DE19860969B4 - Metering valve for pressurized dispensing containers - Google Patents

Abstract

The liner (16) lining on at least a portion of the inner surface of the main component part (17) is made of material selected from fluoropolymer, ceramic, a metal or a glass, and the main component part is made of another material. The valve stem (1) is coaxially slidable within the valve member defining an annular metering chamber (13). The outer and inner seals (4,5) operate between the respective outer and inner ends of valve member (2) and the valve stem (1) to seal the annular metering chamber (13) between them. Preferred Features: The liner may be Stainless steel or aluminum, with at least a portion of its inner surface being coated with a layer of polytetrafluoroethylene. Alternately the liner is formed as a separate component insertable within the main one, or may be co-moulded with the main part. The thickness in the radial direction of the liner is less than or equal to 0.6mm, and is preferably 0.5mm. The thickness in the radial direction of the polytetrafluoroethylene layer is less than 30 microns.

Description

These The invention relates to metering valves for pressure-discharge containers according to the preamble of claim 1.

Conventional metering valves of this type, as for example, from the generic state of the art according to the DE 692 03 591 T2 include a valve stem which is coaxially displaceable within a valve member defining an annular metering chamber and outer and inner annular seals acting between the respective outer and inner ends of the valve stem and valve member to seal the metering chamber therebetween. The valve stem is hollow, whereby in a non-dispensing position of the valve stem, the metering chamber is connected to the container and is filled from this with a substance. The valve stem is movable against the action of a spring to a dispensing position in which the metering chamber is separated from the container and opened to the environment to allow the material to flow out.

One Problem with this metering valve type according to the prior art is especially in liquid Propellant with (suspended) held therein particulate matter in that the solid substance is on the inner surfaces of the dosing chamber and on others Components after a plurality of service cycles and / or after deposits or deposits a storage. This can be a degraded one operability lead the valve, as the deposit of the substance the amount of active to disposal available Ingredient decreased (due to the fact that the active Ingredient on the surfaces the chamber remains behind). For devices according to this The prior art has relied on the container and the valve attached to it is shaken before use, around the deposited particles as a result of the movement of the liquid propellant and the mixture of substances. While this remedy is within of the container body itself is effective, it is in terms of on the inner surfaces of the metering chamber deposited particles are not effective. Because the chamber is considerably smaller is, leads the limited fluid flow in the dosing chamber (caused by the turbulent flow in the chamber) to prevent the fluid in the dosing chamber with sufficient energy moves around the deposited particles sufficiently to remove.

From the DE 689 04 252 T2 , WO 97/16360 A1 of DE 195 04 502 A1 and the US 5,027,986 Dosing valves are known in each case, which are also subject to the above problem that can be deposited on the inner surface of the dosing of particles of the substance to be dispensed from the metering valve and thus the amount of available for dispensing active ingredient is reduced due to the deposition.

Out WO 96/32150 A1, it is also known, inner surfaces of a metering container with metering valve partially or completely with one or more To coat fluoropolymers, in particular to the deposition of particles in the dosing tank to reduce.

With the use of fluoropolymers, however, the problem associated that fluoropolymers tend to "swell" when they in such pressure delivery containers used propellants are exposed. This swelling can influence the dosing volume of the dosing chamber, as the internal and outside diameter of the valve element changes uncontrollably.

It It is therefore an object of the present invention to provide a metering valve to provide a deposit of the material and more active Ingredient components minimized on the walls of the dosing is and a change the metering volume of the metering chamber can be prevented.

According to the present The invention is a metering valve for use with a pressure-dispensing container, i. at a set under internal pressure Drop-off containers, provided with the features of claim 1.

Prefers the bushing is made of polytetrafluoroethylene.

Prefers is the socket as a separate, usable in the main component Component formed.

alternative the socket is made together with the main component, preferably by "co-shaping", such as Co-injection or the like.

Prefers the thickness of the bush in the radial direction is less than or equal to 0.6 mm.

In an embodiment is the thickness in the radial direction of the bushing is 0.5 mm.

Prefers is the thickness of the fluoropolymer layer in the radial direction is less than 30 μm.

Special embodiments The present invention will now be given by way of example only With reference to the accompanying drawings, in which:

1 a cross-sectional view of a metering valve according to the present invention;

2 a cross-sectional view of the metering chamber of the metering valve 1 is, which shows on the right and on the left side two alternative design options of the inner sleeve;

3 a cross-sectional view of another embodiment of the metering valve according to the present invention; and

4 a cross-sectional view of the metering chamber of the metering valve 3 is, which shows on the right and on the left side two alternative design options of the inner sleeve.

The dosing valve off 1 includes a valve stem 1 which is an annular metering chamber 13 limiting valve element 2 protrudes and in the valve element 2 is axially displaceable. The valve element 2 is inside a valve body 22 arranged, which in a pressure vessel (not shown) is arranged. The metering valve is held in place by means of a crimping ring crimped on the top of the container.

An outer seal 4 and an inner seal 5 each elastomeric material extending radially between the valve stem 1 and the valve element 2 , The outer seal 4 is radially between the valve element 2 and the valve stem 1 clamped to provide a tight sealing contact, the compression by the use of a seal, which on the valve stem 1 fitted with interference fit (Übermaßpassung), and / or by crimping (beading) of a stamping ring on the pressure vessel is achieved during assembly.

The "upper end" 7 of the valve stem 1 (ie, the end projecting from the valve) is a hollow tube attached to a flange 8th closed is. The flange 8th is in the dosing chamber 13 arranged. The valve stem 1 comprises an outflow opening 9 which is adjacent to the flange 8th radially through the side wall of the valve stem 1 extends. In a likewise hollow intermediate section 7a of the valve stem 1 a passage is formed which has a pair of spaced-apart radial openings 10 and 11 has, which are interconnected via the centrally disposed cavity.

One from a second flange 21 from downwardly extending spring 15 , which second flange 21 between the intermediate section 7a and a lower section 7b of the valve stem 1 is arranged and separates them, biases the valve stem 1 in a "non-dispensing position" in which the flange 8th in sealing contact with the outer seal 4 is held. The second flange 21 is outside the valve element 2 but within the valve body 22 arranged.

The dosing chamber 13 is from the environment by means of the outer seal 4 and from the pressure vessel (not shown) to which the valve is attached by means of the inner seal 5 sealed. In the in 1 shown representation of the valve connect the radial openings 10 and 11 together with the central cavity, the metering chamber 13 and the container so that in this state the dosing chamber 13 is filled with the substance to be dispensed.

After pushing in the upper end 7 of the valve stem 1 relative to the valve element 2 such that the valve stem 1 moved inward into the container, the radial opening 10 closed when passing through the inner seal 5 passes through, leaving the dosing chamber 13 isolated from the contents of the pressure vessel. After further movement of the valve stem 1 in the same direction, the discharge opening runs 9 through the outer seal 4 in a connection state with the metering chamber 13 , In this "dispensing" position, the substance in the dosing chamber 13 over the discharge opening 9 and the hollow top end 7 of the valve stem 1 emanate into the environment.

When the valve stem 1 is released, causes the bias of the return spring 15 in that the valve stem 1 returns to its original position, as a result, the metering chamber 13 is filled again in readiness for further dispensing operations.

conventional Valve elements are as a single molded part of a material, such as acetal, polyester or nylon formed, which for the Previously described deposition problems is prone to. It turned out in experiments that a deposit the active ingredient on the wall of a fluoropolymer, such as PTFE, made of a ceramic or a glass Dosing chamber compared to conventional valve element materials, such as acetal, polyester or nylon, significantly reduced is.

However, a problem associated with the use of fluoropolymers in metering chambers is the tendency of the fluoropolymers to "swell" if they contain the pressure in such pressure delivery tern used propellants are exposed. This swelling can affect the metering volume of the metering chamber, since the inner and outer diameter of the valve element changes uncontrollably. Thus, the delivered dose amount, ie the delivered dose volume, is also affected. This is a serious problem, especially in cases where the substance is a pharmaceutically active agent to be administered at specific doses.

In the present invention, the in 2 shown valve element 2 a main component 17 and an inner ring bush 16 which are coaxially and assembled or formed in mutual contact with each other. The main component 17 is made of a conventional material for such a component, such as acetal, polyester or nylon. In one embodiment, the inner sleeve 16 made of a fluoropolymer, such as polytetrafluoroethylene (PTFE), and clad the inner ring surface of the valve member 2 so that they are actually the wall of the dosing chamber 13 forms. Typical fluoropolymers of this type are TEFLON (RTM) PFA fluorocarbon resins manufactured by Du Pont, Inc. The inner liner 16 is "thin-walled" with a typical thickness in the radial direction of about 10% to 30% of the total radial thickness of the valve element 2 , In one embodiment, the thickness in the radial direction of the inner sleeve 16 about 0.5 mm, and the thickness of the main component 17 is about 1.5 mm.

The left and the right side off 2 show two alternative design options of the inner sleeve 16 , On the left side, the inner sleeve extends 16 axially along the length of the annular metering chamber 13 , On the right side, the inner sleeve extends 16 additionally still radial to a base 20 of the valve element 2 cover which adjacent the inner seal 5 lies. The one on the right side of 2 shown design option has the advantage that a deposit of the active ingredient on the basis 20 of the valve element 2 is minimized.

The problem associated with the use of fluoropolymers is overcome in the present invention by the use of PTFE or other fluoropolymers only on the bush 16 is limited. The thin-walled construction of the socket 16 causes the degree of swelling of the PTFE to be reduced to such an extent that a change in the metered volume is insignificant. Another advantage of using PTFE only in the socket 16 is that the volume of PTFE required to make a metering valve compared to a valve element 2 , which is made entirely of PTFE, is considerably reduced. This is advantageous because PTFE is expensive compared to conventional metering valve element materials such as acetal, polyester and nylon.

The fluoropolymer bush 16 can be made as a separate molding, which in the main component 17 of the metering valve 2 can be used. Alternatively, the main component 17 and the fluoropolymer bush 16 also be formed together as a single component, wherein the molding process comprises two steps. The first step involves molding the socket 16 PTFE, and the second step involves inserting the bushing 16 in a second mold and injecting the main component material, for example polyester, into the mold around the main component 17 form, which is the socket 16 surrounds ("co-forms").

Alternatively, the socket 16 made of PTFE on the main component 17 be applied as a coating by spraying, dipping or by any other suitable coating method.

Another embodiment of the present invention is in 3 and 4 shown. As in the embodiment described above, the valve element comprises 2 , as in 3 represented, a main component 17 and an inner ring bush 16 which are coaxially mounted or formed in mutual contact with each other. The main component 17 is made of a conventional material for such a component, for example acetal, polyester or nylon. In this embodiment, the inner sleeve 16 however, made of a metal such as aluminum or stainless steel, and the inner ring surface of the valve element is made 2 out, so they actually cover the wall of the dosing chamber 13 forms. An inner surface of the socket 16 is with a layer 18 coated such a fluoropolymer as described above. The inner bush 16 has a typical thickness in the radial direction of about 10% to 30% of the total radial thickness of the valve element 2 on. In one embodiment, the thickness in the radial direction of the inner sleeve 16 between 0.3 mm and 0.5 mm and the thickness of the main component 17 is 1.5 mm. The thickness of the PTFE layer 18 in the radial direction is very small, and is typically not more than 30 microns.

The left and right sides off 4 show two alternative design options of the inner sleeve 16 , On the left side, the inner sleeve extends 16 axially along the length of the annular metering chamber 13 , On the right side, the inner sleeve extends 16 additionally radial to a base 20 of the valve element 2 cover which adjacent the inner seal 5 lies. The layer 18 is on the inner surface of both the ra dialen as well as the axial sections of the socket 16 applied. The one on the right side of 4 The design option shown has the advantage that a deposit of active ingredient based on 20 of the valve element 2 is minimized.

The problem associated with the use of fluoropolymers is overcome in this embodiment by the fact that the use of PTFE or other fluoropolymers only on the thin layer 18 is limited. The thin design of the layer 18 causes the degree of swelling of the PTFE to be reduced to such an extent that a change in the dosing volume becomes insignificant. Another advantage of using PTFE exclusively in the layer 18 This is because the volume of PTFE required to make a metering valve is lower than that of a valve element 2 or a bush made entirely of PTFE, is considerably reduced. This is advantageous because PTFE is expensive compared to conventional metering valve element materials such as acetal, polyester and nylon.

The annular bush 16 is preferably formed as a separate component, which in the main component 17 of the metering valve 2 can be used. Preferably, the socket sits 16 in a "sliding seat", ie in transition fit, in the main component 17 such that the socket 16 stuck in the main body 17 is held. Alternatively, the main component 17 around the ring bush 16 be shaped around. The socket 16 is inserted into a mold and the main component material, for example polyester, is injected into the mold around the main component 17 to form, which is the socket 16 surrounds.

The PTFE layer 18 is applied to the inner surface of the annular bushing 16 applied by a suitable method, for example by spraying or dipping. The socket 16 can be before or after insertion into the main component 17 be coated.

The present invention has particular application to metering valves for use in conjunction with pharmaceuticals. While the invention has been described with respect to PTFE and with respect to a particular type of valve element, it is apparent that the bushing 16 can be made of any fluoropolymer and used / used in other types of valve elements without departing from the scope of the present invention.

In summary, the present invention provides a metering valve for use with a pressure delivery container. The valve includes a valve stem 1 coaxial with one another in an annular metering chamber 13 limiting valve element 2 is displaceable. Outer and inner ring seals 4 . 5 are between the respective outer and inner end of the valve element 2 and the valve stem 1 effective to the annular dosing chamber 13 seal in between. The valve element 2 further comprises a main component 17 and at least a part of the inner surface of the main member 17 lining bush 16 , The socket 16 is made of a fluoropolymer and the main component 17 is made of a different material.

Claims (7)

A metering valve for use with a pressure delivery container, the valve comprising: a valve body ( 22 ), a valve stem ( 1 ) which is coaxial in an annular metering chamber ( 13 ) limiting and in the valve body ( 22 ) arranged valve element ( 2 ) is displaceable, one between the valve body ( 22 ) and the valve stem ( 1 ) acting spring ( 15 and an inner ring seal close to the pressure-discharge container, outer and near the pressure-discharge container ( 4 . 5 ), which between the respective outer and inner end of the valve element ( 2 ) and the valve stem ( 1 ) are effective to the annular dosing ( 13 ) between, characterized in that the valve element ( 2 ) a main component ( 17 ) and a socket ( 16 ) comprising at least a portion of an inner surface of the main component ( 17 ), the bushing ( 16 ) is made of either a fluoropolymer or made of a material selected from the materials stainless steel or aluminum, in which case at least a portion of an inner surface of the sleeve ( 16 ) a coating ( 18 ) of a fluoropolymer, and wherein the main component ( 17 ) is made of a different material. Dosing valve according to claim 1, characterized in that the bushing ( 16 ) is made of polytetrafluoroethylene. Dosing valve according to one of the preceding claims, characterized in that the bushing ( 16 ) as a separate part of the main component ( 17 ) usable component is formed. Dosing valve according to claim 1 or 2, characterized in that the bushing ( 16 ) as a common molding with the main component ( 17 ) is trained. Dosing valve according to one of the preceding claims, characterized in that the thickness of the bushing ( 16 ) is less than or equal to 0.6 mm in the radial direction. Dosing valve according to one of the preceding claims, characterized in that the thickness in the radial direction of the bushing ( 16 ) Is 0.5 mm. Dosing valve according to claim 1, characterized in that the thickness in the radial direction of the fluoropolymer layer ( 18 ) is less than 30 microns.