NO174843B - Valve that can be connected to an outlet on a container - Google Patents

Abstract

Valve device comprising an elongate valve body (14) and an elastomeric sleeve (28) covering the side of the valve body and attached thereto at both ends. An inlet channel (20) projects into the valve body from one end, for supplying fluid from a container, e.g. a flexible container. An outlet channel (26) projects at the opposite end of the valve body, for discharge of fluid. At least one side channel (22) projects from the inlet channel (20), to the outside of the valve body (14), so that fluid can tighten out between the valve body and the sleeve (28) and expand the sleeve. The fluid can also flow through at least one other side channel (24) which projects into the outlet channel (26). so that the fluid can flow out through it. The casing (28) prevents fluid from flowing back from the outlet passage (26). to the container.

Description

The present invention relates to a valve that can be connected to an outlet on a container to release fluid from the container when the fluid inside the container is subjected to pressure, the valve comprising an elongated, cylindrical valve body that has an inlet end with an inlet channel that can receive a current of fluid from the container outlet and lead the fluid to the outside of the valve body through at least one outlet opening, an elastic sheath of e.g. rubber surrounds the outside of the valve body and protrudes over the outlet opening or openings and forms a closure for this or these when the fluid is not under pressure, the sleeve before being placed around the valve body has an inner diameter that is smaller than the diameter of the outside of the valve body, so that the sleeve is under tension and lies tightly around the valve body when the fluid is not under pressure, but can open for the fluid by deforming elastically, so that a flow through the inlet channel and through the outlet opening or openings enters between the outside of the valve body and the casing.

Such a valve is known from US-PS 2715980. The valve body in the known valve only comprises an inlet channel in the form of a central opening, i.e. no outlet channel, as branch openings project from the central opening to the outside of the valve body. An outlet for the fluid is formed by the elastic casing expanding, so that the fluid is released through a gap between the valve body and the casing. When a fluid is to be released, it flows through the central opening and then through the branch openings and causes the sleeve to expand and enables the fluid to flow out through one end of the sleeve. During such flow, it is possible for contaminants to flow into the expanded end of the sleeve and then through the branch openings and the central opening, back into the container. An effective closure cannot be achieved for a flow of contaminants into the container.

US-PS 3739952 shows an elastic sleeve which surrounds a valve body and which expands to admit a fluid between the sleeve and the valve body, which has only one outlet channel (shown in Fig. 3 of the document), i.e. no inlet channel.

In both cases, the casing is thus opened towards the surroundings (in US 3739952, admittedly towards the cavity in the rest of the casing).

Another known valve comprises an elastic tube or sleeve, and is described in US-PS 4346704. A solution for parenteral administration is discharged through a central tube or channel, to branch openings which discharge the fluid to the inside of an elastic sleeve or tube . When the fluid is under pressure, it forces the elastic tube outwards and enables flow from the branch openings and outwards from the end of the sleeve. The device is primarily intended for single use, e.g. for release of an anesthetic agent. There is no particular problem with any return flow of contaminants into a container during such single use. The device is designed to deliver anesthetics with a large flow rate per unit of time and low pressures, so that accurate dosing is possible.

When discharging sterile fluids from a container when the container can be used for a longer period of time, it is essential to prevent any backflow of contamination into the container during and after the discharge operation has been carried out. Contamination in the form of materials originating from the outside of a valve and the container may contain micro-organisms, atmospheric gases, moisture, dust etc. If the sterile fluid is contaminated, this can affect the quality, effectiveness and even safety of the product.

The main purpose of the present invention is to arrive at a valve for a container which enables easy discharge of the fluid, while preventing any backflow of contaminants through the valve and into the container containing the remaining fluid.

The valve according to the present invention is characterized by the fact that the valve body comprises an outlet channel at an axial distance from the inlet channel, with at least one inlet opening on the outside of the valve body, within the housing, so that the fluid can flow from the outlet opening or openings for the inlet channel and to the inlet opening or openings for the outlet channel and out of the valve body, the sleeve being sealingly attached to the valve body upstream of the outlet opening or openings and downstream of the inlet opening or openings in relation to the direction of flow through the valve body, so that fluid entering between the outside of the valve body and casing through the inlet channel can only flow out through the outlet channel.

According to the present invention, there is in the valve body both an inlet channel and an outlet channel, and both of these channels have their openings within a permanently closed part of the casing, the ends of the casing being prevented from opening elastically. Fluid that enters between the valve body and the housing through the inlet channel is therefore forced to flow out through the outlet channel. When the valve is not in use, the elastic sleeve lies tightly against the outside of the valve body and blocks any flow through the outlet channel and back into the container. When the container is supplied with pressure that drives the fluid into the inlet channel, the fluid flows from the inlet channel into the openings and outwards towards the elastic sleeve. The pressure in the fluid expands the elastic sleeve radially outwards and enables flow between the outside of the valve body and the sleeve, to the openings which are in connection with the outlet channel. The pressure in the fluid and the reaction in the elastic sleeve drive the fluid out through the outlet channel. When the fluid flows into the openings connected to the outlet channel, the elastic sleeve assumes its original shape, and lies tightly against the valve body and blocks any flow from the openings connected to the outlet channel into the space between the valve body and the sleeve. Consequently, backflow into the container is prevented, and it is ensured that contaminants do not enter the container and affect the quality, effectiveness or sterility of the fluid.

At the end of the inlet channel inside the valve body, i.e. at a distance from the end which receives the fluid from the container, one or more openings are arranged which project obliquely in relation to the longitudinal direction of the valve body, radially outwards to the outside of the body. While a single opening can be used, it is preferred to arrange openings with a distance in the circumferential direction, for even distribution of the fluid outwards to the inside of the elastic sleeve, for expansion of the sleeve.

At a distance in the longitudinal direction of the valve body from the openings that bring the fluid to the inside of the elastic sleeve, further openings are arranged, to bring the fluid inward to an outlet channel that projects in the longitudinal direction of the valve body and opens out through the outlet end of the body, furthest from the container .

In view of the manufacture of the valve body and efficient flow of the fluid through the valve body, it is preferred to design the channels and openings with a generally rounded cross-section, e.g. circular or oval cross-section.

Depending on the elastic properties of the sleeve and the pressure in the fluid released by flowing through the valve body, a rigid element of cylindrical tube shape can be placed around the elastic sleeve to limit its expansion from the outside of the valve body.

The valve can be used together with many different vessels or containers. Preferably, a compressible, flexible container in the form of a plastic bag, an accordion-folded plastic container, a container of the chimney fan type or the like is used.

The valve device can be used for the discharge of materials with different consistencies, including liquids, creams, gels, powders, gases etc., such as foodstuffs, pharmaceuticals, cosmetics, industrial chemicals, photographic solutions, adhesives, paints and others.

Because both ends of the housing are sealed to the valve body, the flow of fluid between the outside of the body and the inside of the housing can only flow through the outlet openings and the outlet channel. Consequently, no fluid is lost during the discharge operation. Moreover, the elastic nature of the casing ensures that it forms a barrier over the mouths of the openings which are directed towards the inside of the casing, so that contaminants cannot flow back through the openings which are connected to the inlet channel and the outlet channel.

Many different materials can be used in the valve body and the elastic sleeve, the materials being chosen so that they are compatible with the fluid to be released and with any sterilization method used for the fluid. If thermal sterilization is used, the selected material must maintain its condition throughout the temperature range for sterilization and during the time period required for sterilization. Sterilization can be achieved in other ways, such as by irradiation, use of ethylene oxide etc.

As the valve according to the invention prevents any flow of contaminants into the container, there is no need to use preservatives, which can be expensive and affect the effect of the product or which have potential, harmful side effects.

During the development of the present invention, it has been found that contaminants, such as microorganisms, which enter a container within a short time can develop by strong growth. Experiments have been made with the invention, and it has been found that the valve prevents any flow of such contamination into the container, so that the discharged fluid can be stored for a long time after it has first been discharged, without harmful effects due to contaminants which has entered the container.

In an exemplary embodiment, the compressible container is formed of polyolefin, while the valve body is made of Teflon and has an outer diameter of 12.7 mm, while the elastic sleeve is made of synthetic rubber with a Shore hardness of 50, inner diameter of 9.5 mm and outer diameter of 10.3 mm. A rigid sleeve is arranged around the elastic sleeve, and has an inner diameter of 13.5 mm. When the elastic sleeve is placed on the valve body it is stretched to ensure that it maintains the necessary tight contact with the outside of the body to block the flow of contaminants when the valve is not in use. It is also possible to make the elastic sheath from natural rubber and gutta-percha.

For a better understanding of the invention, its advantages and what is particularly achieved by the use of the invention, reference is made to the attached drawings, which show preferred embodiments of the invention. Fig. 1 shows, seen in elevation, a valve according to the invention, mounted on a bellows-like, flexible container, Fig. 2 shows a longitudinal section through an embodiment of

the valve shown in fig. 1,

Fig. 3a shows a cross-section along the line 3a-3a in fig. 2, Fig. 3b shows a cross-section along the line 3b-3b in fig. 2, Fig. 3c shows a cross-section along the line 3c-3c in Fig. 2, Fig. 3d shows a cross-section along the line 3d-3d in Fig. 2, Fig. 4 shows in a corresponding section as fig. 2 a stiff, tubular sleeve which is arranged around the valve, Fig. 5 shows a longitudinal section through another embodiment of the invention, Fig. 6 shows a cross section along the line 6-6 in fig. 5, • Fig. 7 shows in a similar way as fig. 5 a further

execution of the invention,

Fig. 8 shows a cross-section along the line 8-8 in fig. 7, Fig. 9a shows in elevation a valve according to the invention mounted on a flexible container of the chimney fan type, Fig. 9b shows in elevation the arrangement shown in fig. 9a

turned 90°.

In fig. 1, a bellows-like flexible container 10 is shown, with a valve 12 mounted on one end of the container. The valve 12 is constructed in such a way that fluid inside the container 10 can be released when the container is compressed.

In fig. 2 shows an embodiment of the valve 12, comprising a valve body 14 which is elongated in the direction that runs between an inlet end 16 and an outlet end 18. When the valve body 14 is placed on a container, the inlet end 16 is in communication with the inside of the container.

An inlet channel 20 projects from the inlet end 16 along part of the length of the valve body 14. As shown in fig. 2, the inlet channel protrudes approximately one-third of its length. The opposite end of the inlet channel 20 in relation to the inlet end branches into four separate openings 22, which are angularly evenly distributed and extend to the outside 14a of the valve body 14. Closer to the outlet end 18 of the valve body are openings 24, which project inwards from the outside 14a and are angularly even distributed, and ends at the inner end of an outlet channel 26. The outlet channel 26 is axially aligned with the inlet channel 20, and the two channels are at a distance from each other in the longitudinal direction of the valve body.

An elastic sleeve 28 surrounds the outside 14a, and is normally in close contact with the outside. As shown in fig. 2, the elastic sleeve projects from near the inlet end 16 to near the outlet end 18 of the valve body. At each of the ends, spaced in the longitudinal direction of the valve body, the sleeve 28 is in sealing contact with the outside 14a of the valve body. As shown in fig. 3a, 3b and 3d, the sleeve 28 is stretched when it is placed on the valve body, so that it lies tightly around the valve body and forms a closure for the mouth of the openings 22, 24 which project through the outside of the valve body 14. The sleeve is attached to the outside of the valve body 14 by means of 0-ring-like elements 30 which are placed in recesses 32 on the outside of the valve body. The means used to seal the ends of the casing can vary depending on the type of materials used and the properties of the fluid to be released. In addition to or instead of the O-ring elements 30, the sleeve can be attached by means of thermal or chemical attachment operations or by the use of adhesives.

If the container 10 in fig. 1 is pressed together in the longitudinal direction, the contents will flow out through the valve 12, and first pass through the inlet channel 20 and into the valve body 14. When the fluid flows out of the inlet channel 20, it passes into one of the four openings 22 and generally flows radially outward to the outside 14a of the valve body. The pressure in the fluid causes the elastic sleeve 28 to expand outwards, so that the fluid flows between the outside 14a of the valve body and the inside of the elastic sleeve, until it reaches the second set of openings 24 to flow radially inward. Fluid from the openings 24 flows into the inner end of the outlet channel 26 and then passes through the outlet channel to flow out of the valve.

When the fluid does not flow through the valve 12, the elastic sleeve 28 forms a barrier or a closure for each of the openings 22, 24 on the outside of the valve body 14. This means that contaminants cannot flow through the valve and back into the container. When the fluid causes the sleeve 28 to expand, the flow of fluid will prevent contaminants from entering the container. When the fluid reaches the openings 24, the elastic sleeve will contract and block the openings 24 on the outside 14a of the valve body 14, so that backflow into the container through the outlet channel 26 is prevented.

In fig. 4, the valve is of the same construction as in fig. 2, but an elongated, rigid, tubular sleeve 34 is located around and somewhat outside the elastic sleeve 28. The tubular sleeve 34 forms a restriction for the movement of the sleeve 28 radially outwards. If there is a tendency for the sleeve to expand in an uncontrolled manner, the tubular sleeve 34 limits the outward movement. The tubular sleeve 34 is only needed under special circumstances, and is not a necessary element in the valve.

In fig. 5 and 6 show another embodiment of the invention. The valve 112 has a valve body 114, with an inlet end 116 and an outlet end 118. The valve body 114 is elongated in the direction between the inlet and the outlet.

The valve body has an inlet channel 120 which projects from the inlet end 116 for approximately a quarter of the length between the ends of the valve body. In contrast to the design shown in fig. 2, 3 and 4, a single opening 122 projects from the end of the inlet channel 120 which is spaced inwards from the inlet end 116, to the outside 114a of the valve body. On the diametrically opposite side of the valve body, another opening 124 projects radially inwards from the outside to the inner end of the outlet channel 126. The mouths of the openings 122, 124 in the outside of the valve body are longitudinally spaced apart. This special arrangement prevents any flow channel from being formed between the elastic sleeve 128 and the outside 114a of the valve body 114. Consequently, the flow coming out of the opening 122 will flow around the valve body between the outside 114a and the inside of the sleeve 128 to the inlet of the opening 124.

As can be seen from fig. 5, the ends of the elastic sleeve 128 are sealingly attached to the outside 114a of the valve body 114 by means of O-rings 130.

In fig. 6, the opening 122 is shown somewhere between the inlet end and the outlet end. In addition, the elastic sleeve 128 lies close to the outside 114a of the valve body 114, and forms closures for the openings 122, 124. The valve 112 generally works in the same way as the valve 12, in that the elastic sleeve 128 expands outwards only when fluid is driven from a container and into the inlet channel 120 to flow through and around the valve body to the outlet channel 126.

In fig. 7 and 8 show a further embodiment of the valve. This embodiment is a valve 212 which comprises an elongated valve body 214. The valve body protrudes in its longitudinal direction between an inlet end 216 and an outlet end 218. Unlike the embodiment in fig. 5 and 6, the valve 212 has two openings 222 which branch outward from the downstream end to an inlet channel 220. The openings 222 are located at 180° angular distance, and each project to the outside 214a of the valve body. At a distance from the openings 222 along the outside 214a is another pair of openings 224 which project inwardly from the outside and terminate at the inner or upstream end of an outlet channel 226. While the openings 222 and 224 in fig. 7 may appear to be in the same plane, in reality the openings 224 are at 90° angular distance from the openings 222, in order to achieve the same effect as for the embodiment in fig. 5 and 6, i.e. to prevent the formation of a channel for the fluid flowing through the valve.

An elastic sleeve 228 surrounds the outside of the valve body from a location near the inlet end 216 to a location near the outlet end 218 so that the sleeve covers the mouths of the openings 222, 224 in the outside of the valve body. As in the other designs, the ends of the elastic sleeve 228 are sealingly attached to the outside of the valve body 214 by means of O-rings 230. The O-rings are placed in recesses 232. As previously mentioned, it is also possible to use other means for sealing and securing the ends of the sleeve so that the fluid discharged through the valve does not flow outside the openings 224 projecting to the outlet channel 226.

As can be seen from fig. 8, the openings are located diametrically opposite each other. The other openings 224 are at a 90° angular distance from the openings shown.

In fig. 9a and 9b another container 310 is shown, with a valve 312 projecting from the top of the container across its vertical direction. The container resembles a chimney fan, see fig. 9a, so that when the sides are pressed against each other, the fluid is driven out through the valve 312.

While the containers 10 and 310 are both flexible containers, it is possible to use a container arrangement which is not of a flexible construction, but of a compressible construction, one part of the container being telescopically movable into another part to drive the fluid out. It will be understood that many different container constructions can be used together with a valve according to the invention.

Claims (8)

1. Valve which can be connected to an outlet on a container to release fluid from the container when the fluid inside the container is subjected to pressure, the valve comprising an elongated, cylindrical valve body (14; 114; 214) which has an inlet end with an inlet channel (20; 12 0; 220) which can receive a flow of fluid from the container outlet and lead the fluid to the outside of the valve body through at least one outlet opening (22; 122; 222), wherein an elastic sleeve (28; 128 ; 228) of e.g. rubber surrounds the outside of the valve body and protrudes above the outlet opening or openings and forms a closure for this or these when the fluid is not under pressure, the sleeve before being placed around the valve body has an inner diameter that is smaller than the diameter of the outside of the valve body, so that the sleeve is under tension and lies tightly around the valve body when the fluid is not under pressure, but can open for the fluid by deforming elastically, so that a flow through the inlet channel and through the outlet opening or openings enters between the outside of the valve body and the casing, characterized in that the valve body (14; 114; 214) comprises an outlet channel (26; 126; 226) at an axial distance from the inlet channel (20; 120; 220), with at least one inlet opening (24; 124; 224) on the outside of the valve body, within the casing (28; 128; 228) ), so that the fluid can flow from the outlet opening or openings (22; 122; 222) of the inlet channel (20; 120; 220) and to the inlet opening or openings (24; 124; 224) of the outlet channel (26; 126; 226) o g out of the valve body, as the casing (28; 128; 228) is sealingly attached to the valve body (14; 114; 214) upstream of the outlet opening or openings (22; 122; 222) and downstream of the inlet opening or openings (24; 124; 224) in relation to the direction of flow through the valve body, so that fluid entering between the outside of the valve body (14; 114; 214) and the casing (28; 128; 228) through the inlet channel (20; 120; 220) can only flow out through the outlet channel (26; 126; 226). 2. Valve as specified in claim 1, characterized in that the inlet channel (20; 12 0; 220) and the outlet channel (2 6; 126; 22 6) each comprise two or more respectively outlet openings (22; 122; 222) and inlet openings (24 ; 124; 224), these openings being distributed around the circumference of the valve body (14; 114; 214). 3. Valve as stated in claim 2, characterized in that there is an equal number of respectively outlet openings (22; 122; 222) and inlet openings (24; 124; 224), and that the openings are distributed at equal angular distances around the circumference of the valve body (14; 114; 214) . 4. Valve as stated in claim 1, characterized in that the inlet channel (20; 120; 220), the outlet channel (26; 126; 226) and the openings (22; 122; 222; 24; 124; 224) are each delimited by a curved fleet. 5. Valve as stated in claim 1, characterized in that an O-ring (30; 13 0; 230) is located at each end of the casing (2 8; 128; 228) and secures the casing tightly to the outside of the valve body (14; 114; 214), or that the ends of the sleeve are thermally sealed to the outside of the valve body, or that the ends of the sleeve are chemically attached to the outside of the valve body, or that the ends of the sleeve are glued to the outside of the valve body. 6. Valve as specified in claim 1, characterized in that the outlet opening or openings (22; 122; 222) and the inlet opening or openings (24; 124; 224) are located on diametrically opposite sides of the valve body (14; 114; 214) . 7. Valve as stated in claim 1, characterized in that the valve body (14; 114; 214) is formed from a plastic material, e.g. teflon. 8. Valve as stated in claim 1, characterized in that the inlet channel (20; 120; 220) and the outlet channel (26; 126; 226) are arranged in the longitudinal direction of the valve body (14; 114; 214), the outlet end of the inlet channel and the inlet end of the outlet channel is spaced apart in the longitudinal direction.