EP0492030A1 - Improved filling valve - Google Patents
Improved filling valve Download PDFInfo
- Publication number
- EP0492030A1 EP0492030A1 EP90811027A EP90811027A EP0492030A1 EP 0492030 A1 EP0492030 A1 EP 0492030A1 EP 90811027 A EP90811027 A EP 90811027A EP 90811027 A EP90811027 A EP 90811027A EP 0492030 A1 EP0492030 A1 EP 0492030A1
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- EP
- European Patent Office
- Prior art keywords
- container
- valve
- counterpressure
- filling
- cam
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B67—OPENING, CLOSING OR CLEANING BOTTLES, JARS OR SIMILAR CONTAINERS; LIQUID HANDLING
- B67C—CLEANING, FILLING WITH LIQUIDS OR SEMILIQUIDS, OR EMPTYING, OF BOTTLES, JARS, CANS, CASKS, BARRELS, OR SIMILAR CONTAINERS, NOT OTHERWISE PROVIDED FOR; FUNNELS
- B67C3/00—Bottling liquids or semiliquids; Filling jars or cans with liquids or semiliquids using bottling or like apparatus; Filling casks or barrels with liquids or semiliquids
- B67C3/02—Bottling liquids or semiliquids; Filling jars or cans with liquids or semiliquids using bottling or like apparatus
- B67C3/22—Details
- B67C3/26—Filling-heads; Means for engaging filling-heads with bottle necks
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B67—OPENING, CLOSING OR CLEANING BOTTLES, JARS OR SIMILAR CONTAINERS; LIQUID HANDLING
- B67C—CLEANING, FILLING WITH LIQUIDS OR SEMILIQUIDS, OR EMPTYING, OF BOTTLES, JARS, CANS, CASKS, BARRELS, OR SIMILAR CONTAINERS, NOT OTHERWISE PROVIDED FOR; FUNNELS
- B67C3/00—Bottling liquids or semiliquids; Filling jars or cans with liquids or semiliquids using bottling or like apparatus; Filling casks or barrels with liquids or semiliquids
- B67C3/02—Bottling liquids or semiliquids; Filling jars or cans with liquids or semiliquids using bottling or like apparatus
- B67C3/06—Bottling liquids or semiliquids; Filling jars or cans with liquids or semiliquids using bottling or like apparatus using counterpressure, i.e. filling while the container is under pressure
- B67C3/08—Bottling liquids or semiliquids; Filling jars or cans with liquids or semiliquids using bottling or like apparatus using counterpressure, i.e. filling while the container is under pressure and subsequently lowering the counterpressure
Definitions
- This invention relates to filling valves for use in counterpressure filling machines. More specifically, this invention relates to filling valves having a movable vent tube for counterpressure filling containers with carbonated liquids.
- a filling valve which connects a container with a tank containing a supply of the liquid which will fill the container, and a supply of the pressurized gas for counterpressurizing the container.
- the filling valve is controlled by a cam outside of the tank which actuates a first valve member such that the counterpressure gas is first admitted to the container.
- the container is filled with the counterpressure gas until the pressures of the gas and the liquid are equal.
- a second valve member is then opened by the cam which allows the liquid to flow into the container under the influence of gravity.
- the cam actuator closes the valve members and the bottle is lowered away from the valve in a sequenced operation.
- a plurality of filling valves are mounted to the machine on a bottom circular surface.
- the cans which are to be filled are carried along a conveyer to lifters which move along a path under the filling valves.
- Examples of such filling valves are found in U.S. Patent No. 4,750,533, Yun, which is commonly assigned.
- the Yun patent teaches a filling valve for filling cans with a pressurized fluid wherein the can is lifted to the filling valve.
- Each can is carried to a lifter which moves the can vertically upward to the filling valve.
- the lifter and the can are then moved in a circular path with the filling valve as the can is filled with the carbonated liquid. After the can is filled, the lifter lowers the can away from the valve.
- Machines which utilize lifters are relatively complex and expensive, and require complex structures to support the lifters as they cooperate with the filling valves.
- the filling valves which are used in these stationary can machines generally include two concentric valve members.
- An outer valve member for admitting liquid into the container is provided, and an inner valve member for admitting counterpressure gas into the container is further provided.
- the outlet dispensing end or "vent tube" for the inner valve member must be inserted a certain distance into the container for proper operation of the filling valve.
- the filling valve must have a relatively long stroke to meet the containers, thereby ensuring that the outlet of the vent tube is inserted the proper depth in the container and that the vent tube is lifted clear from the container after the container is filled with the carbonated liquid. The requirement of moving the filling valves along this relatively long stroke significantly slows down the overall operation of stationary container filling machines.
- the filling valves disclosed in the Rademacher et al. patent do not fulfill a long-felt need in the art for filling valves that perform fast and efficient filling of containers with carbonated liquids.
- the use of the double arm lever arrangement disclosed in the Rademacher et al. patent for allowing independent movement of the return gas tube with respect to the valve is cumbersome and requires complex mechanisms to actuate valve movement. These complex mechanisms are costly, and greatly add to the time it takes for the filling valve to be lowered into position over the container which will be filled with the carbonated liquids.
- the filling valves described above do not satisfy a long-felt need in the art for filling valves which can efficiently and expeditiously fill a large number of filling cans in a counterpressure filling machine. Filling valves which would satisfy this need should have a shortened vent tube stroke and be movable to interface with stationary containers which will be filled with carbonated liquids.
- filling valves for counterpressure filling containers with carbonated liquids are provided.
- Valve body means for conducting the carbonated liquid to the container from an external reservoir, the valve body means having an end from which the carbonated liquid is dispensed to the container is further provided.
- Counterpressure valve means movably mounted in the valve body means for controlling the flow of counterpressure gas to the container is also further provided.
- Vent tube means slidably mounted in the valve body means through the dispensing end of the valve body means for dispensing the counterpressure gas to the container, the vent tube means being slidable with respect to the valve body means from a retracted position to an extended position in the container in response to the counterpressure gas is provided.
- pressure relief means interfaced through the valve body means for venting gas from the valve after the liquid has filled the container whereby movement of the vent tube means from the extended position to the retracted position is substantially unimpeded is provided in accordance with the invention.
- housing means movably mounted with respect to the valve body means for securing the container to valve during filling is provided.
- Actuating means coupled thereto for moving the housing means relative to valve body means onto the container is further provided.
- Methods of dispensing carbonated liquids from a counterpressure filling machine to a container are provided in accordance with the present invention.
- the methods comprise the steps of moving the container in proximity to a valve in the counterpressure filling machine, moving a vent tube into a container from the valve, filling the container with counterpressure gas through the vent tube, filling the container with carbonated liquid, thereby displacing a substantial portion of the counterpressure gas from the container through the vent tube, venting remaining counterpressure gas from the container, and moving the vent tube from the container without substantial pressure impedance due to the counterpressure gas.
- Figure 1 is a schematic of a counterpressure filling machine utilizing filling valves provided in accordance with the present invention.
- Figure 2 is a side elevation view of a filling valve provided in accordance with the present invention.
- Figure 3 is a side elevation view of a filling valve provided in accordance with the present invention in engagement with a can.
- Figure 4 is a cross-sectional view of a filling valve taken along the 4-4 line of Figure 1.
- Figure 5 is a cross-sectional view of a filling valve taken along the 5-5 line of Figure 3.
- Figure 6 is a cross-sectional view of a filling valve engaged with a can as the can is being filled with carbonated liquid.
- Figure 1 is a schematic drawing of a counterpressure filling machine shown generally at 10.
- the entire machine is supported by base 20, which is mounted or rests on a conventional footing.
- a drive motor 30 having a main drive gear assembly 40 in rotational engagement with drive motor 30 is mounted to base 20.
- Main drive gear assembly 40 is supported by base 20 through main bearings 50.
- Cylindrical support casting 60 is mounted to main drive gear assembly 40.
- Reservoir 70 is generally cylindrical in shape and is supported by main drive gear assembly 40. Reservoir 70 is rotatable by main drive gear assembly 40 and contains carbonated liquid and counterpressure gas used in filling containers. Reservoir 70 is mounted to cylindrical support casting 60 by vertical support member 80 and is further centrally disposed about and in fluid communication with counterpressure gas feed hub 90, and carbonated liquid feed line 100 respectively. Due to this arrangement, a constant supply of counterpressure gas and carbonated liquid may be supplied to reservoir 70 even as it rotates.
- valve 110 Depending externally from and extending into reservoir 20 is a filling valve 110 provided in accordance with the present invention.
- a valve actuating arm 120 is connected to a cam 130 contained within the reservoir and in contact with valve 110.
- Valve actuating arm 120 is used to dispose cam 130 with respect to valve 110 in various operating positions as valve 110 fills a container 140 with carbonated liquid.
- the container may be a bottle, can, or any other receptacle appropriate for holding carbonated liquids.
- containers are repeatedly engaged and disengaged with stationary filling valves by a carousel apparatus which moves the containers to the filling valves.
- a carousel apparatus with its associated lifter mechanisms may be eliminated, and filling valve 110 is lowered onto stationary can 140 in order to fill the can with carbonated liquids.
- filling valve 110 is shown above a stationary can 140.
- Filling valve 110 is in fluid communication with reservoir 70.
- the filling valve has a generally cylindrical valve body 150 having an end from which the carbonated liquid is dispensed to a container and which extends downward onto a housing 160, herein denoted as a "bell.”
- Bell 160 is mounted to valve body 150 by machine screws 170 through bracket 180.
- Snift valve 190 is mounted to valve body 150 and, in typical operation of a counterpressure filling machine, is actuated by a snift cam to release counterpressure gas from the top of can 140 after the can has been filled with the carbonated liquid.
- a clean in place valve 200 is interfaced with valve body 150 and is actuated to allow cleaning fluid to course through the valve and accomplish the cleaning operation which kills bacteria in the filling machine.
- Bell 160 is slidably mounted around valve body 150.
- a valve actuating cam 210 is pivotally mounted to bracket 180 which joins bell 160 to valve body 150.
- An arcuate slot 220 is integrally formed in actuating cam 210.
- a cam roller 230 is housed within arcuate slot 220 and is mounted to valve body 150.
- Cam roller 230 rides within arcuate slot 220 as actuating cam 210 pivots around bracket 180.
- Cam roller 230 is rotatably mounted to valve body 150 by a cam roller shaft 240 which extends through valve body 150 to the opposite side of the valve body wherein an identical actuating cam and cam roller are mounted.
- a second cam roller shaft 250 is disposed through actuating cam 210 and bracket 180 to further secure cam 210 to valve body 150, and to mechanically join cam 210 to bell 160, which is longitudinally, slidably mounted around the bottom of valve body 150.
- a resilient spring 260 is secured at 270 to the top of valve body 150.
- Resilient spring 260 is also securely mounted on a back arm 280 which is integrally formed on actuating cam 210.
- resilient spring 260 is shown in the extended position, indicating that bell 160 is disengaged from can 140.
- actuating cam 210 is fixedly secured on a second arm 290 to a roller 300.
- Roller 300 rests on cam follower surface 310.
- Cam follower surface 310 will generally have a sloping profile which varies along the periphery of the filling machine in accordance with the position that the filling valve is intended to take with respect to the stationary cans at the various filling positions on the machine. Since cam follower surface 310 is sloped, roller 300 actuates cam 210 and drives cam 210 along cam roller 230 in arcuate slot 220 with respect to valve body 150.
- cam 210 changes its position due to the movement of the arcuate slot 220 along cam roller 230, bell 160 slidably moves longitudinally around valve body 150 and is put in engagement with can 140. In this fashion, actuating cam 210 forces bell 160 into engagement with can 140 as roller 300 rolls along cam follower surface 310, thereby causing cam roller 230 to move in engagement with arcuate slot 220.
- valve 110 is shown wherein bell 160 is engaging can 140.
- Roller 300 has rolled to a position on cam follower surface 310 such that actuating cam 210 has pivoted on shafts 240 and 250, thereby causing cam roller 230 to migrate in arcuate slot 220 to the opposite end of the arcuate slot.
- resilient spring 260 is at its natural length, and bracket 180 mounted to bell 160 through bolts 170 has forced bell 160 into engagement with the top of can 140.
- arcuate slot 220 is fashioned so as to contain an unstable point of equilibrium 320 for cam roller 230.
- cam roller 230 falls on unstable equilibrium point 320 as roller 300 forces actuating cam 210 to move, cam roller 230 is forced into the position shown in Figure 3, thereby forcibly engaging bell 160 with can 140.
- arcuate slot 220 having unstable equilibrium point 320 is assured of fixedly securing bell 160 to can 140 during the filling process.
- Unstable equilibrium point 320 within arcuate 220 is particularly necessary for filling valves provided in accordance with this invention which utilize sealing rubbers located within bell 160. Sealing rubbers for use in counterpressure filling machines and filling valves are taught in U.S. Patent No. 4,750,533, Yun which is specifically incorporated herein by reference.
- unstable equilibrium point 320 which, in preferred embodiments, is located substantially around the center of arcuate slot 220, ensures that cam roller 230 is forced into the position within arcuate slot 220 that causes actuating cam 210 to securedly fix bell 160 onto the top of can 140 during the counterpressure filling process.
- a filling valve provided in accordance with this invention is fixedly mounted through flange 370 to the bottom wall 330 of reservoir 70 by bolts 340.
- Reservoir 70 contains carbonated liquid 350 which is dispensed to can 140 during operation of the filling machine.
- a liquid passage 380 extends longitudinally through a portion of valve body 150 from the top end of valve body 150 and is in communication with liquid 350 in reservoir 70.
- a tube 390 extends upwardly through the liquid passage 380 into reservoir 70 to a point above the level of liquid 350.
- the tube 390 has a passage 400 extending longitudinally therethrough terminating at its upper end in first valve member 410 which is constructed, in preferred embodiments, to permit the flow of counterpressure gas 360 from reservoir 70 into passage 400.
- first valve member 410 which is constructed, in preferred embodiments, to permit the flow of counterpressure gas 360 from reservoir 70 into passage 400.
- Valve member 410 is actuated by a cam 420 which directly acts on a valve cap 430.
- a counterpressure spring 440 forces counterpressure valve 410 upward, thereby allowing counterpressure gas 360 to flow into and through longitudinal passage 400.
- the bottom end of tube 390 opens into a cylinder 450 which contains a longitudinally slidable piston 460 having a longitudinal passage 470 in substantial alignment with longitudinal passage 400 of tube 390.
- a vent tube 480 is secured to the bottom of piston 460 and extends longitudinally from the bottom of the piston such that the bottom of the vent tube 480 is in substantial alignment with the passage 470 of piston 460.
- Vent tube 480 is slidably mounted in valve body 150 through the end of valve body 150 for dispensing the counterpressure gas into the container.
- vent tube 480 is longitudinally slidable with respect to valve body 150 from a retracted position to an extended position in the container.
- vent tube 480 is slidable back into the retracted position in valve body 150 from the extended position in the container.
- Vent tube 480 is adapted to receive a "checkball" cage 490 to regulate the flow of the carbonated liquid to the container on its bottom end.
- Checkball cage 490 is seated in a recess 500 at the bottom end of the valve body 150.
- a ball 510 is located within the checkball cage 490.
- a resilient spring 520 is compressed between the piston 460 and the bottom end of the cylinder at 530. Resilient spring 520 urges piston 460 in an upward direction towards reservoir 470 to seat the checkball cage 490 in a recess 500.
- a second valve member 540 is located within valve body passage 380 surrounding valve tube 450. Located on the bottom of the second valve member 540 is valve seat 550 which is seated on openings 560 that extend through the bottom portion of valve body 150 to the end of bell 160. Valve seat 550 is held against openings 560 by cam 420. However, spring 620 between valve tube 390 and second valve member 540 tends to lift valve seat 550 away from openings 560 when permitted by cam 420.
- can 140 is carried by conveyor to a position in proximity under filling valve 110 in a counterpressure filling machine.
- bell 160 is lowered onto can 140 which remains stationary.
- Cam 420 then operates the valve member 410 to allow counterpressure gas to flow through the passage 400 into cylinder 450.
- the counterpressure gas presses on piston 460, causing it to move downwardly in the cylinder 450.
- the counterpressure gas overcomes the resiliency of spring 520 and thus forces vent tube 480 and checkball cage 490 into the can 140 in the extended position, as indicated by the arrows 570 in Figure 5.
- spring 620 pushes the second valve member 540 up, thereby allowing carbonated liquid to flow from reservoir 70 through passage 470 to the openings 560 and down inlet gaps 580 into can 140, as indicated by arrows 590 in Figure 6.
- the liquid entering the can 140 causes the counterpressure gas to be displaced upwardly out of the can as indicated by arrows 600 in Figure 6.
- the carbonated liquid fills can 140 until it reaches the level of ball 510 in checkball cage 490. As the liquid reaches the level of ball 510, the liquid lifts the ball upwardly until it closes the valve stem 480 and stops the flow of counterpressure gas out of can 140. This in turn stops the flow of liquid into can 140. Since the gas and the liquid are in the same reservoir 70 their pressures are equal and hence, liquid flow stops when gas can no longer escape from can 140. This method of shutting off liquid flow is accurate and efficient and is discussed in detail in the Antonelli patent.
- valve body 150 Since the counterpressure gas has been removed from valve body 150, spring 450 urges piston 460 to move upward into the valve body, thereby removing checkball cage 490 and vent tube 480 out of can 140 longitudinally back into the valve in the retracted position.
- bell 160 stays stationary and fixed to the top of can 140 since, in preferred embodiments, vent tube 480 is movable with respect to bell 160 within the valve body 150.
- pressure relief means 610 is interfaced through valve body 150 and passage 380.
- pressure relief means 610 is a passage interfaced through the valve body means.
- Passage 610 is opened to the atmosphere and allows the displaced gas and air which impedes migration of piston 460 up into valve 110 to escape valve body 150 allowing vent tube 480 substantially unrestricted traverse to the retracted position after can 140 has been filled with the carbonated liquid.
- vent tube 480 moves separately from bell 160 into, and out of can 140. Therefore, it is only necessary for bell 160 to move a short distance, typically about 1/4 inch, in order to make sealing contact with can 140. Actuating cam 210 need thus only move bell 160 a very short distance, which alleviates the necessity for complex mechanical components to bring valve 110 into sealing contact with can 140 so that can 140 can be filled with carbonated liquids. Furthermore, since vent tube 480 moves separately from bell 160, the remaining distance which checkball cage 490 must traverse to achieve the proper depth in can 140 to fill the can is similarly minimized. This further alleviates the need for complex machinery to accurately and quickly place vent tube 480 within the can so that the can may be filled.
- vent tube stroke of filling valves provided in accordance with this invention and the distance which bell 160 must move is much shorter than similar strokes of other filling machine valves in which a filling valve moves in contact with a stationary can.
- since only bell 160 moves to make sealing contact with can 140 only a small amount of mechanical structure must be moved, thereby aiding and further increasing the speed of the filling machine.
- Filling valves provided in accordance with the present invention thus solve a long-felt need in the art for filling valves which have a shortened stroke to permit faster operation of the counterpressure filling machines.
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- Filling Of Jars Or Cans And Processes For Cleaning And Sealing Jars (AREA)
Abstract
Filling valves for counterpressure filling of containers with carbonated liquids. The filling valves comprise valve bodies for conducting the carbonated liquids to the container from an external reservoir, the valve body having an end from which the carbonated liquid is dispensed to the container. The valves further comprise counterpressure valves movably mounted in the valve body for controlling the flow of counterpressure gas to the containers. Vent tubes mounted in the valve bodies through the dispensing end of the valve bodies, the vent tubes being slidable with respect to the valve bodies from a retracted position to an extended position in the containers in response to the counterpressure gas are provided. Pressure relief passages interfaced through the valve bodies for venting gas from the valves after the liquid has filled the containers whereby movement of the vent tubes from the extended position to the retracted position is substantially unimpeded are further provided. Housings movably mounted with respect to the valve bodies for securing the containers to the valves during filling and actuating cams coupled thereto for moving the housings relative to the valve bodies onto the containers are further provided in accordance with the invention.
Description
- This invention relates to filling valves for use in counterpressure filling machines. More specifically, this invention relates to filling valves having a movable vent tube for counterpressure filling containers with carbonated liquids.
- The beverage industry continually strives for machinery and methods which facilitate rapid, economical and efficient filling of containers, such as bottles or cans, with carbonated liquids. Improved machinery for filling containers with carbonated liquids and improved filling valves for rapidly and efficiently filling these containers are therefore desirable. These machines and valves must ensure that the carbonated liquid which fills the containers under pressure does not escape from the machine during filling, and that the carbonation does not escape from the liquid as the container is filled.
- Methods and apparatus for filling containers with carbonated liquids have evolved into counterpressure filling machines in which the containers are first filled with a gas under pressure, for example, CO₂, at about 40 psi. The carbonated liquid is thereafter admitted to the containers under pressure so that the carbonated liquid does not escape. The containers are then quickly closed, thereby ensuring that the carbonation does not escape the liquid. An example of a filling valve in a carbonated liquid bottling machine is shown in U.S. Patent No. 4,089,353, Antonelli, which is commonly assigned. The teachings of the Antonelli patent are specifically incorporated herein by reference.
- In the Antonelli patent, a filling valve is shown which connects a container with a tank containing a supply of the liquid which will fill the container, and a supply of the pressurized gas for counterpressurizing the container. The filling valve is controlled by a cam outside of the tank which actuates a first valve member such that the counterpressure gas is first admitted to the container. The container is filled with the counterpressure gas until the pressures of the gas and the liquid are equal. A second valve member is then opened by the cam which allows the liquid to flow into the container under the influence of gravity. When the container is filled, the cam actuator closes the valve members and the bottle is lowered away from the valve in a sequenced operation.
- In exemplary machines for filling cans employing the principles of the Antonelli patent, a plurality of filling valves are mounted to the machine on a bottom circular surface. The cans which are to be filled are carried along a conveyer to lifters which move along a path under the filling valves. Examples of such filling valves are found in U.S. Patent No. 4,750,533, Yun, which is commonly assigned. The Yun patent teaches a filling valve for filling cans with a pressurized fluid wherein the can is lifted to the filling valve. Each can is carried to a lifter which moves the can vertically upward to the filling valve. The lifter and the can are then moved in a circular path with the filling valve as the can is filled with the carbonated liquid. After the can is filled, the lifter lowers the can away from the valve. Machines which utilize lifters are relatively complex and expensive, and require complex structures to support the lifters as they cooperate with the filling valves.
- To reduce the cost and complexity of such can filling machines, machines have been developed in which the cans are not elevated toward the filling valves, but rather, remain stationary in a vertical direction while the filling valve is lowered to meet the can. Although these machines are mechanically less complicated and substantially less expensive to produce, they have a severe disadvantage due to a reduced operating speed.
- The filling valves which are used in these stationary can machines generally include two concentric valve members. An outer valve member for admitting liquid into the container is provided, and an inner valve member for admitting counterpressure gas into the container is further provided. The outlet dispensing end or "vent tube" for the inner valve member must be inserted a certain distance into the container for proper operation of the filling valve. To achieve this action, the filling valve must have a relatively long stroke to meet the containers, thereby ensuring that the outlet of the vent tube is inserted the proper depth in the container and that the vent tube is lifted clear from the container after the container is filled with the carbonated liquid. The requirement of moving the filling valves along this relatively long stroke significantly slows down the overall operation of stationary container filling machines.
- Examples of filling machines having movable filling valves may be found in U.S. Patent No. 4,679,603, Rademacher et al. The Rademacher et al. patent discloses a filling valve which can be lowered into the filling position by a cam disk and a pressure spring, or which can be lowered into position by overpressure within the filling machine vessel. A centering member within the filling valve can similarly be moved into position with the container. An upwardly extending piston member forming part of the piston-cylinder unit contains a return gas tube which can move independently of the piston-cylinder unit. The piston-cylinder unit in cooperation with a double lever arm arrangement places the filling valve in the open condition to achieve complete pressure equalization. See column 1, line 58, through column 2, line 15.
- The filling valves disclosed in the Rademacher et al. patent do not fulfill a long-felt need in the art for filling valves that perform fast and efficient filling of containers with carbonated liquids. The use of the double arm lever arrangement disclosed in the Rademacher et al. patent for allowing independent movement of the return gas tube with respect to the valve is cumbersome and requires complex mechanisms to actuate valve movement. These complex mechanisms are costly, and greatly add to the time it takes for the filling valve to be lowered into position over the container which will be filled with the carbonated liquids.
- The filling valves described above do not satisfy a long-felt need in the art for filling valves which can efficiently and expeditiously fill a large number of filling cans in a counterpressure filling machine. Filling valves which would satisfy this need should have a shortened vent tube stroke and be movable to interface with stationary containers which will be filled with carbonated liquids.
- The above mentioned long-felt needs in the art are satisfied by filling valves provided in accordance with the present invention. In accordance with this invention, filling valves for counterpressure filling containers with carbonated liquids are provided. Valve body means for conducting the carbonated liquid to the container from an external reservoir, the valve body means having an end from which the carbonated liquid is dispensed to the container is further provided. Counterpressure valve means movably mounted in the valve body means for controlling the flow of counterpressure gas to the container is also further provided. Vent tube means slidably mounted in the valve body means through the dispensing end of the valve body means for dispensing the counterpressure gas to the container, the vent tube means being slidable with respect to the valve body means from a retracted position to an extended position in the container in response to the counterpressure gas is provided. Further, pressure relief means interfaced through the valve body means for venting gas from the valve after the liquid has filled the container whereby movement of the vent tube means from the extended position to the retracted position is substantially unimpeded is provided in accordance with the invention.
- In further preferred embodiments, housing means movably mounted with respect to the valve body means for securing the container to valve during filling is provided. Actuating means coupled thereto for moving the housing means relative to valve body means onto the container is further provided.
- Methods of dispensing carbonated liquids from a counterpressure filling machine to a container are provided in accordance with the present invention. The methods comprise the steps of moving the container in proximity to a valve in the counterpressure filling machine, moving a vent tube into a container from the valve, filling the container with counterpressure gas through the vent tube, filling the container with carbonated liquid, thereby displacing a substantial portion of the counterpressure gas from the container through the vent tube, venting remaining counterpressure gas from the container, and moving the vent tube from the container without substantial pressure impedance due to the counterpressure gas.
- Figure 1 is a schematic of a counterpressure filling machine utilizing filling valves provided in accordance with the present invention.
- Figure 2 is a side elevation view of a filling valve provided in accordance with the present invention.
- Figure 3 is a side elevation view of a filling valve provided in accordance with the present invention in engagement with a can.
- Figure 4 is a cross-sectional view of a filling valve taken along the 4-4 line of Figure 1.
- Figure 5 is a cross-sectional view of a filling valve taken along the 5-5 line of Figure 3.
- Figure 6 is a cross-sectional view of a filling valve engaged with a can as the can is being filled with carbonated liquid.
- Referring now to the drawings wherein like reference numerals refer to like elements, Figure 1 is a schematic drawing of a counterpressure filling machine shown generally at 10. The entire machine is supported by
base 20, which is mounted or rests on a conventional footing. Adrive motor 30 having a maindrive gear assembly 40 in rotational engagement withdrive motor 30 is mounted tobase 20. Maindrive gear assembly 40 is supported bybase 20 throughmain bearings 50. Cylindrical support casting 60 is mounted to maindrive gear assembly 40. -
Reservoir 70 is generally cylindrical in shape and is supported by maindrive gear assembly 40.Reservoir 70 is rotatable by maindrive gear assembly 40 and contains carbonated liquid and counterpressure gas used in filling containers.Reservoir 70 is mounted to cylindrical support casting 60 byvertical support member 80 and is further centrally disposed about and in fluid communication with counterpressuregas feed hub 90, and carbonatedliquid feed line 100 respectively. Due to this arrangement, a constant supply of counterpressure gas and carbonated liquid may be supplied toreservoir 70 even as it rotates. - Depending externally from and extending into
reservoir 20 is a fillingvalve 110 provided in accordance with the present invention. Avalve actuating arm 120 is connected to acam 130 contained within the reservoir and in contact withvalve 110.Valve actuating arm 120 is used to disposecam 130 with respect tovalve 110 in various operating positions asvalve 110 fills acontainer 140 with carbonated liquid. The container may be a bottle, can, or any other receptacle appropriate for holding carbonated liquids. - In operation of previous filling machines, containers are repeatedly engaged and disengaged with stationary filling valves by a carousel apparatus which moves the containers to the filling valves. In accordance with the present invention, such a carousel apparatus with its associated lifter mechanisms may be eliminated, and filling
valve 110 is lowered ontostationary can 140 in order to fill the can with carbonated liquids. - Referring to Figure 2, filling
valve 110 is shown above astationary can 140. Fillingvalve 110 is in fluid communication withreservoir 70. The filling valve has a generallycylindrical valve body 150 having an end from which the carbonated liquid is dispensed to a container and which extends downward onto ahousing 160, herein denoted as a "bell." -
Bell 160 is mounted tovalve body 150 bymachine screws 170 throughbracket 180.Snift valve 190 is mounted tovalve body 150 and, in typical operation of a counterpressure filling machine, is actuated by a snift cam to release counterpressure gas from the top ofcan 140 after the can has been filled with the carbonated liquid. Additionally, a clean inplace valve 200 is interfaced withvalve body 150 and is actuated to allow cleaning fluid to course through the valve and accomplish the cleaning operation which kills bacteria in the filling machine. -
Bell 160 is slidably mounted aroundvalve body 150. Avalve actuating cam 210 is pivotally mounted tobracket 180 which joinsbell 160 tovalve body 150. Anarcuate slot 220 is integrally formed inactuating cam 210. Acam roller 230 is housed withinarcuate slot 220 and is mounted tovalve body 150.Cam roller 230 rides withinarcuate slot 220 as actuatingcam 210 pivots aroundbracket 180.Cam roller 230 is rotatably mounted tovalve body 150 by acam roller shaft 240 which extends throughvalve body 150 to the opposite side of the valve body wherein an identical actuating cam and cam roller are mounted. A secondcam roller shaft 250 is disposed throughactuating cam 210 andbracket 180 to furthersecure cam 210 tovalve body 150, and to mechanically joincam 210 tobell 160, which is longitudinally, slidably mounted around the bottom ofvalve body 150. - A
resilient spring 260 is secured at 270 to the top ofvalve body 150.Resilient spring 260 is also securely mounted on aback arm 280 which is integrally formed onactuating cam 210. In Figure 2,resilient spring 260 is shown in the extended position, indicating thatbell 160 is disengaged fromcan 140. - In preferred embodiments, actuating
cam 210 is fixedly secured on asecond arm 290 to aroller 300.Roller 300 rests oncam follower surface 310.Cam follower surface 310 will generally have a sloping profile which varies along the periphery of the filling machine in accordance with the position that the filling valve is intended to take with respect to the stationary cans at the various filling positions on the machine. Sincecam follower surface 310 is sloped,roller 300 actuatescam 210 and drivescam 210 alongcam roller 230 inarcuate slot 220 with respect tovalve body 150. - As
cam 210 changes its position due to the movement of thearcuate slot 220 alongcam roller 230,bell 160 slidably moves longitudinally aroundvalve body 150 and is put in engagement withcan 140. In this fashion, actuatingcam 210forces bell 160 into engagement withcan 140 asroller 300 rolls alongcam follower surface 310, thereby causingcam roller 230 to move in engagement witharcuate slot 220. - Referring now to Figure 3,
valve 110 is shown whereinbell 160 is engagingcan 140.Roller 300 has rolled to a position oncam follower surface 310 such thatactuating cam 210 has pivoted onshafts cam roller 230 to migrate inarcuate slot 220 to the opposite end of the arcuate slot. In this position,resilient spring 260 is at its natural length, andbracket 180 mounted tobell 160 throughbolts 170 has forcedbell 160 into engagement with the top ofcan 140. - In still further preferred embodiments,
arcuate slot 220 is fashioned so as to contain an unstable point ofequilibrium 320 forcam roller 230. Whencam roller 230 falls onunstable equilibrium point 320 asroller 300forces actuating cam 210 to move,cam roller 230 is forced into the position shown in Figure 3, thereby forcibly engagingbell 160 withcan 140. In this manner,arcuate slot 220 havingunstable equilibrium point 320 is assured of fixedly securingbell 160 to can 140 during the filling process. -
Unstable equilibrium point 320 within arcuate 220 is particularly necessary for filling valves provided in accordance with this invention which utilize sealing rubbers located withinbell 160. Sealing rubbers for use in counterpressure filling machines and filling valves are taught in U.S. Patent No. 4,750,533, Yun which is specifically incorporated herein by reference. Thus,unstable equilibrium point 320, which, in preferred embodiments, is located substantially around the center ofarcuate slot 220, ensures thatcam roller 230 is forced into the position withinarcuate slot 220 that causes actuatingcam 210 tosecuredly fix bell 160 onto the top ofcan 140 during the counterpressure filling process. - Referring to Figure 4, a filling valve provided in accordance with this invention is fixedly mounted through
flange 370 to thebottom wall 330 ofreservoir 70 bybolts 340.Reservoir 70 containscarbonated liquid 350 which is dispensed tocan 140 during operation of the filling machine. Acounterpressure gas 360 at elevated pressure, typically nitrogen or carbon dioxide at 40-45 psi, is aboveliquid 350 inreservoir 70. Aliquid passage 380 extends longitudinally through a portion ofvalve body 150 from the top end ofvalve body 150 and is in communication withliquid 350 inreservoir 70. - A
tube 390 extends upwardly through theliquid passage 380 intoreservoir 70 to a point above the level ofliquid 350. Thetube 390 has a passage 400 extending longitudinally therethrough terminating at its upper end infirst valve member 410 which is constructed, in preferred embodiments, to permit the flow ofcounterpressure gas 360 fromreservoir 70 into passage 400. The construction and operation of similar filling valves is described in the Antonelli patent. -
Valve member 410 is actuated by acam 420 which directly acts on avalve cap 430. Whenvalve cap 430 is released bycam 420, acounterpressure spring 440 forces counterpressurevalve 410 upward, thereby allowingcounterpressure gas 360 to flow into and through longitudinal passage 400. The bottom end oftube 390 opens into acylinder 450 which contains a longitudinallyslidable piston 460 having alongitudinal passage 470 in substantial alignment with longitudinal passage 400 oftube 390. Avent tube 480 is secured to the bottom ofpiston 460 and extends longitudinally from the bottom of the piston such that the bottom of thevent tube 480 is in substantial alignment with thepassage 470 ofpiston 460. -
Vent tube 480 is slidably mounted invalve body 150 through the end ofvalve body 150 for dispensing the counterpressure gas into the container. In preferred embodiments, venttube 480 is longitudinally slidable with respect tovalve body 150 from a retracted position to an extended position in the container. Similarly, venttube 480 is slidable back into the retracted position invalve body 150 from the extended position in the container. -
Vent tube 480 is adapted to receive a "checkball"cage 490 to regulate the flow of the carbonated liquid to the container on its bottom end.Checkball cage 490 is seated in arecess 500 at the bottom end of thevalve body 150. Aball 510 is located within thecheckball cage 490. Aresilient spring 520 is compressed between thepiston 460 and the bottom end of the cylinder at 530.Resilient spring 520 urgespiston 460 in an upward direction towardsreservoir 470 to seat thecheckball cage 490 in arecess 500. - A
second valve member 540 is located withinvalve body passage 380 surroundingvalve tube 450. Located on the bottom of thesecond valve member 540 isvalve seat 550 which is seated onopenings 560 that extend through the bottom portion ofvalve body 150 to the end ofbell 160.Valve seat 550 is held againstopenings 560 bycam 420. However,spring 620 betweenvalve tube 390 andsecond valve member 540 tends to liftvalve seat 550 away fromopenings 560 when permitted bycam 420. - Referring now to Figure 5, can 140 is carried by conveyor to a position in proximity under filling
valve 110 in a counterpressure filling machine. In this fashion,bell 160 is lowered ontocan 140 which remains stationary.Cam 420 then operates thevalve member 410 to allow counterpressure gas to flow through the passage 400 intocylinder 450. The counterpressure gas presses onpiston 460, causing it to move downwardly in thecylinder 450. The counterpressure gas overcomes the resiliency ofspring 520 and thus forces venttube 480 andcheckball cage 490 into thecan 140 in the extended position, as indicated by thearrows 570 in Figure 5. - Referring to Figure 6, when can 140 is filled with counterpressure gas,
spring 620 pushes thesecond valve member 540 up, thereby allowing carbonated liquid to flow fromreservoir 70 throughpassage 470 to theopenings 560 and downinlet gaps 580 intocan 140, as indicated byarrows 590 in Figure 6. The liquid entering thecan 140 causes the counterpressure gas to be displaced upwardly out of the can as indicated byarrows 600 in Figure 6. - The carbonated liquid fills can 140 until it reaches the level of
ball 510 incheckball cage 490. As the liquid reaches the level ofball 510, the liquid lifts the ball upwardly until it closes thevalve stem 480 and stops the flow of counterpressure gas out ofcan 140. This in turn stops the flow of liquid intocan 140. Since the gas and the liquid are in thesame reservoir 70 their pressures are equal and hence, liquid flow stops when gas can no longer escape fromcan 140. This method of shutting off liquid flow is accurate and efficient and is discussed in detail in the Antonelli patent. - At this point, the
snift valve 190 is actuated allowing the counterpressure gas in the head space ofcan 140 to be vented to the atmosphere throughvalve body 150. Since the counterpressure gas has been removed fromvalve body 150,spring 450 urgespiston 460 to move upward into the valve body, thereby removingcheckball cage 490 and venttube 480 out ofcan 140 longitudinally back into the valve in the retracted position. During this procedure,bell 160 stays stationary and fixed to the top ofcan 140 since, in preferred embodiments, venttube 480 is movable with respect tobell 160 within thevalve body 150. - However, as
piston 460 and venttube 480 are urged upward intovalve body 150, any remaining counterpressure gas and air is displaced upward and tends to overcome the resiliency ofspring 520, thereby impeding the migration ofpiston 460 and venttube 480 back up intovalve body 150 after the liquid has filled the can. In preferred embodiments, to overcome the undesirable effects of this trapped gas and air, pressure relief means 610 is interfaced throughvalve body 150 andpassage 380. In further preferred embodiments, pressure relief means 610 is a passage interfaced through the valve body means.Passage 610 is opened to the atmosphere and allows the displaced gas and air which impedes migration ofpiston 460 up intovalve 110 to escapevalve body 150 allowingvent tube 480 substantially unrestricted traverse to the retracted position aftercan 140 has been filled with the carbonated liquid. - In still further preferred embodiments, vent
tube 480 moves separately frombell 160 into, and out ofcan 140. Therefore, it is only necessary forbell 160 to move a short distance, typically about 1/4 inch, in order to make sealing contact withcan 140. Actuatingcam 210 need thus only move bell 160 a very short distance, which alleviates the necessity for complex mechanical components to bringvalve 110 into sealing contact withcan 140 so that can 140 can be filled with carbonated liquids. Furthermore, sincevent tube 480 moves separately frombell 160, the remaining distance whichcheckball cage 490 must traverse to achieve the proper depth incan 140 to fill the can is similarly minimized. This further alleviates the need for complex machinery to accurately and quickly placevent tube 480 within the can so that the can may be filled. - The vent tube stroke of filling valves provided in accordance with this invention, and the distance which
bell 160 must move is much shorter than similar strokes of other filling machine valves in which a filling valve moves in contact with a stationary can. By providing a shortened stroke, faster operation of the filling machine is achieved. This greatly increases the economy and efficiency of counterpressure filling machines provided in accordance with this invention, and solves a long-felt need in the art for counterpressure filling machines and filling valves which can fill containers with carbonated liquids at high speed. Additionally, sinceonly bell 160 moves to make sealing contact withcan 140, only a small amount of mechanical structure must be moved, thereby aiding and further increasing the speed of the filling machine. Filling valves provided in accordance with the present invention thus solve a long-felt need in the art for filling valves which have a shortened stroke to permit faster operation of the counterpressure filling machines. - There have thus been described certain preferred embodiments of methods and apparatus for filling containers with carbonated liquids. While preferred embodiments have been described, it will be appreciated by those with skill in the art that modifications are within the true spirit and scope of the invention. The appended claims are intended to cover all such modifications.
Claims (27)
- A filling valve for counterpressure filling a container with carbonated liquids comprising:
valve body means for conducting the carbonated liquid to the container;
counterpressure valve means for controlling the flow of counterpressure gas to the container;
vent tube means for dispensing the counterpressure gas to the container; - A filling valve according to claim 1, comprising:
valve body means for conducting the carbonated liquid to the container from an external reservoir, the valve body means having an end from which the carbonated liquid is dispensed to the container;
counterpressure valve means movably mounted in the valve body means for controlling the flow of counterpressure gas to the container;
vent tube means slidably mounted in the valve body means through the dispensing end of the valve body means for dispensing the counterpressure gas to the container, the vent tube means being slidable with respect to the valve body means from a retracted position to an extended position in the container in response to the counterpressure gas; and
pressure relief means interfaced through the valve body means for venting gas from the valve after the liquid has filled the container whereby movement of the vent tube means from the extended position to the retracted position is substantially unimpeded. - The valve recited in claim 1 further comprising;
a liquid passage extending through the valve body means from the counterpressure valve means to the dispensing end of the valve body means;
a cylinder formed in the valve body means between the liquid passage and the dispensing end of the valve body means; and
piston means fixedly mounted to the vent tube means and slidable in the cylinder for moving the vent tube means longitudinally through the valve body means into the container. - The valve recited in one of the preceeding claims further comprising:
resilient means mounted between the piston means and the cylinder for urging the piston up through the cylinder away from the dispensing and of the valve body means. - The valve recited in one of the presceeding claims wherein pressure from the counterpressure gas forces the piston means to move the vent tube means into the container when the counterpressure gas flows through the counterpressure valve means to the container.
- The valve recited in one of the preceeding claims wherein the resilient means urges the piston end vent tube means out of the container after a snift valve releases counterpressure gas from the container.
- The valve recited in one of the preceeding claims further comprising:
housing means movably mounted with respect to the valve body means for securing the container to the valve during filling; and actuating means coupled thereto for moving the housing means relative to the valve body means onto the container. - The valve recited in claim 7 wherein the actuating means comprises:
a cam;
at least one cam roller interfaced with the cam; and
a roller interfaced with the cam for actuating the cam to move the housing means onto the container. - The valve recited in claim 8 wherein the cam further comprises:
at least one arcuate slot wherein the cam roller is housed within the arcuate slot. - The valve recited in claim 9 wherein the arcuate slot has at least one unstable equilibrium point such that when the cam roller falls on the unstable equilibrium point, the cam moves the housing onto the container.
- The valve recited inone of the preceeding claims wherein the pressure relief
means comprises a passage between the valve body means and atmosphere so that when the resilient means urges the piston and vent tube means out of the container, gas is vented to the atmosphere through the passage. - A method of dispensing carbonated liquids from a counterpressure filling machine to a container comprising the steps of:
moving the container in proximity to a valve in the counterpressure filling machine;
moving a vent tube into the container;
filling the container with counterpressure gas ;
filling the container with the carbonated liquid, thereby displacing a substantial portion of the counterpressure gas from the container through the vent tube:
venting remaining counterpressure gas from the container; and moving the vent tube from the container. - A method of dispensing carbonated liquids from a counterpressure filling machine to a container according to claim 12 comprising the steps of :
moving the container in proximity to a valve in the counterpressure filling machine;
moving a vent tube into the container from the valve; filling the container with counterpressure gas through the vent tube;
filing the container with the carbonated liquid, thereby displacing a substantial porition of the counterpressure gas from the container through the vent tube;
venting remaining counterpressure gas from the container; and
moving the vent tube from the container without substantial pressure impedance due to the counterpressure gas. - The method recited in claims 12 or 13 wherein as the vent tube moves out of the container, the vent tube displaces counterpressure gas through a pasage in the valve to atmosphere.
- In a counterpressure filling machine for filling stationary containers with carbonated liquids, of the type in which the containers are put in engagement with filling valves that are movably engaged with the containers so that the containers can be filled with the carbonated liquids, the improvement comprising:
vent tube means arranged in relation to each filling valve for filling the containers with counterpressure gas, the vent tube means being displaceable with respect to each filling valve from a first position in relation to each valve to a second position into the container and a passage for venting gas out. - In a counterpressure filling machine for filling stationary containers with carbonated liquids, of the type in which the containers are put in engagement with filling valves that are movably engaged with the containers so that the containers can be filled with the carbonated liquids, the improvement comprising:
vent tube means disposed longitudinally through each filling valve for filling the containers with counterpressure gas, the vent tube means being slidable with respect to each filling valve from a retracted position in each filling valve to an extended position into the container in response to the counterpressure gas; and
a passage disposed through the filling valve for venting gas out of the filling valve after the container has been filled with the carbonated liquid and as the vent tube moves longitudinally in the filling valve to the retracted position. - The counterpressure filling machine recited in claims 15 or 16 further comprising:
piston means fixed mounted to the vent tube means for moving the vent tube means to the extended position into the container in response to the counterpressure gas. - The counterpressure filling machine according to one of the claims 15 to 17 further comprising:
resilient means mounted around the piston means for urging the piston means longitudinally back into the valve after the container has been filled with the carbonated liquids. - The counterpressure filling machine recited in one of claims 15 to 18 wherein remaining counterpressure gas is vented to atmosphere through the passage as the resilient means urges the piston means back into the valve.
- The counterpressure filling machine recited in one of claims 15 to 19 further comprising:
housing means movably mounted to each filling valve for securing the container to the valve during filling; and
actuating means mounted to the housing means for moving the housing means onto the container. - The counterpressure filling machine recited in claim 20 wherein the actuating means comprises:
a cam;
at least one cam roller interfaced with the cam; and
a roller interfaced with the cam for actuating the cam, thereby moving the housing means onto the container. - The counterpressure filling machine recited in one of claims 15 to 21 wherein the cam further comprises:
at least one arcuate slot wherein the cam roller is housed within the arcuate slot. - The counterpressure filling machine recited in claim 22 wherein the arcuate slot has at least one unstable equilibrium point such that when the cam roller falls on the unstable equilibrium point, the cam moves the housing onto the container.
- A filling valve for counterpressure filling a container with carbonated liquids comprising:
valve body means for conducting the carbonated liquid to the container from an external reservoir, the valve body means having an end from which the carbonated liquid is dispensed to the container;
counterpressure valve means movably mounted in the valve body means for controlling the flow of counterpressure gas to the container;
vent tube means slidably mounted in the valve body means through the dispensing end of the valve body means for dispensing the counterpressure gas to the container, the vent tube means being slidable with respect to the valve body means from a retracted position to an extended position in the container in response to the counterpressure gas;
housing means movably mounted with respect to the valve body means for securing the container to the valve during filling; and
actuating means coupled to the housing means for moving the housing means relative to the valve body means onto the container. - The valve recited in claim 24 wherein the actating means comprises:
a cam;
at least one cam roller interfaced with the cam; and
a roller interfaced with the cam for actuating the cam to move the housing means onto the container. - The valve recited in claims 24 or 25 wherein the cam further comprises:
at least one arcuate slot wherein the cam roller is housed within the arcuate slot. - The valve recited in claim 26 wherein the arcuate slot has at least one unstable equilibrium point such that when the cam roller falls on the unstable equilibrium 1 point, the cam moves the housing onto the container.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP90811027A EP0492030A1 (en) | 1990-12-27 | 1990-12-27 | Improved filling valve |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP90811027A EP0492030A1 (en) | 1990-12-27 | 1990-12-27 | Improved filling valve |
Publications (1)
Publication Number | Publication Date |
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EP0492030A1 true EP0492030A1 (en) | 1992-07-01 |
Family
ID=8205981
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP90811027A Ceased EP0492030A1 (en) | 1990-12-27 | 1990-12-27 | Improved filling valve |
Country Status (1)
Country | Link |
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EP (1) | EP0492030A1 (en) |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3626996A (en) * | 1970-04-08 | 1971-12-14 | Servi Tech Inc | Container-filling method and apparatus |
GB1359496A (en) * | 1970-08-29 | 1974-07-10 | Holstein & Kappert Maschf | Filling of containers |
US4750533A (en) * | 1981-11-27 | 1988-06-14 | Crown Cork & Seal Company, Inc. | Filling valve for counterpressure filling of cans |
US4938261A (en) * | 1988-08-08 | 1990-07-03 | H & K Inc. | Apparatus for filling cans with a liquid |
-
1990
- 1990-12-27 EP EP90811027A patent/EP0492030A1/en not_active Ceased
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3626996A (en) * | 1970-04-08 | 1971-12-14 | Servi Tech Inc | Container-filling method and apparatus |
GB1359496A (en) * | 1970-08-29 | 1974-07-10 | Holstein & Kappert Maschf | Filling of containers |
US4750533A (en) * | 1981-11-27 | 1988-06-14 | Crown Cork & Seal Company, Inc. | Filling valve for counterpressure filling of cans |
US4938261A (en) * | 1988-08-08 | 1990-07-03 | H & K Inc. | Apparatus for filling cans with a liquid |
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