with the pair of groove portions 10e provided in the horizontal tube 10d included in the body 10. The operating lever 6 is also provided with a columnar convex portion 6d that engages with an engagement concave portion 13c of the piston 13.

(22) Herein, as illustrated in detail in FIGS. 2A to 2C, the spring member 7 in the present embodiment includes a columnar shaft portion 7a and a pair of arms 7b extending from both ends of the shaft portion 7a, and the shaft portion 7a and the pair of arms 7b are formed integrally. Each arm 7b is formed by one end 7c in which the shaft portion 7a is disposed, the other end 7d that abuts against the operating lever 6, and a curved portion 7e that connects the one end 7c and the other end 7d. Herein, the spring member 7 in the present embodiment may be made of a resin material. However, the present disclosure is not limited to this embodiment. The shaft portion 7a and the arms 7b of the spring member 7 may also be formed as separate members which may be connected by, for example, an adhesive, or alternatively, the arms 7b may be coupled swingably to the shaft portion 7a formed separately.

(23) As illustrated in FIG. 1, the shaft portion 7a is held swingably by the bearing portion 10g disposed between the horizontal tube 10d and the fitting wall 10f of the body 10, and the pair of curved portions 7e is disposed on both sides in a manner such that the horizontal tube 10d is sandwiched by the curved portions 7e. The other end 7d abuts against the front wall 6a of the operating lever 6 and is supported from below by a support rib 6e provided on an inner surface of each side wall 6b. Additionally, in response to the operating lever 6 being pulled, the support rib 6e serves as a pressing portion that presses the other end 7d of the arm 7b toward the one end 7c.

(24) The way of holding the spring member 7 swingably with respect to the main body portion 3 is not limited to the structure according to the present embodiment, and another structure may also be adopted. For example, the bearing portion may be provided in the spring member 7, and the shaft portion, configured to engage with the bearing portion, may be provided in the main body portion 3.

(25) FIG. 3 illustrates a pulled state in which the operating lever 6 is pulled from an initial state illustrated in FIG. 1. In the trigger-type liquid dispenser 1 according to the present embodiment, once the operating lever 6 is pulled from the initial state to cause the piston 13 to retract to the rear with respect to the cylinder member 12, the liquid contained in the cylinder chamber R is pressurized, and the pressurized liquid passes through the holes 12d and 11d and the second check valve 11c, and then through the inside of the horizontal tube 10d, to be injected from the nozzle 5 to the outside. Subsequently, when being released, the operating lever 6 swings toward the front due to the restoring force of the spring member 7, and accordingly, the piston 13 is caused to advance to the front with respect to the cylinder member 12. Consequently, the cylinder chamber R is placed under negative pressure. Thus, the liquid contained in the container C is drawn via the pipe 4 in the upright position and via the inversion-time drawing hole 16b, the through hole 17b, and the inversion-time flow path 19 in the inverted position, and the drawn liquid pushes up the first check valve 11b to flow into the cylinder chamber R. By thus pulling and releasing the operating lever 6 repeatedly, the liquid contained in the container C may be injected from the nozzle 5 successively.

(26) In the trigger-type liquid dispenser 1 according to the present disclosure that has the aforementioned structure, each arm 7b undergoes elastic deformation and swings about the shaft portion 7a from the initial state illustrated in FIG. 1 to the pulled state illustrated in FIG. 3. Accordingly, compared with conventional cases where a spring member undergoes elastic deformation while a portion of the spring member is fixed to the main body portion, the magnitude of deformation of the spring member 7 undergoing elastic deformation is reduced. This reduces load applied to the spring member 7 and prevents occurrence of plastic deformation caused by long-term repeated use, and therefore, a decrease in discharge dose is prevented. Furthermore, since the magnitude of deformation of the spring member 7 undergoing elastic deformation is reduced, the operating lever 6, when being pulled, does not generate an excessive repulsive force and may be pulled easily with slight force.

(27) Moreover, since the shaft portion 7a and the pair of arms 7b are formed integrally in the trigger-type liquid dispenser 1 according to the present embodiment, the number of members is reduced, and manufacturing cost and time are reduced.

(28) Although the present disclosure has been described based on the illustrated examples, the present disclosure is not limited to the above embodiment and may be changed as appropriate within the scope of the claims. For example, although in the present embodiment the spring member includes the pair of arms 7b, the spring member may include only a single arm. Furthermore, the shape of the curved portion 7e is not limited to the illustrated shape. Moreover, the internal structure of the main body portion 3 that provides the pump function is not limited to the one according to the present embodiment, and any other commonly used structure may be adopted.

REFERENCE SIGNS LIST

(29) 1 Trigger-type liquid dispenser

(30) 2 Fitting cap

(31) 2a Side wall

(32) 2b Screw portion

(33) 2c Upper opening

(34) 2d Ceiling wall

(35) 3 Main body portion

(36) 4 Pipe

(37) 5 Nozzle

(38) 6 Operating lever

(39) 6a Front wall

(40) 6b Side wall

(41) 6c Pivot shaft

(42) 6d Convex portion

(43) 6e Support rib

(44) 7 Spring member

(45) 7a Shaft portion

(46) 7b Arm

(47) 7c One end

(48) 7d Other end

(49) 7e Curved portion

(50) 8 Cover

(51) 10 Body

(52) 10a Coupling tubular portion

(53) 10b Flange

(54) 10c Longitudinal tube

(55) 10d Horizontal tube

(56) 10e Groove portion

(57) 10f Fitting wall

(58) 10g Bearing portion

(59) 10h Hole

(60) 11 Intake

(61) 11a Tubular portion

(62) 11b First check valve

(63) 11c Second check valve

(64) 11d Hole

(65) 12 Cylinder member

(66) 12a Cylinder tube

(67) 12b Partition tube

(68) 12c Inner wall

(69) 12d Hole

(70) 13 Piston

(71) 13a Slide portion

(72) 13b Circumferential wall portion

(73) 13c Engagement concave portion

(74) 14 Valve-mounted tubular member

(75) 15 Pipe attachment member

(76) 16 Drawing member

(77) 16a Inner tube

(78) 16b Inversion-time drawing hole

(79) 17 Valve member

(80) 17a Outer tube

(81) 17b Through hole

(82) 18 Valve body

(83) 19 Inversion-time flow path

(84) C Container

(85) R Cylinder chamber

(86) V Valve chamber

(87) X Upright and invert dual mechanism