JP2548665Y2 - Gas filling valve mechanism in aerosol injection device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial application field) This invention relates to a gas filling valve mechanism in an aerosol type injection device, in which a stem rubber is sandwiched between an upper end of a valve housing and a top plate of a mountain cap. When the pressure is interposed and the stem rubber is compressed downward by the filling gas pressure to form a filling passage between the stem rubber and the top plate, the filling passage is formed to be large by the pressure of the filling gas. This is extremely effective for increasing the gas filling speed and improving the filling efficiency.

(Prior Art) A stem rubber is interposed between a top end of a valve housing of a container and a zenith plate of a mountain cap, and the stem rubber is compressed downward by a filling gas pressure so that the stem rubber and the zenith plate are connected to each other. FIG. 4 shows an example in which a filling passage is formed between the above-mentioned structures (Japanese Patent Publication No. 59-33428). When the injection rubber 24 is pushed down by the stem rubber 13 being pressed between the upper end of the valve housing 15 and the zenith plate 3 of the mountain cap 1, the valve stem 5
Lowers against the valve housing 15 against the spring 60,
The inner peripheral portion of the stem rubber 13 is pushed down and deformed. Then, due to the deformation of the inner peripheral portion of the stem rubber 13, the inlet of the injection fluid of the valve stem 5 is opened, and the gas in the cylinder is ejected from the nozzle of the injection cylinder 24 through the outflow passage 7. When filling the gas, the filling nozzle is pressed against the top plate 3 with the injection tube 24 removed, and the filling gas flows from between the valve stem 5 and the opening 4 of the top plate 3, and the pressure of the filling gas flows through the stem rubber 13. Is compressed to separate the stem rubber 13 from the zenith plate 3 to form a filling passage between the stem rubber 13 and the zenith plate 3 to form a valve housing 15.
It flows into the cylinder via the vertical high-speed filling groove 18 between the standing pieces 17 on the outer periphery of the cylinder.

By the way, when filling the gas, the top plate 3 is pressed by the filling nozzle and bent downward, and the stem rubber 13 is broken between the top plate 3 and the valve housing 15. As described above, since the portion interposed between the zenith plate 3 and the valve housing 15 is crushed, the amount of compression of this portion due to the pressure of the filling gas is small.
Since the filling passage formed between 13 and the top plate 3 is small, the gas inflow resistance is large at this portion. Therefore, the filling speed cannot be increased.

(Issues to be solved by the present invention) In the present invention, the collapse of the stem rubber 13 due to the pressing force of the filling nozzle is minimized so that the large filling flow path is formed between the stem rubber 13 and the top plate 3. Valve housing with mountain cap to make it smaller
15 support structures have been devised.

(Means for solving the problem) The solution of the present invention is as follows.

This is a gas filling mechanism in the gas filling valve mechanism in the aerosol type injection device. The stem rubber is interposed between the upper end of the cylindrical valve housing and the top plate of the mountain cap, and the stem rubber is interposed by the filling gas pressure. To form a filling passage between the stem rubber and the top plate, and into the container via a vertical filling valve between standing pieces protruding radially on the upper outer periphery of the valve housing. In the gas filling valve mechanism in the aerosol type injection device to be flowed in, the upstanding piece protruding from the upper outer periphery of the valve housing is protruded above the upper end of the valve housing, and the upper end is formed into a semicircular arc surface, and An upwardly projecting semicircular annular space portion is provided on the outer periphery of the top plate of the cap, and the semicircular upper end of the standing piece is fitted into the semicircular annular space portion. That is, the zenith plate was directly supported by the standing pieces.

(Operation) When the filling nozzle is pressed toward the zenith plate, the pressing force is supported by the upstanding pieces protruding from the outer periphery of the valve housing. Therefore, the downward bending of the zenith plate due to this pressing force is small. Even between the upper end of the valve housing and the zenith plate of the stem rubber due to the downward bending of the plate, the gas pressure is greatly compressed by the gas pressure, and the flow path resistance of the flow path is formed between the upper end of the valve housing and the zenith plate. Is reduced and the filling speed is accelerated.

(Embodiment) The space of the cylindrical projecting portion 2 provided at the center position of the mountain cap 1 is used as the housing portion of the injection valve structure, and the central portion of the zenith plate 3 of the cylindrical projecting portion 2 is opened. An upwardly projecting semicircular annular space portion is provided on the outer peripheral portion of the plate 3, and the semicircular upper end of the erecting piece is fitted into the semicircular annular space portion to erect the zenith plate 3. The upright piece 17 is directly supported by the piece 17 and the valve housing 15
The upper end of the mountain cap 1 has a semicircular arc surface, the opening 4 in the central portion of the zenith plate 3 of the mountain cap 1 is opened upward, and the opening 4 is provided with a valve stem. 5, an injection fluid flow channel cylinder 6 is inserted into the upper structure of the injection fluid 5, and an upper end opening of the injection fluid flow channel cylinder 6 is defined as an outlet 7, and the injection cylinder is inserted into the outlet 7 from above. The injection head 24 is fitted so as to connect the inflow port 8 of the injection fluid 24 to the mass portion 9 serving as a lower structure of the valve stem 5.
The lower surface portion is formed into a hemispherical surface structure 10, an inflow port 11 of the flow path of the jet fluid is provided at an upper position of the massive portion 9, and an annular groove 12 is formed at the inflow port 11 portion, Attach the through hole at the center of the stem rubber 13 at the position of the annular groove 12,
Normally, the inlet 11 of the flow path of the ejection fluid is
When the valve stem 5 is pressed down on the central portion of the top plate 3 of the cylindrical projecting portion 2 with reference to the opening portion 4, the inlet 11 of the flow path of the jet fluid is closed. The stem rubber 13 moves and opens to open the fluid flow path, and when the valve stem 5 rises,
The upper portion of the stem rubber 13 is brought into contact with the back surface portion, that is, the inner surface portion of the top plate 3 of the cylindrical projecting portion 2 of the mountain cap 1, and the valve stem 5
A plurality of elastic protruding elongate plate-like members 14 that support the portion of the hemispherical surface structure 10 forming the lower surface of the massive portion 9 serving as the lower structure are always pushed upward from the lower bottom thereof. The upright valve housing 15 is inserted into the space inside the cylindrical protruding portion 2, and the upper end portion of the large-diameter cylindrical portion 16 of the valve housing 15 is spaced upward at a desired interval along the circumferential direction. A large number of standing pieces 17 projecting from each other are formed, and an inclined part is formed from the outer lower side to the inner upper side in the groove-shaped part provided between the adjacent parts of the standing pieces 17, and the part is formed at high speed A filling groove 18 is formed at an upper end position of the cylindrical portion of the cylindrical projecting portion 2 and at a peripheral portion of the top plate portion 3 of the cylindrical projecting portion 2 to form a space portion 19 having an annular semicircular cross section upward. And the valve housing is An upper end opening of an elongated tube 22 is fitted from below into a short cylindrical portion 21 protruding downward from a lower bottom portion of the valve housing 15, and a downward nozzle of a through hole 23 provided in the lower bottom portion of the valve housing 15. A gas filling valve mechanism in the aerosol-type injection device, wherein an upper end opening of the elongated tube 22 is fitted between an outer surface of the protruding hole and an inner surface of the short cylindrical portion 21.

(Effect) The effect of the gas filling valve mechanism in the aerosol type injection device will be described.
A valve housing is provided on the back or inner surface of the top plate 3
15 so that the upper end of the
The upper end portion of the mountain cap 1 is formed so as to be in contact with the valve and is normally closed, and the valve is opened when used, so that gas can be charged from the opening of the mountain cap 1. There is. In addition, a plurality of elastic protruding elongated plate-like members 14 which support the portion of the hemispherical surface structure 10 forming the lower surface of the massive portion 9 serving as the lower structure of the valve stem 5 so as to be constantly pushed upward are provided below the portion. A valve housing 15 erected upward from the bottom is inserted into a space inside the cylindrical protruding portion 2, and an upper end portion of a large-diameter cylindrical portion 16 of the valve housing 15 has a circumference. A large number of standing pieces 17 projecting upward at desired intervals along the direction are provided, and a groove-shaped portion provided between adjacent portions of the standing pieces 17 is formed from the lower part outside to the inner part upward. Since the inclined portion is formed and the portion is formed as the high-speed filling groove 18, there is an effect that the filling gas can be filled at a high speed through the high-speed filling groove 18. Further, at the upper end position of the cylindrical portion of the cylindrical projecting portion 2 and at the peripheral portion of the zenith plate portion 3 of the cylindrical projecting portion 2, a space portion 19 having an annular semi-circular cross section is formed upward. The upper end opening of the elongated tube 22 is inserted from below into the short cylindrical portion 21 protruding downward from the lower bottom portion of the valve housing 15 in the lower space portion,
There is an effect that the gas in the container can easily flow into the valve housing 15. Further, the upper end opening of the elongated tube 22 is fitted between the outer surface of the downwardly protruding nozzle-like projection hole 23 provided in the lower bottom of the valve housing 15 and the inner surface of the short cylindrical portion 21. Therefore, there is an effect that it can be easily fitted even in a place where the fitting is difficult. Further, when the filling nozzle is pressed toward the top plate, the pressing force is supported by the standing pieces protruding from the outer periphery of the valve housing. Therefore, the downward bending of the top plate due to this pressing force is small. Also, between the upper end of the valve housing and the zenith plate of the stem rubber due to downward bending, the gas pressure is greatly compressed, and between the upper end of the valve housing and the zenith plate, the flow resistance of the flow path is It has the effect that it is reduced and its filling speed can be accelerated.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a gas filling valve mechanism in the aerosol type injection device to which the present invention is applied, and FIG. 2 is an enlarged view of a high-speed filling groove of a valve housing which is a main part of FIG. FIG. 3 is a top view of a valve housing which is a main part of FIG. FIG. 4 shows a drawing described in Japanese Patent Publication No. 59-33428, which is a prior art cited example.

 ──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-51-99315 (JP, A) JP-A 1-109692 (JP, U) JP-A 51-23708 (JP, U) JP-A Sho 61- 22563 (JP, U) JP-A 1-122859 (JP, U) JP-A-59-99979 (JP, U) JP-B-59-33428 (JP, B2)

Claims (1)

(57) [Scope of request for utility model registration] A stem rubber is interposed between an upper end of a cylindrical valve housing and a zenith plate of a mountain cap, and the stem rubber is compressed downward by a filling gas pressure so as to compress the stem rubber and the zenith plate. A gas filling valve mechanism in an aerosol type injection device in which a filling passage is formed between the valve housing and a vertical filling valve between standing pieces protruding in a radial direction on an upper outer periphery of a valve housing to flow into a container. An upstanding piece protruding from the upper outer periphery of the valve housing is protruded above the upper end of the valve housing, and the upper end thereof is formed into a semicircular arc surface. The aerosol type in which a circular annular space portion is provided, and the semicircular upper end of the standing piece is fitted into the semicircular annular space portion and the zenith plate is directly supported by the standing piece. Gas filling valve mechanism in the injection device.