The present application relates to a novel and useful apparatus for eliminating oxygen in the filling of a flexible bag with a beverage such as wine.
Dissolved oxygen in wine is normally considered to be a detrimental occurrence. For example, excess oxygen in wine is capable of reducing aging potential and creating chemical reactions that influence the wine color and flavor, as well as effecting the loss of varietal character. Such developments in wine are due to enzymatic oxidation, chemical oxidation, microbial oxidation, and the like. For example, enzymatic oxidation via polyphenol oxidase (PPL) produces quinones, which cause wines to develop a brownish tint and an oxidative odor of acetaldehyde. Another enzyme, laccase, also causes browning and decreases varietal aromas in wine.
Chemical oxidation, the main oxidative process in wines, causes oxidation of polyphenols forming quinones and hydrogen peroxidase. The latter converts ethanol into acetaldehyde resulting in a Sherry-like aroma and a brown-yellow discoloration and aroma degradation. Other wine negative effects take place due to microbial oxidation, which is dependent upon oxygen being present in the wine.
Needless to say, the removal of oxygen from wine and other beverages is most important to maintain quality on various levels.
The elimination of oxygen is extremely important during the bottling or filling process, such as where wine is transferred from a cask or bulk container to a bottle or bag. In the past, inert gasses such as nitrogen and carbon dioxide have been used to purge the container being filled in order to eliminate oxygen entering the beverage within the container. However, a significant amount of oxygen enters a wine container during filling through the uncapping and recapping of the beverage container. Such ingress of oxygen is especially acute at the spout or fitment area of a flexible bag.
The removal of oxygen during the filling process of a flexible bag from a beverage such as wine is needed to preserve color and sensory characteristics.
It is therefore an object of the present application to provide a method and apparatus for filling a flexible bag with a beverage that removes oxygen from the flexible bag chamber and the spout of a flexible bag, simultaneously.
Another object of the present application is to provide a method and apparatus for eliminating oxygen in the filling of a flexible bag with a beverage that separately purges oxygen from the flexible bag and spout and rinses oxygen from the cap prior to recapping of the bag.
Another object of the present application is to provide a method and apparatus for substantially eliminating oxygen in the filling of a flexible bag with a beverage that removes residual product drips in the fill valve surfaces prior to sealing flexible bag with an oxygen rinsed cap.
Another object of the present application is to provide a method and apparatus for substantially eliminating oxygen in the filling of a flexible bag with a beverage that results in the oxygen level of the beverage of the fill bag to lie at a far lower level than that attained by prior art devices.
Another object of the present application is to provide a method and apparatus for substantially eliminating oxygen in the filling of a flexible bag with a beverage that permits consistent bag filling mechanics.
Another object of the present application is to provide a method and apparatus for substantially eliminating oxygen in the filling of a flexible bag with a beverage which may be employed in a continuous procedure utilizing multiple flexible bags.
Another object of the present application is to provide a method and apparatus for substantially eliminating oxygen in the filling of a flexible bag with a beverage that greatly avoids the detrimental effects of oxygen on beverages such as wine due to oxidation forces.
The application possesses other objects and advantages especially as concerns particular characteristics and features thereof which will become apparent as the specification continues.
For a better understanding of the application, reference is made to the following detailed description of the preferred embodiments thereof, which should be referenced to the prior disclosed drawings.
In accordance with the present application, an apparatus for greatly eliminating oxygen in the filling of a flexible bag is hereinafter described.
The apparatus of the present application utilizes a source of inert gas, such as nitrogen. Also, a source of vacuum is provided with the apparatus of the present application.
The apparatus further includes a filling head which includes a conduit for a beverage, such as wine, a conduit for the inert gas emanating from the source of inert gas, and a conduit for a vacuum originating from the source of vacuum. The filling head also includes an outlet communicating with the beverage inert gas conduit, the vacuum conduit, and the beverage source.
The apparatus is also provided with a first valve for selectively regulating the flow of the inert gas and vacuum through the inert gas and vacuum conduits to the outlet of the filling head. A second valve regulates the flow of the beverage to the outlet of the filling head.
A shroud is also provided having a first portion for substantially surrounding the filling head. The shroud also includes a second portion for substantially surrounding the closure cap employed to stop the bag spout of the flexible bag. The shroud first portion communicates with the shroud second portion.
A holder is found in the present apparatus for supporting the cap in the shroud second portion. A nozzle is connected to the source of inert gas and positioned to direct inert gas at a high velocity onto the closure cap supported by the holder in the shroud second portion. The shroud second portion further includes an inlet from the source of inert gas.
The inert gas second portion may also possess a diffuser for directing the flow of inert gas from the inlet, at a relatively low velocity, to the shroud second portion apart from the nozzle directing inert gas directly to the closure cap supported by the closure cap holder. Needless to say, the first portion of the shroud also includes an inlet communicating with the source of inert gas.
A prior art bag closure pad is also employed in the present apparatus and is movable to bias the flexible bag into a sealing configuration about the bag's spout or fitment.
The apparatus heretofore described is also employed with a method or process which includes loading and sealing the bag to the filling head.
Initially, the bag closure pad is the raised to seal the lower portion or film of the bag against the bag spout. This step insures that gasses do not enter the bag during the uncapping process. The cap is then lifted out of the spout and rotated into a portion of the shroud which is employed to create an inert gas atmosphere about the apparatus.
The filling valve of the filling head is then lowered and sealed against the filling head spout. At this point, the bag closure pad is lowered to allow a path for air to be vacuumed out of the bag for a specific length of time, typically 0.25 seconds. Vacuum is then applied to the bag from the source of vacuum employed with the apparatus of the present application.
Following vacuuming of the bag, the bag closure pad is again raised and forced against the spout. This step isolates the spout from the bag chamber. Inert gas is then delivered via the valve mechanism to the spout simultaneously with the application of vacuum to the spout through a separate conduit. This step cross-flushes residual oxygen from the spout and simultaneously purges oxygen from the vacuum conduits communicating with the filling head.
The delivery of inert gas and vacuum to the spout via the filling head is then stopped. The closure pad is then lowered, and products such as wine or other beverage is delivered to the bag via the filling head. Following the dosing of beverage into the bag, nitrogen is then again injected into the spout for an elapsed time, typically 0.05 seconds, to push beverage into the bag and to clear the spout of residual liquid. The bag closure pad is then again raised to seal the product into the bag.
Subsequently, the product filling valve is lifted to a “seal break” position and paused for a set period of time. Vacuum is then applied to remove residual product drips adhering to the filling valve surface. The cap, separate from the bag, is then rinsed of oxygen by the directing of inert gas to the cap in the shroud chamber. The cap is then again moved over the spout to recap the filled beverage bag.
It may be apparent that a novel and useful method and apparatus for eliminating oxygen in filling a flexible bag has been hereinabove described.
Various aspects of the present application will evolve from the following detailed description of the preferred embodiments thereof which should be referenced to the prior delineated drawings.
With reference to
Conduits 44 and 46 deliver vacuum and/or nitrogen to tubes 48 and 50 of filling head 22. Beverage intended to fill flexible bag 24 is passed from beverage source 52 to beverage inlet 54 of filling head 22 via beverage channel 56,
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A prior art programmable logic control, such as one manufactured by Allen-Bradly of Milwaukee, Wis., is employed to activate and deactivate valve pairs 40 and 42, valve stem 60 of filling head 22, rotatable gripper 84, and other mechanical servo and pneumatic components of apparatus 10.
Employing apparatus 10, a novel method is depicted for substantially eliminating oxygen from the interior 82 of flexible bag 24.
Initially, bag 24 is loaded onto the filling head 22 by the use of a spout gripper 96,
After this time period elapses, the bag closure pad 72 is raised to isolate spout interior 80 from interior 82 of bag 24. At this point, the vacuum through tube 48 is turned off and inert gas through tube 48 is turned on. This action displaces and cross flushes any residual oxygen from the interior 80 of spout 34 and purges any oxygen from conduit 44, tube 48, tube 50, and conduit 46. After a lapse, typically 0.25 seconds, vacuum valve pairs 36 and 38 are turned off.
At the cessation of the operation of vacuum valves 36 and 38, product filling valve stem 60 is opened according to directional arrow 62, and the proper amount of beverage is passed into the interior 82 of flexible bag 24 from beverage source 52. Following filling of bag 24, beverage filling valve stem 60 is closed (moved downwardly in
After a short elapsed time, typically 0.0025 seconds, product filling valve stem 60 is lifted upwardly approximately 3 millimeters into a “seal break” position. Filling valve stem 60 remains in this position for a short period of time, typically 0.15 seconds. In this “seal break” position, valve pairs 36 and 38 apply vacuum to tubes 48 and 50 which removes residual beverage drips adhering to the fill valve surfaces. Such “seal break” creates a high velocity condition that essentially vacuums the entire circular seal area about valve stem 60. Thus, the low pressure of the vacuum applied to valve stem 60 is magnified to increase effectiveness.
Closure cap 32 is then rinsed of oxygen by the directing of nitrogen from nozzle 90 and through diffuser 86. Spout 34 is subsequently then lowered from filling head 22, cap 32 is rotated from shroud second portion 28 into a position over spout 34, and is reinserted into spout 34. Filled bag 24 is then ejected from the filling chamber.
It has been found that the concentration of oxygen in filled bag 24 is at a level of 1% or less.
While in the foregoing embodiments of the application have been set forth in considerable detail for the purposes of making a complete disclosure of the invention, numerous changes may be made in such details without departing from the spirit and principles of the invention.
Number | Name | Date | Kind |
---|---|---|---|
4445550 | Davis | May 1984 | A |
4446674 | Inada | May 1984 | A |
4494363 | Rica | Jan 1985 | A |
4519184 | Brunswick | May 1985 | A |
10059476 | Parisini | Aug 2018 | B2 |
20170158366 | Decio | Jun 2017 | A1 |