The invention concerns a stem of a valve for a container for dispensing a pressurized fluid, said stem having an inner channel inside a cylindrical housing connecting the at least one lateral inlet opening at its lower end and an outlet opening at its upper end.
Hollow stems are usually used in valves for containers to dispense a pressurized fluid. The stem is providing in a passage for a pressurized fluid which is part of a valve and mounted onto a container. The stem is displaceable between a closed position and an open position. In the open position, the pressurized fluid inside the container can be released through the lateral inlet opening at the lower end of the stem passing through the inner channel of the stem and being released through the outlet ending of the stem. The valve can provide spring means for pushing the stem in its closed position, in which the container is sealed and the passageway through the stem is blocked. The stem of the valve is exposed to bending and tensile force which can lead to material failure of the stem.
It is known in the prior art to reinforce stems with fibers, e.g. glass fibers, basalt fibers or wollastonite fibers. However, the reinforcing fibers are expensive and increase significantly the production costs of the stem. Furthermore, due to the presence of fibers the production tools and molds wear out faster than without reinforcement fibers which also leads to increased production costs. EP 2 354 037 A1, EP 2 481 688 A1 and BE 1 021 068 B1 describe stems for a valve for dispensing pressurized fluids with a conical shape at its lower end.
It is therefore an object of the present invention to provide an optimized stem.
This object is achieved according to the invention by a stem in which the inner channel has a parabolic shape at its lower end.
The main advantages of these measures are the following. The parabolic shape of the inner channel of the hollow stem confers a higher rigidity to the stem. The bending and mainly the tensile/compression forces which act on the stem while the using the valve or due to unintentional force on the exposed stem are better distributed and can be introduced in the cylindrical housing of the stem by the parabolic shape of the lower end of the inner channel. As an example, for opening the valve the stem must be pushed in direction of the container and thus against the effect of pressure in the container in order to displace the stem from its closed position into its open position. The pressurized fluid exerts a force on the bottom end of the stem which is then introduced into the cylindrical housing of the stem. The higher rigidity of the stem due to the parabolic shape of the inner channel allows to reduce the amount of material to produce the stem which also reduces the production costs of the stem.
As an advantage, the parabolic shape smoothens out hard edges which are usually found in hollow stems at their lower end. These edges form a weak point, stress concentrations of the stem and can therefore lead to material failure when the stem is exposed to bending and tensile force.
As an additional advantage, the parabolic shape of the lower end of the inner channel can optimize the fiber direction of filled materials. In this way forces acting on the stem can be better distributed and introduced in the cylindrical housing of the stem. Especially for dispensing high pressure fluids the optimized fiber directions improve the rigidity of the stem.
According to a further preferred embodiment, the cylindrical housing broadens toward the lower end of the stem.
The diameter of the cylindrical housing and its thickness is increased towards the lower end of the stem. As a result, the stem is mainly more resilient to bending forces acting on the stem but also improves the tensile/compression resistance of the stem. The potential mechanical weak point of the connection between the flange and the cylindrical housing is reinforced. The stability of the lower section of the stem with the lateral inlet openings is improved by the increased diameter of the cylindrical housing surrounding the lateral inlet openings.
Especially the combination of the parabolic shape of the inner channel and the increased outer diameter of the cylindrical housing of the lower end of the stem increases the stability of the stem. The parabolic shape of the inner channel makes the stem mainly more resilient against tensile/compression forces while the increased outer diameter of the cylindrical housing contributes mainly to the resilience against bending forces. Both structural improvements reinforce the potential weak point of the stem at its lower end.
According to a preferred embodiment of the invention the stem is provided on its lower end with a flange.
The flange can abut in the closed position of the stem against the housing of the valve thereby closing the passageway through the stem. This is a very reliable solution for closing the passageway. The pressurized fluid exerts force on the flange when the stem is pushed into its open position. As an advantage, the parabolic shape of the inner channel reinforces the stem.
Furthermore, according to the present invention, a top sealing part is provided around the outlet opening of the stem.
This top sealing part is the interface between the stem and an actuator or adapter which may be placed on the valve. The top sealing part can also provide means for limiting the opening distance of the valve. These means make sure that the valve is not opened beyond a maximum opening distance. The means can be a contact surface which abuts against the housing of the valve.
The valve according to the present invention can be used for dispensing foam, preferably one or two component polyurethane foam.
In the following, the invention is discussed more in detail with reference to preferred embodiments shown in the drawings in which
The
The stem 1 comprises of a cylindrical housing 4 with an inner channel 7 as a passageway of the pressurized fluid. The inner channel 7 connects the lateral inlet openings 2 at the lower end of the stem 1 with an outlet opening 3 at the upper end of the stem 1. To reinforce the stem 1, the inner channel 4 has a parabolic shape at its lower end. The parabolic shape of the inner channel 4 of the hollow stem 1 confers a higher rigidity to the stem 1 and increases the resilience of the stem 1 tensile/compression forces and also but to a lesser extent the bending force.
The diameter of the cylindrical housing 4 is increased towards the lower end of the stem 1 and in particular in the section which corresponds to the section with the lateral inlet openings 2. As a result, the stem 1 is more resilient to bending forces acting on the stem 1. The stability of the lower section of the stem 1 with the lateral inlet openings 2 is improved by the increased diameter of the cylindrical housing 4.
The flange 6 abuts in the closed position of the stem 1 against the housing of the valve thereby closing the passageway through the inner channel 7 of the stem 1.
The stem 1 provides a top sealing part 5 around the outlet opening 3. This top sealing part 5 is the interface between the stem 1 and an actuator or adapter which may be placed on the valve. The top sealing part 5 has a contact surface 9 for limiting the opening distance of the valve. The contact surface 9 abuts the housing of the valve and inhibits an opening of the valve beyond a maximum opening distance.
Number | Date | Country | Kind |
---|---|---|---|
BE2020/5344 | May 2020 | BE | national |
This application is the National Stage of PCT/EP2021/062375 filed on May 10, 2021, which claims priority under 35 U.S.C. § 119 of Belgium Application No. BE2020/5344 filed on May 15, 2020, the disclosure of which is incorporated by reference. The international application under PCT article 21(2) was published in English.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2021/062375 | 5/10/2021 | WO |