HU206764B - Fluid-feeding device - Google Patents

Abstract

Assembly for dispensing fluid includes container and valve through which the fluid is dispensed when a compressing force is applied to the container, the valve preventing backflow of any contaminants into the container during and following dispensing. The valve has an elongated body with inlet and outlet ends spaced apart in the longitudinal direction. An inlet channel connected to the container outlet and extending part way into the body has at least one port extending from its inner end to the outer surface of the body and an outlet channel extending part way into the body in the opposite direction similarly has at least one port extending from its inner end to the outer surface, the two ports being spaced apart. - An elastomeric sheath laterally encloses the outside surface of the body and extends over the ports, the sheath being stretched so that it fits tightly around the valve body and normally closes the ports. On applying force to the container, fluid is able to flow from the inlet to the outlet channel via the ports and forced passage between the outer surface of the body and the sheath but flow in the opposite direction is not possible.

Description

BACKGROUND OF THE INVENTION The present invention relates to a fluid dispensing device for use in releasing a fluid from a container, such as a flexible container, which is capable of preventing any contamination from entering the container through the valve assembly. The valve assembly includes an elongated valve body which is enclosed by a resilient rubber-like (elastomeric) sleeve that covers the outer surface of the valve body. Flowing medium passes through the valve body into the space between the outer surface of the valve body and the resilient rubber-like sleeve, and then returns to the valve body and exits therefrom through an outlet or outlet.

For a long-life container from which sterile fluid is drained, it is very important to prevent any contamination from returning to the container during and after the emptying operation. Materials from outside the valve assembly and the container may include microorganisms, atmospheric gases, moisture, dust, and the like. Contamination of the sterile liquid can affect the quality, efficiency and even the safety of the product.

When a sterile liquid container is used once and is not intended to be emptied in portions over a prolonged period of time, there is usually no problem of impurities entering the container. U.S. Patent No. 2,715,980 discloses a reservoir for storing and emptying a liquid wherein the valve mechanism comprises a valve body having a centrally located opening extending through the valve body and extending from the central portion of the valve body to its outer surface. The outer surface of the valve body is enclosed by a stretchable sleeve or sleeve, such as a sleeve made of rubber-like material, which prevents flow from the branching outlet openings. When fluid is to be discharged from the container, it flows through the center opening and then through the branching outlet openings, thereby expanding the resilient rubber-like sleeve to allow the fluid to drain around one end of the sleeve or casing. During such a flow, dirt can enter the protruding end of the elastic sleeve or jacket and from there, through the branching outlets and the central opening, into the container. No effective shut-off device is available to prevent dirt from entering the tank.

Another valve is disclosed in U.S. Patent No. 4,346,704 which includes a flexible tube or sleeve. A parenteral solution, i.e., a sterile liquid that is injected subcutaneously, intramuscularly, or intravenously, is expelled from the container to a spout through a central tube or duct that delivers the liquid to the inner surface of a flexible sleeve or tube. When the fluid is pressurized, it moves the flexible tube outward, allowing flow through the branching outlets outwardly from the end of the sleeve or jacket. The device described in this patent is primarily recommended for single use, for example, for administration of anesthetic. There is no particular problem with the return of dirt to the tank as it is a single use device. The device described herein is proposed for use in delivering anesthetic, wherein the anesthetic is administered at high flow rates and low pressures such that accurate dosing is possible.

It is therefore a primary object of the present invention to provide a liquid dispensing device for containers that allows easy metering of the liquid while preventing impurities from being returned to the container through the valve assembly while the remaining liquid is still in the container.

The liquid dispensing device of the present invention comprises a container with an outlet means and a valve assembly for dispensing contaminants from the container during and after dispensing, wherein the valve assembly is provided with a longitudinally spaced inlet end and comprises a valve body having a peripheral surface between the inlet end and the outlet end. The container is formed of a resilient material and its outlet means is connected to the inlet end, an inlet duct is located inside the valve body, one end of which is connected to the inlet end of the valve body and the other end is connected with at least one inlet duct extending to the peripheral surface, the channel body having an outlet channel having one end extending towards the outlet body of the valve body and one end extending toward the inlet end of the valve body, at least one outlet channel extending from the inside of the valve body to its peripheral surface offset in the longitudinal direction of the valve body in the direction of the outlet end relative to the inlet end of the inlet duct; it has a resilient rubber-like sleeve that covers the peripheral surface of the valve body and extends beyond the first inlet passage for sealing, is smaller than the outer diameter of the valve body before being mounted on the valve body and is elastically deformable between its two positions, in the first position it closes the inlet duct and the outlet duct, while in the second position it is spaced apart so that the flow path is the space between the inlet duct, the inlet duct, the peripheral surface of the valve body and the sleeve, and the outlet is formed and the sleeve is connected to the valve body between the outlet end and the opening of the outlet channel on the peripheral surface, and between the inlet end and the opening of the inlet channel on the peripheral surface, sealed to the peripheral surface.

When the fluid delivery device is not in use, the elastic rubber-like sleeve tightly fits

EN 206 764 Β to the outside of the valve body and prevents anything from entering the tank through the outer channel. When the container is pressurized to force the fluid into the inlet conduit, the fluid flows outwardly from the inlet conduit to the elastic rubber-like sleeve through the inlet conduits. The fluid pressure expands the elastic rubber-like sleeve radially outward, thereby allowing flow between the peripheral surface of the valve body and the sleeve toward the outlet channels connected to the outlet conduit. The pressure on the fluid and the reaction of the elastic rubber-like sleeve force the fluid through the outlet duct. Once fluid has flowed into the outlet ducts connected to the outlet duct, the resilient rubber-like sleeve returns to its original shape and seals the valve body, thereby preventing anything from passing through the outlet ducts connected to the outlet duct . Accordingly, it prevents reflux into the container, thereby ensuring that contaminants do not enter the container and do not affect the quality, efficacy or sterilized state of the liquid therein.

In a preferred embodiment of the device according to the invention, the valve body is elongated in the direction of flow from the container. At one end, the valve body has an inlet duct extending in the longitudinal direction of the oblong shape and is generally centered inside the body. In most cases, a single outlet duct is sufficient and, depending on the characteristics of the fluid to be dispensed, multiple inlet ducts may be used.

At the end of the inlet duct, one or more inlet ducts are formed at a distance from the end receiving the liquid from the container, which extend radially outwardly towards the peripheral surface of the valve body at an angle to the longitudinal direction of the valve body. Although a single inlet channel could be used, it is advantageous to provide a plurality of evenly angled apertures to uniformly distribute the fluid outwardly within the elastic rubber-like sleeve, which expands the sleeve.

In the longitudinal direction of the valve body, further outlets are provided further away from the inlet channels for transferring the fluid to the inside of the elastic rubber-like sleeve, usually in the same number, to allow the fluid to flow inwardly toward an outlet channel. and opens at the end of the valve body. In other words, the end of the outlet duct, which is further away from the outlet ducts, forms the discharge end of the valve body.

It is advantageous for the inlet, inlet, outlet, and outlet ducts to be generally circular in cross-section for improved valve body fabrication and more efficient fluid flow through the valve body. Flow-through passageways can be circular or oval.

Depending on the resilient nature of the sleeve and the pressure exerted by the fluid to be dispensed during flow through the valve body, a rigid cylindrical tube section may be placed around the elastic rubber sleeve to limit the extent to which the sleeve extends beyond the periphery of the valve body. displaced.

The valve assembly can be used for a variety of containers or vessels. It is preferable to use a collapsible flexible container in the form of a plastic bag, a plastic container in the form of an accordion fold, a container of the fireplace bellows type or the like. A container similar to an inflator is disclosed in U.S. Patent Nos. 3,506,163 and 4,526,296. For purposes of the present invention, the metering container is only interesting in terms of the pressure that can be exerted on the fluid to flow through the valve body and expand the elastic rubber-like sleeve so that the fluid passes through the valve body to its outlet end.

The valve assembly of the present invention may be used to dispense materials of various consistency, including liquids, cosmetic lotions, gels, powders, gases, and the like. The dosing container can be used to store and dispense a wide variety of products, such as foods, pharmaceuticals, cosmetics, industrial chemicals, photographic solutions, adhesives, paints and more.

An essential feature of the device according to the invention is the seal formed between the resilient rubber-like sleeve and the parts of the valve body or of the valve body. The sealing is required to ensure that material flows into the inlet passages from the inlet passage between the peripheral surface of the valve body and the inner surface of the resilient rubber-like sleeve, thereby providing metering. When free at one or both ends of the sleeve, the fluid to be dispensed can be released and contaminants can enter the channels and thus the container itself. The sleeve may be sealed at its ends in various ways, for example by means of O-rings, adhesives, or the sleeve may be heat-bonded or chemically bonded to the valve body or to the part connected to the valve body. When the ends of the sleeve are sealed to the valve body, the flow of fluid directed between the peripheral surface of the valve body and the inner surface of the sleeve can only flow through the outlet ducts and the outlet duct. Accordingly, there is no fluid loss during the dosing operation. In addition, the resilient property of the sleeve ensures that it closes from the inlet and outlet channels to the inner surface of the sleeve so that the stream of contaminants cannot pass through the inlet channels and the inlet channel connected to the inlet channel.

A variety of materials can be used to form the valve body and the elastic rubber-like sleeve, which should be

They must be compatible with the properties of the liquid to be administered and must comply with the sterilization procedure used for the liquid. When using heat treatment sterilization, the selected material must maintain its integrity throughout the sterilization temperature range for the entire time required for sterilization. Sterilization can be achieved in other ways, for example by irradiation, ethylene oxide and the like.

Because the device of the invention prevents any contamination from entering the dispensing container, it is not necessary to add any preservative or preservative to the liquid, which can be costly, affect the efficacy of the product, or have potentially harmful side effects.

In further development of the invention, it has been found that impurities, such as microorganisms, multiply rapidly in the dosing tank in a short period of time. The valve structure of the present invention has been subjected to tests and it has been found that the valve structure prevents any such impurities from entering the container by allowing the liquid to be delivered to be stored for an extended period of time after a dose has been withdrawn for the first time without penetrating the container. contamination would result in any adverse effects.

In a typical embodiment of the device according to the invention, the compressible container is formed of polyolefin, the valve body is made of Teflon 0.5 (1.27 cm) in diameter, the flexible rubber-like sleeve is made of 50 Shore hard rubber with an inner diameter of 0.375 (0.9525 cm) and an outer diameter of 0.405 (1.029 cm). A rigid sleeve having an inside diameter of 0.530 (1.346 cm) was placed around the elastic rubber-like sleeve. When the resilient rubber-like sleeve is placed on the valve body, it is stretched and thus held in sufficient contact with the peripheral surface of the valve body to prevent contaminant flow when the valve assembly is not in use. The elastic rubber-like sleeve can also be made of natural rubber or gutters.

The fluid dispensing device of the present invention will now be described in more detail with reference to the accompanying drawing, in which:

Figure 1 is a perspective view of a device according to the invention mounted on an accordion-like flexible container; the

Figure 2 is a longitudinal sectional view of the device of Figure 1 shown in Figure 1; the

Figure 3a is a sectional view taken along line 3a-3a of Figure 2; the

Figure 3b is a cross-sectional view taken along line 3b-3b of Figure 2; the

Figure 3c is a cross-sectional view taken along line 3c-3c in Figure 2; the

Fig. 3d is a cross-sectional view taken along the line 3d-3d in Fig. 2; the

Figure 4 is a view similar to Figure 2, with a rigid tubular portion disposed around the device; the

Figure 5 shows another embodiment of the device according to the invention; the

Figure 6 is a cross-sectional view taken along line 6-6 of Figure 5; the

Figure 7 is a view similar to Figure 5 of another embodiment of the device of the invention; the

Figure 8 is a cross-sectional view taken along line 8-8 of Figure 7; the

Fig. 9a is a perspective view of a device according to the invention mounted on a flexible container of a fireplace-bellows type; and the

9b is a 90 ° rotated view of the arrangement.

Fig. 1 shows a flexible container (10) similar to a fireplace blower equipped with a valve assembly (12) mounted on one end of the flexible container (10). The valve assembly (12) is configured to dispense fluid from the flexible container (10) when the flexible container (10) is compressed.

Figure 2 shows an embodiment of the valve assembly (12) comprising an valve body (14), an elongated body extending between the inlet end (16) and the outlet end (18). When the valve body (14) is placed on a dispensing container, the inlet end (16) engages with the interior of the container.

An inlet channel (20) extends from the inlet end (16) to a portion of the length of the valve body (14). As depicted in Figure 2, the inlet channel (20) is approx. extends to 1/3 of the length. The end of the inlet duct (20) opposite the inlet end (16) is branched into four separate inlet ducts (22). The adjacent inlet ducts 22 are at an identical angle and extend to the peripheral surface 14a of the valve body 14. Towards the outlet end (18) of the valve body (14), there are outlets (24) extending inwardly from the peripheral surface (14a) and at an angle to one another and connected at the other end to an outlet channel (26). The axis of the outlet channel (26) is aligned with the axis of the inlet channel (20) and the inlet channel (20) and the outlet channel (26) are formed in the longitudinal direction of the valve body (14).

The circumferential surface (14a) is surrounded by a resilient rubber-like sleeve (28) and is normally in close contact with it. As shown in Fig. 2, one end of the niggly rubber-like sleeve 28 is near the inlet end 16 of the valve body 14 and the other end is near the outlet end 18. The ends of the resilient rubber-like sleeve 28, which are spaced apart in the longitudinal direction of the valve body 14, are sealed to the peripheral surface 14a of the valve body 14. As shown in Figures 3a, 3b and 3d, the rubber-like sleeve (28) is widened while being placed on the valve body (14) so that, after installation, it fits snugly against the valve body (14), and

The inlet conduits (22) and the outlet conduits (24) which open to the peripheral surface (14a) of the valve body (14) are closed.

As shown in Figure 2, the sleeve (28) is secured to the peripheral surface (14a) of the valve body (14) by O-rings (30) formed on the peripheral surface (32) of the valve body (14). are inserted into recesses. The means for sealing the two ends of the sleeve (28) may be tailored to the particular case depending on the material being used and the properties of the liquid to be delivered. In addition to the O-rings (30), the sleeve (28) may be sealed by heat treatment or chemical bonding or by the use of an adhesive.

When the flexible container (10) shown in Figure 1 is squeezed or compressed in its longitudinal direction, its contents will flow out through the valve assembly (12) and first enter the valve body (14) through the inlet channel (20) of Figure 2. As the fluid flows out of the inlet passage (20), it passes through one of the four inlet passages (22) and flows outwardly, generally radially, to the circumferential surface (14a) of the valve body (14). The fluid pressure expands the elastic rubber-like sleeve (28) outwardly so that the fluid flows between the peripheral surface (14a) of the valve body (14) and the inner surface of the elastic sleeve (28) until it reaches the outlet (24). one of the channels through which it flows radially inward. The fluid passes through the outlet duct (24) into the inner end of the outlet duct (26) and then passes through the outlet duct (26) and leaves the valve assembly (12).

When the fluid is not flowing through the valve assembly (12), the resilient rubber-like sleeve (28) forms a seal or barrier layer on the inlet channel (22) and on each of the outlet channels (24) at the peripheral surface (14a) of the valve body (14). As a result, impurities cannot flow back through the valve assembly (12) into the flexible container (10). When the fluid expands the elastic rubber-like sleeve to expand, the fluid flow prevents any contamination from entering the flexible container (10). Once the fluid has reached the outlet channels (24), the resilient rubber-like sleeve (28) will contract and seal the outlet (24) at the peripheral surface (14a) of the valve body (14) to prevent backflow of the flexible (10). into the container through the outlet conduit (26).

Figure 4 shows the same configuration of the valve assembly (12) as in Figure 2, but with a rigid, elongated tube assembly (34) positioned around and at a short distance from the resilient rubber-like sleeve (28). The role of the rigid, elongated tubular assembly (34) is to limit the radially outward displacement of the flexible sleeve (28). If the sleeve (28) is stretched and expanded in an uncontrolled manner, i.e., the extent of expansion is not limited by the material of the sleeve (28), the rigid elongated tube assembly (34) limits its outward displacement. The rigid, elongated tube assembly (34) is only required under special circumstances and is not a necessary component of the valve assembly (12).

Figures 5 and 6 show a further embodiment of the valve assembly according to the invention. Here, a valve assembly (112) has a valve body (114) having an inlet end (116) and an outlet end (118). The valve body (114) has an elongated, elongated shape in the inlet and outlet directions.

The valve body (114) has an inlet conduit (120) extending from the inlet end (116) to an angle of about 120 mm. unlike the embodiment shown in Figures 2, 3 and 4, in this embodiment a single inlet channel (122) extends from the end of the inlet channel (120), farther from the inlet end (116) to the circumferential surface (114a) of the valve body (114). At the opposite side of the valve body (114), another outlet (124) extends radially inwardly from the circumferential surface (114) to the inner end of the outlet (126). The inlet duct (122) and the outlet (124) are spaced apart longitudinally from the circumferential surface (114a) of the valve body (114). This particular arrangement prevents the flow of one or more grooves between the resilient rubber-like sleeve (128) and the peripheral surface (114a) of the valve body (114). Accordingly, the outlet flow from the inlet passage 122 extends around the valve body 114 between the peripheral surface 114a and the inner surface of the sleeve 128 toward the inlet end of the outlet passage.

As shown in Figure 5, the opposed ends of the resilient rubber-like sleeve (128) are sealed with O-rings (130) to the peripheral surface (114a) of the valve body (114).

6 illustrates an inlet channel 122 between its inlet and outlet ends. In addition, the resilient rubber-like sleeve (128) abuts the peripheral surface (114a) of the valve body (114), thereby sealing the inlet (122) and the outlet (124). The valve assembly (112) shown in Figure 5 operates according to the same general principles as the valve assembly (12), wherein the elastic rubber-like sleeve (128) is only extended outwardly when fluid is forced from the reservoir (10) into the inlet (120). channel to pass through and through valve body (114) into outlet channel (126).

Figures 7 and 8 show a further embodiment of the valve assembly according to the invention. It differs from the previous embodiments in that this embodiment has a valve assembly (212) which includes an elongated valve body (214). The valve body (214) extends in its longitudinal direction between the inlet end (216) and the outlet end (218). 5 and 6, the valve assembly (212) has two inlet channels (222) extending outwardly from an inlet channel (220) distal to the downstream end thereof.

HU 206 764 Β el. The inlet ducts 222 are at an angle of 180 ° to each other and extend to the circumferential surface 214a of the valve body 214. Further away from the inlet channels 222 from the mantle surface 214a is another pair of outlet channels 224 which extend inwardly from the mantle surface 214a and extend into an outlet channel 226. While in Figure 7, the inlet channels 222 and the outlet channels 224 appear to be in the same position, in fact, the outlet channels 224 are rotated 90 ° relative to the inlet channels 222, with the same effect. 5 and 6, that is, to prevent the formation of grooves or channels in the fluid flowing through the valve assembly.

An elastic rubber-like sleeve (228) encloses the peripheral surface (214a) of the valve body (214) extending from a location near the inlet end (216) to a location near the outlet end (218) such that the sleeve (228) 214) covers the ends of the inlet ducts 222 and the outlet ducts 224 on the circumferential surface 214a of the valve body 214a. As in previous embodiments, the ends of the elastic rubber-like sleeve (228) are sealed to the peripheral surface (214a) of the valve body (214) by means of O-rings (230). The O-rings (232) are located in recesses (232). As previously mentioned, other sealing means may be used to seal the ends of the sleeve 228 so that the fluid to be dispensed through the valve assembly 212 cannot pass around the outlet duct 224 toward the outlet duct 226.

As shown in FIG. 8, the inlet channels 222 are located at two ends of a diameter. The other outlet ducts (224) may be configured to be rotated 90 ° relative to the inlet ducts (222) shown.

9a and 9b show an additional flexible container (310) provided with a valve assembly (312) extending from the top of the flexible container (310) transversely to its upper end. The walls of the flexible container 310 are formed in the form of a fireplace bellows, see Fig. 9a, so that when the side walls are pressed toward each other, fluid flows from the flexible container 310 through the valve assembly 312.

Because the flexible containers (310) are formed of a flexible material, it is also possible to provide a container arrangement having a non-flexible structure which is collapsible or collapsible, wherein part of the container (310) can be telescopically displaced and dispensed to another. snugly received therein. One skilled in the art will recognize that a variety of container designs may be used with the valve assembly (312) of the present invention.

Although the invention has been illustrated and described in detail through specific embodiments, to illustrate how the principle of the invention may be used, it will be appreciated that the invention may be practiced otherwise without departing from these principles.

Claims (23)

PATENT CLAIMS A fluid dispensing device comprising a container with an outlet means and a valve assembly for dispensing fluid from the container during and after dispensing, which is in an open position when the container is compressed, characterized in that (12) comprising an elongated valve body (14) having a longitudinally spaced inlet end (16) and an outlet end (18) having a peripheral surface (14a) disposed between the inlet end (16) and the outlet end (18) the reservoir (10) is formed of a resilient material and its outlet means is connected to the inlet end (16), an inlet channel (20) is located inside the valve body (14), one end of which is located at the inlet end (16) of the valve body and communicating with the container (10), other at least one inlet channel (22) extending from the inside of the valve body (14) to the peripheral surface (14a), and an outlet channel (26) formed in the valve body (14) with one end at the outlet end of the valve body (14) The other end (18) is located in the direction of the inlet end (16) of the valve body (14), to which at least one outlet conduit (24) extends from the inside of the valve body (14) to its peripheral surface (14a). the orifice end being offset in the longitudinal direction of the valve body (14) relative to the outlet end (18) relative to the orifice end of the inlet channel (22); comprising a resilient rubber-like sleeve (28) covering the peripheral surface (14a) of the valve body (14) and extending over the first inlet channel (22) and the outlet channel (24) for sealing, the diameter of the valve body (14) smaller than the outer diameter of the valve body (14) and fitted close to it, it is elastically deformable between its two positions, whereby the inlet duct (22) and outlet duct (24) are closed in the first position and spaced apart in the second position and the sleeve (28) to the valve body (14) between the outlet end (18) and the opening of the outlet conduit (24) on the peripheral surface (14a) and the inlet end (16) and the inlet conduit (22) on the peripheral surface (14) 14a) is sealed to the peripheral surface (14a). Device according to Claim 1, characterized in that the valve body (14) has a longitudinal central axis and the inlet channels (22) and the outlet channels (24) are at an angle to each other. Device according to Claim 2, characterized in that the number of inlet channels (22) and the outlet channels (24) are the same and the former have the same angle. Device according to claim 1, characterized in that the inlet channel (20), the outlet channel (26), the inlet channel (22) and the outlet channel (24) have a circular or oval cross-section. HU 206 764 Β Device according to claim 4, characterized in that the inlet channel (20), the outlet channel (26), the inlet channel (22) and the outlet channel (24) are circular in cross-section. Device according to claim 1, characterized in that the sleeve (28) is made of rubber. Device according to claim 1, characterized in that the sleeve (28) is made of natural rubber. Device according to Claim 1, characterized in that the sleeve (28) is made of gutta-percha. Device according to Claim 1, characterized in that the sleeve (28) is made of flexible plastic. Device according to Claim 1, characterized in that O-rings (30) are disposed at the ends of the sleeve (28) which secure the sleeve (28) to the peripheral surface (14a) of the valve body (14). Device according to claim 1, characterized in that the ends of the sleeve (28) are sealed to the outer surface (14a) of the valve body (14) by a heat treatment process. Device according to claim 1, characterized in that the ends of the sleeve (28) are chemically bonded to the outer surface (14a) of the valve body (14). Device according to Claim 1, characterized in that the ends of the sleeve (28) are bonded to the outer surface (14a) of the valve body (14). Device according to claim 1, characterized in that the inlet channel (122) extends from the inlet channel (120) to the peripheral surface (114a) of the valve body (114), and an outlet channel (124) extends from the peripheral surface of the valve body (114). (114a) extends to the outlet duct and the inlet duct (122) and the outlet duct (124) are disposed at opposite sides of the valve body (114). Device according to claim 1, characterized in that two inlet channels (222) extend from the inlet channel (220) and two outlets (224) from the outlet channel (226) to the peripheral surface (214) of the valve body (214). such that the axis lines of the connecting inlet channels (222) and the outlet channels (224) define a plane, and the resulting two planes form an angle of 90 ° to each other. Device according to claim 1, characterized in that it is enclosed by a rigid, concentricly elongated tubular section (34) having an inside diameter greater than the outside diameter of the valve body (14) surrounded by the resilient rubber-like sleeve (28). Device according to claim 1, characterized in that the container (10) is resilient. Device according to claim 1, characterized in that the container (10, 310) is formed in a directionally compressible manner. Device according to claim 18, characterized in that the sub-container (10) is a bellows-like member. Device according to claim 18, characterized in that the container (310) is a flexible container of the fireplace-blower type. Device according to claim 1, characterized in that the inlet channel (22) meets the peripheral surface (14a) which is closer to the inlet end (16) of the valve body (14) than the outlet channel (24) into the peripheral surface. (14a) connector end. Device according to claim 1, characterized in that the valve body (14) is made of plastic. Device according to claim 22, characterized in that the valve body (14) is made of Teflon.