FI87444C - VENTILKOMBINATION - Google Patents

Description

87444

VALVE COMBINATION

The invention relates to a valve assembly for discharging fluid out of a container, for example a flexible container, and for preventing the flow of contaminants through the valve assembly into the container. The valve assembly includes an elongate valve body having an elastomeric sheath that closes the outer surface of the valve body transversely. The flow passes through the valve body 10 to a space between the outer surface of the valve body and the elastomeric jacket. As a result, the flow returns inward through the valve body and out through the outlet or outlet passage.

15 When dispensing sterile fluids from a tank with a long service life, it is important to prevent any contaminating backflow into the tank, both after and after the dispensing operation has been completed. Contamination in the form of substances from outside the valve assembly and the container may include microorganisms, atmospheric gases, moisture, dust, and the like. If a sterile liquid becomes contaminated, it can affect the quality, strength, and even safety of the product.

25 If the sterile fluid container is disposable and is not intended to be dispensed for a long time, there is usually no contaminant problem with the contaminant flowing into the container. In a prior art liquid handling tank disclosed in U.S. Pat. in U.S. Pat. No. 2,715,980, Frick, the valve mechanism already includes a valve body having a central orifice extending through the valve body and having side openings extending from the central orifice extending to the outer surface of the valve body. An expandable sleeve, such as a sleeve of rubber-like material, closes the outer surface of the valve body, preventing flow from the side openings. When flowing .35 material is to be dispensed, it flows through the central orifice and then through the side openings, causing the sleeve to expand and allow the fluid to flow out around the other end of the sleeve. During such flow, contaminants may flow to the expanded end of the sleeve and then through the side and center openings' 40 back into the tank. There is no effective barrier of contaminants to block the flow into the tank.

2 87444

Another valve with a flexible tube or sleeve is disclosed in U.S. Pat. in U.S. Patent No. 4,346,704 to Kulle. The mother liquor is dispensed through a central tube or passageway to the side openings which supply the fluid to the inner surface of the flexible sleeve or tube. When the fluid 5 is pressurized, it moves the flexible tube outward, allowing flow from the side ports outward from the end of the sleeve. The device is primarily intended for single use, such as for the administration of anesthetics. There is no particular problem with the return flow of contaminants due to such 10 disposables. The device is designed to deliver anesthetic at rapid flow and low pressure so that accurate dosing is possible.

It is a primary object of the invention to provide a valve-15 assembly for a container that allows for effortless dosing of the fluid while preventing any backflow of contaminants through the valve assembly into the container with the remainder of the fluid.

According to the invention, the valve assembly comprises an axially elongated valve body having inlet and outlet ends spaced apart in the extended direction. The valve body has an outer surface that includes an elastomeric sheath that closes transversely and presses inwardly against the outer surface. 25 The entrance passage extends from the entrance end in the extended direction for part of the distance. One or more orifices or side passages extend radially outward from the inlet passageway relative to the outer surface of the valve body. In the direction of the outlet end of the valve body, one or more openings or side passages generally extend 3Ό radially inwards from the outer surface to one end of the outlet passage which is longitudinal. The other end of the outlet passage is located at the outlet end of the valve body.

When the valve assembly is not in use, the elastomeric jacket 35 is tightly against the outer surface of the valve body, preventing any flow through the outlet passage back into the container. If pressure is applied to the container which forces the fluid to enter the inlet passage, the fluid flows from the inlet passage to the openings outwardly toward the elastomeric sheath. The pressure of the fluid 40 expands the elastomeric jacket radially outward 3 87444, thus allowing flow between the outer surface of the valve body and the jacket into the openings connected to the outlet passage. The pressure applied to the fluid and the reaction of the elastomeric jacket force the fluid to exit through the outlet passage. As the fluid 5 flows into the openings connected to the outlet passage, the elastomeric jacket regains its original shape and tightly closes the valve body and prevents any flow from the openings connected to the outlet passage into the space between the valve body and the jacket. Thus, backflow into the tank is prevented, which prevents the contaminants from entering the tank and from affecting the quality, strength or sterile cause of the fluid.

In a preferred embodiment, the valve body is extended downstream of the container. At one end of the valve body is an inlet passage extending in an extended direction and generally concentric within the body. When in most cases a single outlet passage is in operation, depending on the characteristics of the fluid to be dispensed, several multiple inlet passages may be used.

One or more openings are arranged inside the valve body, at the end of the inlet passage, i.e. at the end from the end which receives the fluid from the container, extending at an angle radially outwards from the outer surface of the body to the longitudinal direction of the valve body. Where a single opening can be used, it is preferred that there be angularly spaced openings to evenly distribute the fluid inside the elastomeric sheath to expand the sheath.

3Ό

Located at intervals in the longitudinal direction of the valve body from the openings carrying the fluid inside the elastomeric sheaths, additional openings, usually an equal number, are provided for the flow of fluid into the outlet passage extending through the longitudinal direction of the valve body and opening out of the tank. That is, the end of the outlet passage spaced from the openings forms the outlet end of the valve body.

40 In order to manufacture the valve body and to enhance the flow of material 4 87444 through the valve body, it is preferable to make the passages and orifices generally rounded in cross-section. These flow paths can be round or oval in cross section.

5

Depending on the flexible nature of the jacket and the pressure exerted by the fluid to be dispensed as it flows through the valve body, a rigid cylindrical tubular portion may be placed around the elastomeric jacket to limit the amount it can move outward from the outer surface of the valve body.

The valve combination can be used for several vessels or tanks. The compressible flexible container is preferably used in the form of a plastic bag, an accordion-folded plastic container, a bellows-type container and the like. A bellows type container is disclosed in U.S. Pat. in U.S. Patent No. 3,506,163 to Rauh et al., and U.S. Pat. in U.S. Patent No. 4,526,296 to Berger et al. The dispensing container is significant with respect to the present invention 20 only in that pressure can be applied to the fluid to force it through the valve body to expand the elastomeric jacket so that fluid passes through the valve body to its outlet end.

The valve combination can be used in dispensing agents of various compositions, including liquids, cosmetics, gels, powders, gases, and the like. The dosing tank can be used to store and supply a wide variety of products such as nutrients, pharmaceuticals, cosmetics, industrial chemicals, photographic solutions, adhesives, paints and other materials.

A significant feature of the applicant's invention is a seal formed between the elastomeric jacket and the valve body or the parts connected to the valve body. A seal is needed to ensure that the flow from the inlet passage to the openings directed between the outer surface of the valve body and the inner surface of the elastomeric sheath flows into the outlet passages of the outlet passage to provide dispensing. If the jacket is open at one end 40 or at both ends, the liquid to be dispensed can enter the bark and contaminants could enter the openings and passages and possibly the container. The jacket can be sealed at both ends in different ways, such as by O-rings, glue or heat, or by a chemical connection to the sleeve to connect the valve body or the part connected to it. By means of opposite ends of the jacket attached to the valve body, the flow of material between the outer surface of the body and the inner surface of the jacket can flow only through the outlet openings and the outlet passage. Thus, there is no loss of substance in the dosing. Furthermore, the flexible structure 10 of the jacket ensures that a barrier is obtained across the outlet holes directed against the inner surface of the jacket so that the flow of contaminants cannot pass through the openings connected to the inlet passage and the inlet passage into the tank.

A variety of materials can be used in the valve body and elastomeric jacket, selected because of their suitability for use with the fluid being dispensed and with any sterilization method used for the material. If thermal sterilization is used, the selected material must retain its integrity for the various temperatures of sterilization and the time required for sterilization. Sterilization can be performed in other ways, such as by irradiation, ethylene oxide, and the like.

λ25 Because the valve assembly of the present invention prevents any flow of contaminants into the metering tank, no antiseptics are required, which can be expensive, affect product performance, or have adverse side effects.

In the development of the invention, it has been found that contaminants such as microorganisms which enter the dosing tank can develop very vigorous growth in a short time. The invention has been tested and it has been determined that said valve combination prevents any flow of such contaminants into the tank, so that the dispensable fluid can be stored for long periods of time after it has been initially dispensed without any detrimental effects of contaminants entering the tank. .

40 In a typical embodiment, the compressible container 6 87444 is made of polyolefin, the valve body is made of Teflon with an outer diameter of 0.5 ", the elastomeric jacket is made of synthetic rubber having a shore hardness of 50, an inner diameter of 0.375" and an outer diameter of 0.45 ". with an inside diameter of. When the elastomeric jacket is fitted over the valve body, it is stretched to ensure that it maintains a sufficiently tight contact with the outer surface of the body to prevent contaminant flow when the valve assembly 10 is not in use. It is also possible to make an elastomeric sheath from real rubber and gutta-percha.

The novelty features which are characteristic of the invention are explained in the appended claims and form part of this description. For a better understanding of the invention, the advantages of its use, and the specific objects related to its use, reference is made to the accompanying drawings and illustrative material, which describe and explain preferred embodiments of the invention.

In the drawings, Figure 1 is a side view of a valve assembly embodying the invention mounted in a bellows type flexible container; Fig. 2 is a longitudinal cross-section of an embodiment of the valve assembly shown in Fig. 1; Fig. 3a is a cross-sectional view taken along line 3a-3a according to Fig. 2; Fig. 3b is a cross-sectional view taken along line 3b-3b according to Fig. 2; Fig. 3c is a cross-sectional view taken along line 3c-3c according to Fig. 2; Fig. 3d is a cross-sectional view taken along line 3d-3d according to Fig. 2; Fig. 4 is a view according to Fig. 2, in which the rigid tubular member 7 87444 is located around the valve assembly; Fig. 5 is a longitudinal cross-sectional view of a second embodiment of the invention; Fig. 6 is a cross-sectional view taken along line VI-VI according to Fig. 5; Fig. 7 is a view corresponding to Fig. 5 of yet another embodiment of the invention; Fig. 8 is a cross-sectional view taken along line VIII-VIII according to Fig. 7; Fig. 9a is a side view of a valve assembly of the invention mounted in a bellows type flexible container; and Fig. 9b is a side view of the arrangement shown in Fig. 9a rotated 90 °.

20

Figure 1 shows a bellows type flexible container 10 having a valve assembly 12 mounted at one end of the container. The valve-brick assembly is constructed so that the fluid in the container 10 is dispensed when the container is compressed.

- - 25

Figure 2 shows one embodiment of a valve assembly 12 including a valve body extended in a direction extending between the inlet end 16 and the outlet end 18. When the valve body 14 is fitted over the dispensing tank, the inlet end 16 communicates with the inside of the tank.

The inlet passage 20 extends from the inlet end 16 by a length 14 of the valve body. As can be seen in Figure 2, the input bus is about a third of this length. At the end of the inlet end 16, the opposite end ... 35 of the inlet passage 20 branches into four different openings 22 which are separated at equal angles and extend to the outer surface 14a of the valve body 14. Being spaced toward the outlet end 18 of the valve body are openings 24 extending inwardly from the outer surface 14a spaced at an equal angle 40 apart and terminating at the inner end of the outlet passage 26 8 87444. The outlet passage 26 is axially parallel to the inlet passage 20 and the two passages are spaced apart in the longitudinal direction of the valve body.

An elastomeric jacket 28 is normally in intimate contact with the outer surface 14a of the envelopes and the outer surface 28. As seen in Figure 2, said elastomeric jacket extends close to the inlet end 16 of the valve body near its outlet end 18. The jacket 28 is tightly closed at each end spaced apart in the longitudinal direction of the vent-10 brick body from the outer surface 14a of the vent brick body. As seen in Figures 3a, 3b and 3d, the jacket 28 is stretched when fitted over the valve body so as to fit snugly around the valve body, forming a partition wall of the openings 22, 24 extending through the outer surface of the valve body 14.

As can be seen in Figure 2, the jacket is secured to the outer surface of the valve body 14 by O-ring-like portions 30 which are inserted into recesses 32 in the outer surface of the valve body. In addition to the O-ring members 30, the sheath may be sealed by thermal or chemical bonding or gluing.

.25

If the container 10 shown in Figure 1 is compressed in its longitudinal direction, the contents flow out through the valve assembly 12, first passing through the inlet passage 20 to the valve body 14. As the fluid flows out of the inlet passage 20, it advances 30 into one of four openings 22 and generally radially outward to the outside 14a. The pressure of the fluid causes the elastomeric jacket 28 to expand outwardly so that the fluid flows between the outer surface 14a of the valve body and the inner surface of the elastomeric jacket until it enters the second orifice group 35 to flow radially inward. The fluid flowing from the openings 24 flows to the inner end of the outlet passage 26 and then flows through said outlet passage to exit the valve assembly.

When the fluid is not flowing through the valve assembly 12, the elastomeric jacket 28 forms a barrier, i.e., a septum, for each opening 22, 24 on the outer surface of the valve body 14. As a result, contaminants cannot flow back into the tank through the valve assembly. As soon as the fluid 5 enters said openings 24, the elastomeric jacket shrinks and closes the openings 24 on the outer surface 14a of the valve body 14, so that backflow into the container through the outlet passage part 26 is prevented.

In Fig. 4, the structure of the valve assembly is the same as in Fig. 2, except that the elongate rigid tubular member 34 is positioned around and slightly outwardly of the elastomeric jacket 28. The tubular member 34 forms an obstacle to the radially outward movement of the jacket 28. If the jacket 15 begins to expand uncontrollably, the tubular member 34 restricts its outward movement. The tubular member 34 is only needed in special circumstances and is not a necessary part of the valve assembly.

Figures 5 and 6 show another embodiment of the invention. The valve assembly 112 has a valve body 114 having an inlet end 116 and an outlet end 118. The valve body 114 is extended in the inlet and outlet directions.

.25 The valve body shall have an inlet passageway 120 extending from the inlet end 116 approximately one quarter between the ends of the valve body. In contrast to the embodiments of Figures 2, 3 and 4, a single opening 122 exits the end of the inlet passage 120, located at the inner spacing of the inlet end 116, on the outer surface of the valve body. On the diametrically opposite side of the valve body, the second opening 124 extends radially inward from the outer surface to the inner end of the outlet passage 126. The holes in the openings 122, 124 on the outer surface of the valve body are spaced apart in the longitudinal direction. This special arrangement prevents the flow 35 from being channeled between the elastomeric jacket 128 and the outer surface 114a of the valve body 114. Thus, the flow exiting the orifice 122 passes around the valve body between the outer surface 114a and the inner surface of the jacket 128 to the inlet of the orifice 124.

As can be seen in Figure 5, the opposite ends of the elastomeric jacket 128 are sealed to the outer surface 114a of the valve body 114 by O-rings 130.

Figure 6 shows an opening 122 between its inlet and outlet ends. In addition, the elastomeric sheath 128 fits snugly against the outer surface 114a of the valve body 114, thereby forming partitions for the openings 122, 124. The valve assembly 112 operates in the same general manner as the valve assembly 12 relative to the elastomeric sheath 128; through and around the valve body to the outlet passage 126.

Figures 7 and 8 show another embodiment of the valve assembly 15. Unlike the previous embodiments, this embodiment has a valve assembly 212 that includes an elongate valve body 214. The valve body extends in its longitudinal direction between the inlet end 216 and the outlet end 218. In contrast to the embodiment shown in Figures 5 and 6, this valve assembly 212 has two openings 222 branched outward from the downstream end of the inlet bus 220. The openings 222 are spaced 180 degrees apart, and each extends to the outer surface 214a of the valve body. Located spaced along the outer surface 214a from the openings 222 is a second pair of openings 224 extending si-25 inwardly from the outer surface and terminating at the inner or countercurrent end of the flow path 226. When the orifices 222 and 224 in Figure 7 appear to be in the same plane, the orifices 224 are actually rotated 90 ° relative to the orifices 222 to provide the same power as in the embodiment of Figures 5 and 6, i.e., they prevent fluid 30 from channeling through the valve assembly.

The elastomeric sheath 228 laterally closes the outer surface of the valve body from a location near the inlet end 216 to a location near the outlet end 218 so that the sheath covers the holes in the openings 222, 224 in the outer surface of the valve body. As in the previous embodiment, the ends of the elastomeric jacket 228 are sealed to the outer surface of the valve body 214 by O-rings 230. The O-rings are in recesses 232. As mentioned above, it is also possible to use other sealing means 40 to secure opposite ends of the jacket so that The fluid to be dispensed through the system does not pass through the openings 224 which extend into the flow passage 226.

As can be seen from Fig. 8, the openings are arranged diametrically opposite each other. The other openings 224 may be spaced 90 degrees from the openings shown in the figures.

Figures 9a and 9b show a second container in which the valve assembly 312 extends from the upper end of the container across its height. 10 The walls of the tank are in the shape of a cooker hood, note. Fig. 9a, so that by pressing the sides inwards against each other, the liquid is dispensed through the valve assembly 312.

When the containers 10 and 310 are each flexible containers, it would be possible to form a container assembly that is not flexible in construction but collapsible, with one part of the container being telescopically movable to another to dispense fluid. One skilled in the art will appreciate that multiple tank designs may be used with the valve assembly of the kek-20 invention.

Having set out and described in detail specific embodiments of the invention to illustrate the application of the principles of the invention, it will be understood that the invention may be practiced otherwise than without departing from the said principles.

Claims (10)

A fluid dispensing device comprising a container (10, 310) and a dispensing valve (12, 112, 212) for dispensing fluid from the container (10, 310) and preventing backflow of contaminants into the container during and after dispensing of the fluid, wherein the container (10, 310) has an outlet and is capable of discharging fluid from the container when a compressive force is applied to the fluid inside the container, characterized in that the dispensing valve (12, 112, 212) comprises an elongated valve body (14, 114, 214). has an inlet end (16, 116, 216) and an outlet end (18, 118, 218) spaced longitudinally and an outer surface (14a, 114a, 214a) extending longitudinally between the inlet end and the outlet end, the inlet end (16, 116, 216) ) is connected to the container outlet for receiving fluid flow therefrom, that an inlet duct (20, 120, 220) is located inside the valve body and has a first an end at the inlet end of the valve body (14, 114, 214) and a second end separate from the first end in the direction of the outlet end of the valve body, the inlet duct (20, 120, 220) being arranged to receive fluid from the container (10, 310); at least one first opening (22, 122, 222) of the valve body extends from the second end of the inlet duct (20, 120, 220) through the valve body to the outer surface (14a, 114a, 214a) so that the first opening 2-5 (22 , 122, 222) open through the outer surface (14a, 114a, 214a) that an outlet duct (26, 126, 226) located within the valve body (14, 114, 214) has a first end located in the vicinity of the valve body ( 14, 114, 214) outlet end (18, 118, 218) and a second end separated from the first end in the direction toward the inlet end (16, 116, 216) of the valve body, at least a second opening (24, 124, 224) in the valve body extends from the other end of the outlet duct (26, 126, 226) to in the outer surface (14a, 114a, 214a) of the valve body such that the second opening (24, 124, 224) opens through the outer surface and is separate from the first opening (22, 122, 222) where this first opening opens through the outer surface, that a elastomeric housing (28, 128, 228) laterally encloses the outer surface (14a, 114a, 214a) of the valve body and extends over the first (22, 122, 222) and second (24, 124, 224) openings and forms closures for the first and second openings, that the elastomeric casing (28, it 87444 128, 228) before placement around the valve body (14, 114, 214) has an inner diameter smaller than the diameter of the outer surface of the valve body so that the casing (28, 128, 228) is stretched and fits tightly around the valve body (14, 114, 214) so that the elastomeric housing 5 (28, 128, 228) is elastically deformable with a first position forming the closure of the first and second openings at the outer surface of the valve body and a second position separated eaten from the ground first and second openings so that flow through the inlet duct (20, 120, 220) into the first opening (22, 122, 222) occurs between the outer surface of the valve body (14, 114,214) and the casing (28, 128, 228) and flows therebetween to the second opening (24, 124, 224) and then through the second opening to the outlet channel (26, 126, 226) for discharge from the first end of the outlet channel, and the elastomeric housing (28, 128, 228) being Sealing engagement with the valve body (14, 114, 214) in the flow direction through the valve body downstream from the second opening (24, 124, 224) and upstream from the first opening (22, 122, 222) with respect to the flow direction through the valve body so that flow entering between the outer surface (14a, 114a, 214a) of the valve body and the casing passes only through the first and second openings. Fluid dispensing device according to claim 1, characterized in that the valve body (14, 114, 214) has a longitudinal center axis 25 and a plurality of first openings (22, 122, 222) and second openings (24, 124, 224). these first and second openings being angularly spaced about the center axis. Fluid dispensing device according to claim 2, characterized in that it has an equal number of first openings (22, 122, 222) and second openings (24, 124, 224) and that the first and second openings are separate around the center axis at equal angles . '25 Fluid dispensing device according to claim 1, characterized in that the inlet duct (20, 120, 220), the outlet duct (26, 126, 226) and the first (22, 122, 222) and second (24, 124, 224) apertures each are defined a transversely curved surface extending 40. 18 8 7444 Fluidium dispensing device according to claim 1, characterized in that the elastomeric housing (28, 128, 228) is formed of synthetic rubber, natural rubber, gutta-percha or a flexible plastic material. 5 A fluid dispensing device according to claim 1, characterized in that an o-ring (30, 130, 230) is located at each of the opposite ends of the elastomeric housing (28, 128, 228) which are longitudinally spaced apart and fasten. the elastomeric housing (28, 128, 228) in sealed engagement with the outer surface of the valve body (14a, 114a, 214a) or the opposite ends of the elastomeric housing (28, 128, 228) being thermally spaced longitudinally sealed or chemically bonded or adhesively attached to the outer surface of the valve body (14a, 114a, 214a). Fluid dispensing device according to claim 1, characterized in that a first opening (22, 122, 222) extends from the inlet channel (20, 120, 220) to the outer surface of the valve body and a second opening extends from the outer surface (14a, 114a) of the valve body. 214a) to the outlet duct (26, 126, 226), and that the first aperture (22, 122, 222) and the second aperture (24, 124, 224) are located on diametrically opposite sides of the valve body. 25 Fluid dispensing device according to claim 1, characterized in that the container (10, 130) is flexible, neither a bellows-like member or a flexible bladder-type container. Fluid dispensing device according to claim 1, characterized in that the valve body (14, 114, 214) is formed of a plastic material or teflon. Fluid dispensing device according to claim 1, characterized in that the inlet duct (20, 120, 220) and the outlet duct (26, 126, 226) are aligned with one another in the longitudinal direction of the valve body (14, 114, 214). the portion of the inlet duct and the other end of the outlet duct are longitudinally separated. 40