JP2010275002A - Aerosol container with closing valve - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable degassing in an aerosol container with a closing valve. <P>SOLUTION: The aerosol container with a closing valve is constituted so that a locking tool 30 which can be inserted into a depressing head 60 from an appropriate position of the outer peripheral wall 66 of the depressing head 60, and when a valve rod 82 is at a backward position, by inserting the locking tool 30, the tip part of the locking tool 30 is locked to a part of a lever member 88 or the valve rod 82, to keep an opening condition of a nozzle hole 74. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an aerosol container with a closing valve.

  In order to prevent gas from remaining inside when the aerosol container is discarded, a degassing mechanism is provided. Specifically, it comprises an aerosol container body that erects an upwardly biased stem and a cap that can be fitted to the upper part of the container body, and a pressing portion that allows a part of the cap to be screwed down with respect to the cap body. When the use is completed, the cap is removed, the pressing portion is screwed down, and then the cap is re-fitted to the container body so that the pressing portion pushes down the stem (Patent Document 1).

  Although not an aerosol container, a valve rod that moves forward and backward by a lever member as the pressing head descends and rises is provided inside the head body to improve the liquid running out of the liquid ejected from the pressing head. In addition, a valve in which a closing valve is formed by the tip of the valve stem and the front surface of the pressing head is known (Patent Document 2).

JP2008-110801 JP 2004-359238 A

  The degassing mechanism of the aerosol container of Patent Document 1 cannot be used for a container having a closing valve as in Patent Document 2 because of its structure. Also, as in Patent Document 2, it is troublesome to degas the part of the cap that is rotated (screwed down).

  The first object of the present invention is to enable degassing in an aerosol container equipped with a closing valve.

  The second object of the present invention is to enable degassing by a simple operation in an aerosol container with a closing valve, and to ensure that the operation can be performed.

First, the first means includes an aerosol container body 2 that erects an upwardly biased stem 6, and
A tubular mounting device 42 fitted to the upper part of the stem so as to be able to move up and down together with the stem 6, and an operating member 40 formed by a pressing head 60 attached to the tubular mounting device so as to be able to move up and down.
An injection cylinder 70 is formed in the upper part of the outer peripheral wall 66 of the pressing head 60 so as to communicate with the inside of the stem and open the nozzle hole 74 in the front surface of the outer peripheral wall 66 in the front-rear direction. A lever member that forms a closing valve 84 with the front end surface of the valve rod 82 stored and the rear surface of the nozzle hole 74 and converts a force for raising and lowering the push-down head 60 into a horizontal force for moving the valve rod 82 backward or forward. 88, the closing valve 84 is opened by the lowering of the pressing head 60 with respect to the tubular mounting tool 42, and then the stem 6 is lowered together with the entire operation member 40 to the first lowered position, so that the stem 6 In the aerosol container configured such that the discharge is ejected from the nozzle hole 74 and the closing valve 84 is closed by the release of the stem 6 and the operating member 40,
Furthermore, when the stem 6 is pushed down together with the actuating member 40 to a second lowered position below the first lowered position, a fixing means 38 for fixing the stem and the actuating member 40;
A locking tool 30 that can be inserted into the push-down head 60 from a proper position on the outer peripheral wall 66,
By inserting the locking tool 30 into the pressing head, the tip of the valve rod presses the lever member 88 or a part of the valve rod 82 to move the valve rod 82 backward, and the lever member or valve rod is The nozzle hole 74 is locked and maintained in the open state.

  In this means, as a degassing means for an aerosol container with a shut-off valve, a locking tool is proposed that is inserted from the outside of the outer peripheral wall of the push-down head. In an aerosol container with a shut-off valve, even if the stem is simply pushed down, if the shut-off valve is closed, the degassing state will not occur. A locking tool is used to stop the normal function of closing the closing valve when the pressing head is released.

  The “locking tool” has a function of restricting the movement of the valve stem as described above and retaining the valve stem in the rear position (preferably the rear limit position). The locking tool may lock the lever member as shown in FIG. 1, or may lock the valve stem as shown in FIG. In both illustrated examples, the locking pieces are locked to the lower end portion of the lever member and the tip end portion of the valve rod, but may be locked to other locations. Although it is desirable to detachably attach the locking tool to any one of the container main body, the shoulder cover, and the push-down head, it can be combined with an aerosol container body with an actuating member.

The second means includes the first means, and the lever member 88 has a dogleg shape, and one end is linked to the rear end of the valve rod 82 and the other end is connected to the cylindrical mounting tool 42. Abutting on the top surface of the top plate 52 and pivoting the central portion at an appropriate position of the pressing head 60;
An insertion port 68 is formed in the outer peripheral wall 66 of the push-down head 60, and the insertion rod 34 of the locking tool 30 is inserted into the insertion port. It is comprised so that it can insert between the other ends of 88.

  In this means, the locking tool can be inserted between the lever member and the cylindrical mounting tool. Since the locking tool is sandwiched between the lever member and the cylindrical mounting tool by the forward biasing force of the valve stem, the locking tool is unlikely to fall off from this locked state. In addition, the user feels secure that the degassing operation has been performed properly because the feeling of resistance to insertion increases when moving from the stage before clamping to the stage after clamping. . On the other hand, in a degassing mechanism (for example, Patent Document 1) in which a part of the cap is lowered and the cap is re-fitted, if the gas is not ejected even if a predetermined degassing operation is performed, the residual gas is I don't know if there was no gas because it wasn't there, or if the operation wasn't appropriate.

The third means has the second means, and the locking tool 30 projects at least one insertion rod 34 from the wide handle 32 and fits the insertion rod into the insertion opening 68. The handle 32 is configured to remain outside the push-down head 60 when it is retracted.

  In this means, it is proposed that the base end portion of the locking tool is a wide handle. "Wide" is at least wider than the insertion rod and wider than the insertion slot. Since the handle remains outside the pressing head, it becomes clear that the degassing operation has been completed when the container is discarded.

The fourth means includes any one of the first means to the third means, and further includes a shoulder cover 10 attached to the upper portion of the aerosol container body 2 so as to surround the stem 6.
The fixing means 38 is formed by engaging strips 38a and 38b formed so as to be able to engage with the shoulder cover 10 and the cylindrical mounting tool 42.

The fifth means includes the fourth means, and the locking tool 30 is detachably assembled to a part of the shoulder cover 10.

  Since this means is assembled to a part of the shoulder cover, the locking tool is not lost, and it does not interfere with the normal pressing operation of the pressing head. As an assembling method, as shown in FIG. 1, fitting into the fitting hole is preferable, but not limited thereto.

  According to the invention relating to the first means, the lever rod 82 of the closing valve 84 or the lever member linked to the valve rod is locked by inserting a locking tool from the outside, which is suitable for the configuration of an aerosol container with a closing valve. A degassing mechanism can be proposed.

  According to the second aspect of the invention, since the locking tool 30 is inserted between the end of the lever member linked to the valve stem 82 and the cylindrical mounting tool, the locking tool is mounted on the lever member and the cylindrical mounting tool. It is clamped between the tools and the locked state is reliably maintained.

  According to the third aspect of the invention, since the handle 32 remains outside the pressing head 60 with the insertion rod 34 of the locking tool 30 inserted into the pressing head 60, the degassing operation has been performed. Is apparently clear.

  According to the invention relating to the fourth means, the fixing means 38 of the push-down head 60 is formed by the engagement strips 38a, 38b formed so as to be able to engage with each other on the shoulder cover 10 and the cylindrical mounting tool 42. The pressing head can be securely fixed.

  According to the fifth aspect of the invention, since the locking tool 30 is detachably assembled to a part of the shoulder cover 10, it is convenient for storage and transportation.

It is a longitudinal cross-sectional view of the aerosol container with a closing valve which concerns on the 1st Embodiment of this invention. It is a side view at the time of normal use of the aerosol container of FIG. It is a top view of the latching tool of the aerosol container of FIG. It is a rear view of the aerosol container of Drawing 1 in the state where a locking tool was removed. It is a longitudinal cross-sectional view of the 1st process at the time of degassing of the aerosol container of FIG. It is a top view in the state corresponding to FIG. It is sectional drawing of the 2nd process at the time of degassing of the aerosol container of FIG. It is a longitudinal cross-sectional view at the time of degassing of the aerosol container with a closing valve which concerns on the 2nd Embodiment of this invention. It is a top view of the aerosol container corresponding to FIG. It is a principal part front view of the aerosol container corresponding to FIG.

  1 to 7 show an aerosol container with a closing valve according to a first embodiment of the present invention.

  This aerosol container is formed by the aerosol container body 2, the shoulder cover 10, the locking tool 30, the operating member 40, and the cap 90. In addition, a shoulder cover, a locking tool, an operation member, and a cap can each be formed with a synthetic resin material.

  The aerosol container body 2 includes a trunk portion, a shoulder portion, and a mountain cup having an engagement ring 4 provided around the upper end of the shoulder portion, and a stem 6 urged upward from the upper surface thereof. To do.

  The shoulder cover 10 hangs a connecting cylinder 12 fitted to the outer surface of the engagement ring 4 from an annular top wall 14. An inner cylinder 16 is erected from the inner edge of the top wall 14, and a first engagement strip 38 a is provided around the inner surface of the inner cylinder. In addition, a part of the top wall is raised in a double cylinder shape between the inner cylinder 16 and the connecting cylinder 12, and the inner surface of the raised portion 20 is used as a guide surface 22 of a push-down head described later. A pair of left and right fitting holes 24 are formed in the rear portion of the upper wall of the raised portion 20. Of course, the location of the fitting hole can be changed as appropriate. In the illustrated example, a plurality of hanging walls 26 are suspended from the back surface of the top wall portion between the raised portion 20 and the inner cylinder and are brought into contact with the upper end surface of the engagement ring 4.

  As shown in FIG. 3, the locking member 30 is U-shaped as a whole, and a pair of left and right insertion rods 34 protrude from both sides of a wide left and right handle 32 that is a base end portion. As shown in FIG. 1, the distal ends of both insertion rods have a wedge shape with one side being an inclined surface 35. However, this configuration can be changed as appropriate.

  The actuating member 40 is formed by a cylindrical mounting tool 42 and a pressing head 60.

  The cylindrical mounting tool 42 is fitted and fixed to the stem 6 of the aerosol container body 2 and is formed so as to be movable up and down together with the stem. The illustrated cylindrical mounting tool 42 is further formed by a connecting tube 44 and a cylindrical support base 50. The connecting pipe 44 has a lower end portion on the inner surface having a large inner diameter portion, and the upper end portion of the stem 6 is fitted in the large inner diameter portion. A vertical rib 46 is attached to the outer surface of the connecting pipe 44, and a second engagement strip 38b is attached to the lower portion of the outer surface of the vertical rib. The second engaging strip 38b and the first engaging strip 38a form a fixing means 38 for the operating member when degassing. A plurality of projecting pieces 48 that are continuous with the upper ends of the vertical ribs 46 project from the outer surface of the connecting pipe. The support base 50 erects a support tube 54 that communicates with the stem 6 from the center of the top plate 52, and further includes a joint tube 56 that fits from the inner periphery of the top plate 52 to the upper portion of the connecting pipe 44. The slide cylinders 58 are respectively suspended from the outer periphery of the slide cylinder 58.

  The pressing head 60 includes a head main body 62, a valve stem 82, a substrate 86, and a lever member 88.

  The head body 62 has an outer peripheral wall 66 that hangs down from the outer edge of the top plate 64. The lower outer surface of the outer peripheral wall is slidably in contact with the above-described guide surface 22, and the lower half inner surface of the outer peripheral wall 66 is slidably in contact with the outer surface of the slide cylinder 58. A pair of left and right insertion ports 68 are formed in the rear wall portion of the outer peripheral wall 66 in correspondence with the height of the upper surface of the support cylinder 54 in the initial state of FIG. The shape and size of each insertion port and the distance between both ports are made to correspond to the cross-sectional shape and size of the insertion rod and the distance between both rods.

  Further, the head main body 62 has a horizontal cylinder that opens in the front-rear direction extending from the front end portion to the rear side of the top plate 64 in the front-rear direction, and a nozzle hole 74 at the tip thereof in the cylinder hole. The injection cylinder 70 is formed by inserting the nozzle cylinder 72 having the same. The nozzle cylinder 72 is tapered and a nozzle hole 74 is opened inside the throttle portion (a peripheral portion of the nozzle hole) 76. The rear surface of the injection cylinder 70 is closed by a vertical rear wall 78. A gap for inserting a lever member described later is provided between the rear wall and the rear wall portion of the outer peripheral wall 66 of the head body. A through hole is formed in the lower part of the cylinder wall of the injection cylinder, and a hanging cylinder 80 from around the through hole is fitted on the outer surface of the support cylinder 54 in a liquid-tight and slidable manner.

  A valve rod 82 urged forward by a spring is inserted into the injection cylinder 70. The front end surface of the valve stem is in contact with the rear side of the hole edge of the nozzle hole 74 to form a closing valve 84. The rear end portion of the valve stem 82 penetrates the rear wall 78 and protrudes rearward. A substrate 86 having a through hole through which the drooping cylinder 80 is inserted is provided on the lower surface of the injection cylinder 70. A through hole for inserting a lever member is formed in the rear portion of the substrate 86, and bearings are provided on both sides of the through hole. A lever member 88 having a "<" shape is provided on the bearing so as to be seen from the side. The upper end portion of the lever member is locked to the rear end portion of the valve rod 82, and the lower portion of the lever member is divided into two portions and brought into contact with the top plate 52 portions on both sides of the drooping cylinder 80.

  The cap 90 is fitted to the outer surface of the raised portion 20 of the shoulder cover so as to cover the pressing head 60.

  In the above configuration, when the cap 90 is removed from the state of FIG. 1 and the top surface of the pressing head 60 is pressed down, the pressing head 60 is first lowered with respect to the cylindrical mounting cylinder 42. Then, the lever member rotates, the valve stem moves backward, and the stem together with the actuating member descends to the position shown in FIG. 2 (first lowered position), and the discharged material from the stem 6 passes through the injection cylinder to the nozzle hole 74. Erupted from. In this state, the first engagement strip 38a and the second engagement strip 38b are in contact with each other, but are not yet engaged. When the pressing of the pressing head is released, the state returns to the state shown in FIG. Next, when degassing, the locking tool 30 is pulled out from the fitting hole 24 and inserted into the insertion port 68 as shown in FIG. Then, since the insertion rod 34 pushes up the lower end portion of the lever member 88, the lever member rotates and the valve rod 82 is retracted. Accordingly, the nozzle hole 74 is opened. When the stem is pushed down to the second lowered position shown in FIG. 7 together with the operating member 40 in this state, the inner cylinder 16 comes into pressure contact with the lower surface of the projecting piece 48, and the first engagement strip 38a and the second engagement of the inner cylinder The joint 38b engages. As a result, the stem 6 is fixed at the second lowered position, and is ejected until there is no remaining gas left in the container body 2.

  Hereinafter, other embodiments of the present invention will be described. In these descriptions, the same components as those in the first embodiment are denoted by the same reference numerals and the description thereof is omitted.

8 to 10 show a second embodiment of the present invention. In this embodiment, instead of making the insertion port 68 in the outer peripheral wall 66 of the pressing head 60, the tip of the locking tool 30 can be inserted from the nozzle hole. As shown in FIG. 10 which is a front view of the main part, the distal end portion of the locking tool 30 is formed in a cross-shaped insertion portion 36, and this insertion portion 36 is the front surface of the valve stem 82 and the throttle portion around the nozzle. 76 is formed so as to be sandwiched between the rear surface. Thereby, gas is discharged | emitted from the clearance gap between cross-shaped insertion parts.
In the configuration in which the connecting ring 44 has the projecting pieces 48 as in the illustrated example, these projecting pieces 48 are formed on a flexible plate portion, and the push-down head 60 is pushed down from the state of FIG. The protrusions may be formed so that they can bend when they contact the lower surface of the protrusions.

2 ... Aerosol container body 4 ... Engagement ring 6 ... Stem 10 ... Shoulder cover 12 ... Connecting cylinder 14 ... Top wall 16 ... Inner cylinder 20 ... Raised part
22 ... Guide surface 24 ... Fitting hole 26 ... Vertical wall 30 ... Locking tool 32 ... Handle 34 ... Insertion rod 35 ... Inclined surface 36 ... Insertion part
38 ... Fixing means 38a ... first engaging strip 38b ... second engaging strip
DESCRIPTION OF SYMBOLS 40 ... Actuating member 42 ... Cylindrical mounting tool 44 ... Connecting pipe 46 ... Vertical rib 48 ... Protruding piece 50 ... Support stand 52 ... Top plate 54 ... Supporting cylinder 56 ... Joint cylinder 58 ... Slide cylinder
60 ... Pushing head 62 ... Head body 64 ... Top plate 66 ... Outer peripheral wall 68 ... Inlet port 70 ... Injection cylinder 72 ... Nozzle cylinder 74 ... Nozzle hole 76 ... Throttle part 78 ... Rear wall 80 ... Drop cylinder 82 ... Valve rod 84 ... Close valve
86 ... Substrate 88 ... Lever member 90 ... Cap

Claims (5)

An aerosol container body 2 that erects the stem 6 biased upward;
A tubular mounting device 42 fitted to the upper part of the stem so as to be able to move up and down together with the stem 6, and an operating member 40 formed by a pressing head 60 attached to the tubular mounting device so as to be able to move up and down.
An injection cylinder 70 is formed in the upper part of the outer peripheral wall 66 of the pressing head 60 so as to communicate with the inside of the stem and open the nozzle hole 74 in the front surface of the outer peripheral wall 66 in the front-rear direction. A lever member that forms a closing valve 84 with the front end surface of the valve rod 82 stored and the rear surface of the nozzle hole 74 and converts a force for raising and lowering the push-down head 60 into a horizontal force for moving the valve rod 82 backward or forward. 88, the closing valve 84 is opened by the lowering of the pressing head 60 with respect to the tubular mounting tool 42, and then the stem 6 is lowered together with the entire operation member 40 to the first lowered position, thereby discharging from the stem 6. In an aerosol container in which an object is ejected from the nozzle hole 74 and the closing valve 84 is closed by releasing the stem 6 and the operating member 40,
Furthermore, when the stem 6 is pushed down together with the actuating member 40 to a second lowered position below the first lowered position, a fixing means 38 for fixing the stem and the actuating member 40;
A locking tool 30 that can be inserted into the push-down head 60 from a proper position on the outer peripheral wall 66,
By inserting the locking tool 30 into the pressing head, the tip of the valve rod presses the lever member 88 or a part of the valve rod 82 to move the valve rod 82 backward, and the lever member or valve rod is An aerosol container with a shut-off valve, which is configured to be locked and to maintain the open state of the nozzle hole 74. The lever member 88 has a dogleg shape, one end is linked to the rear end of the valve rod 82, the other end is in contact with the top surface of the top plate 52 of the cylindrical mounting tool 42, and the central portion is pushed down by the head 60. Pivot to the right place
An insertion port 68 is formed in the outer peripheral wall 66 of the push-down head 60, and the insertion rod 34 of the locking tool 30 is inserted into the insertion port. The aerosol container with a shut-off valve according to claim 1, wherein the aerosol container is configured to be inserted between the other end of 88.   In the locking device 30, at least one insertion rod 34 projects from a wide handle 32, and when the insertion rod is fitted into the insertion port 68, the handle 32 remains outside the pressing head 60. The aerosol container with a closing valve according to claim 2, wherein the aerosol container is configured as described above. Furthermore, the shoulder cover 10 attached to the upper part of the aerosol container body 2 so as to surround the stem 6 is provided,
4. The fixing means 38 is formed by engaging strips 38a and 38b formed so as to be able to engage with each other on the shoulder cover 10 and the tubular mounting tool 42. An aerosol container with a closure valve according to claim 1. The aerosol container with a closing valve according to claim 4, wherein the locking member 30 is detachably assembled to a part of the shoulder cover 10.

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