This disclosure relates to manufacture of pressurized flexible, composition containing pouches formed of polymeric film and the apparatus and method for making them. More particularly, it is related to mechanism for producing and separating completed pouches from a travelling web of adhered films and the associated method of doing so.
Flexible pouches made of polymeric film and filled with a consumable product are commonly produced on equipment having an array of pouch forming mold configurations. These pouch forming mold configurations are often incorporated into a rotating drum, or axially movable platen. Examples of such forming, filling and sealing systems include U.S. Pat. No. 3,218,776, issued Nov. 23, 1965 to Charles E. Cloud, and U.S. Pat. No. 9,162,413, issued to Cloud Packaging Solutions, LLC, the entire contents of which are hereby incorporated herein by reference as if fully set forth.
Machines or systems are known for forming flexible sealed pouches or packages containing a consumable product. Such pouches may be made from two continuous films in which a first or base film is vacuum formed into mold configuration cavities on a rotating forming drum to define pockets to be filled with one or more products or materials and subsequently closed by a second or lid film. On release of a completed pouch from its mold cavity, the known shrinkage of the base film and complementary stretch or expansion of the lid film cause the resultant internal pressurization of the pouch and ultimate shape of a completed pouch. Some more recent configurations include multiple compartment pouches, and pouches in which more than two films are employed.
A known two-layer pouch may be made of polyvinyl alcohol (PVA) or similar soft, deformable and water soluble polymeric material. It includes one or more product-containing chambers within a perimeter seal seam defined by the edge of pouch mold configurations on a film support surface of a forming drum or platen. Typically, the process for separation of the completed pouches from the web of adhered films results in creation of a perimeter flange about the seal seam that has a rectangular or square perimeter edge configuration.
Traditionally, the formed and filled pouches are cut from the continuous web of adhered films using stationary slitting blades that cut the moving web into longitudinal strips. Thereafter, rotating transverse blades cut the strips between rows of pouches to separate the strips into individual pouches. The result is a filled pouch with a perimeter flange of surrounding material comprising adhered layers of film having a rectangular or square perimeter edge. A modern example of such a machine and process for forming such pouches is disclosed in previously identified U.S. Pat. No. 9,162,413. (See also U.S. Pat. No. 3,218,776.)
The foregoing process is particularly suitable for producing flexible packages from water soluble film, such as polyvinyl alcohol (PVA). A highly successful application involves manufacture of individual dosage pouches of liquid laundry detergent and/or liquid dish washing detergent, though other commercial applications are also known.
The industry has, for some time, contemplated production of formed filled and sealed pouches with a more cost effective, or attractive shape, particularly, a pouch with a unique surrounding perimeter flange. U.S. patent application Ser. No. 15/812,601, filed on Nov. 14, 2017, Patent Publication No. 2018/0133919 A1, published May 17, 2018, entitled “Machine for Cutting Pouches with Shaped Perimeter Edge, Method and Pouch,” discloses a pouch forming machine capable of providing pouches having an other than a rectangular-shaped perimeter edge flange. The apparatus there disclosed employs a rotary blade drum assembly with blade portions that coact with the film support surface mold configurations to separate pouches along the entire perimeter edge of the perimeter flange of the pouch. The entire specification and drawings of that application are incorporated by reference into this disclosure, as if fully set forth herein.
The evolution of commercial apparatus for separating pressurized pouches from a travelling web of adhered films using a rotary knife operating in association with the film support surface has brought forth a recognition of the need to stabilize the pouch position relative to the coacting separation elements. This recognition has been particularly significant in relation to the need to overcome the effects on pouch position of internal pressure within the pouch on termination of vacuum to the mold cavities and film tension due to elastic deformation.
Accordingly, this disclosure emphasizes structure and methodology to ensure structural and aesthetic integrity of the resultant pouches. Integral to this accomplishment is the maintenance of pouch position and shape relative to the elements of the separation apparatus.
This disclosure provides mechanism and method for separating pouches that attain the foregoing goals. In particular, it provides the capability to produce pouch shapes having non-rectangular perimeter edges resulting in unique and attractive pouch shapes that were heretofore unobtainable. The principles here disclosed are applicable to multiple forms of pouch making mechanisms, including rotary drum and flat platen machines.
Apparatus disclosed for forming product containing pouches from a travelling web of adhered films includes a film support surface, having a plurality of mold configurations, and a film retention chamber in the film support surface preceding and trailing each of the mold configurations. A vacuum system applies vacuum to the mold configurations and film retention chambers to form product containing pockets and to secure the film in the film retention chambers. Separation blades in synchronous register with the mold configurations separate the pouches from the travelling web. In one form the film support surface comprises a rotary forming drum and a rotary blade drum includes the separation blades.
In this disclosure, longitudinal means along the length of the travelling web of film or films. Transverse or lateral means across the film from edge-to-edge. In connection with the base forming drum, inward means toward the axis of rotation of the drum. Circumferential means about the circumference of the outer generally cylindrical film support surface of the drum. Transverse means parallel to the rotational axis of the drum. Downstream means in the direction of travel of the film. A leading edge or trailing edge is used in its usual context of the direction of movement or advancement.
Turning now to the drawings,
Typical film thicknesses for soft blister pouches are 0.001″ (inch) to 0.004″ (inch) thick. The formed stock, sometimes called the base film, is typically around 0.003″ (inch) thick. The lid stock or lid film may be thinner, for example, around 0.002″ (inch) thick. These thicknesses may vary and are not requisite for the principles of this disclosure.
Referring to
The pouch 200 has a generally circular perimeter flange 211 of adhered films with a circular perimeter edge 215. The illustrated pouch 200 has an overall diameter at perimeter edge 215 of about 2½″ (inch) (63.5 mm.). The surrounding flange has a width of 0.16″ (inch) (4 mm.). This pouch shape is, of course, merely illustrative and not limiting.
Three separate interior volumes or chambers are separated by webs 207 of adhered films 202 and 204. Each separate volume contains a product component 210, which may be the same or a different composition, usually a liquid, or other suitable material, such as granular or powdered material.
Pouches formed of polymeric material, such as polyvinyl alcohol, are prone to shrinkage and distortion after forming, filling and sealing. When located in the mold cavity, an applied vacuum from the machine vacuum system retains the shape dictated by the mold configuration. Once vacuum is terminated, however, the pouch base pocket changes shape due to recovering film tension. Because the pouch 200 is sealed, the base film shrinkage is accommodated through stretching of lid film 204 to form the final shape. Often lid film 204 is a thinner material than base film 202 to augment the expansion characteristics of the lid film.
Pouch 200 of
A rotatable base forming drum 220, having an outer generally cylindrical film support surface 223, includes multiple transverse rows of pouch forming mold configurations 224 defining mold cavities to produce multiple pouches simultaneously. Typically, the rotary drum 220 comprises a plurality of combined long bars 221 assembled to form a wheel. The outer generally cylindrical film support surface of the combined bars 221 is best reflected by generally cylindrical end portions 219, seen in
A supply roll of continuous film material provides the base film 202. It is delivered to base forming drum 220 from a film heater system and overlies the transverse extent of generally cylindrical film support surface 223, including portions of generally cylindrical end portions 219. End portions 219 may include vacuum ports 217, seen in
The wheel, comprising drum 220, also carries concentrically disposed circular vacuum distribution plate 222, seen in
Referring to
Elements of the vacuum system 250, as shown in
The heater system 340 is depicted as a rotatable base film heater roller 342 positioned adjacent the base forming drum 220. It includes an internal element to heat the base film 202 prior to it contacting the film support surface 223 of base forming drum 220 or being drawn into mold configurations 224 to form product pockets. The heater system 340 may be configured as a cartridge-type heater within the base film heater roller 342 but other types of heaters, either internal or external to a roller, may be used if desired. In a typical method of thermoforming, for example, PVA or similar film, on a rotary drum form fill and seal pouch machine, the film is heated to a range of 140° F. to 400° F. depending on film thickness, type of film and other operational parameters.
A product feed mechanism 345 is positioned generally adjacent the base forming drum 220 to supply one or more product components into each chamber of the product pocket as the base film 202 moves along with the film support surface 223 of rotating drum 220. Product feed mechanism 345 may include multiple feed nozzles 346 to deliver product, such as a liquid, to individual chambers of a multiple chamber pouch, as is well known in the art and may take any known form. Such mechanisms may also be configured to feed any desired type of composition, number or combination of individual products and/or materials, preferably including a liquid composition. Of course the product could comprise any suitable combination of a gel, a solid, a powder, a paste or wax-type product, pills, tablets, or even other pouched products.
A supply roll of continuous film material provides the lid film 204. The lid film 204 is aligned with the base film 202 so as to come into overlying contact with the base film 202 after the filling of the formed pockets of the base film within mold configurations 224. The illustrated lid wetting system 360 helps create a strong seal between the base film 202 and lid film 204. It is positioned adjacent the lid film 204 at a position upstream of where the lid film 204 seals to the base film 202 at the base forming drum 220.
The lid wetting system 360 may apply a solvent to the lid film 204 to increase its tackiness to assist in adhering the lid film 204 to the base film 202. To do so, the solvent may be provided through a wetting reservoir 362 to a wetting roller 363 that engages the lid film 204. In instances where the base film 202 and lid film 204 are formed of a polyvinyl alcohol material, the solvent for the lid wetting system 360 may be water.
A sealing system 370 having a sealing roller 372 is positioned in close contacting relation to the film support surface 223 of base forming drum 220. Lid film 204 passes around sealing roller 372 and is urged into sealing contact with base film 202 to urge the contacting surfaces of base film 202 and lid film 204 into adhering, sealed relation. In this regard, the sealing roller 372 is mounted such that it applies pressure to the overlying films to perfect the sealing relationship. Sealing roller 372 may include an outer layer 373 formed of material that is deformable, such as a rubber or similar material, though this is not essential. Typically, this material has a thickness of about one-half inch (½″) and a durometer of about 60, though these values may vary. The material, and the pressure exerted on the overlying films, assures effective contact of base film 202 and lid film 204 along the sealed interface 206. Of course, depending on the film material, it is also known to use heat, ultrasonic welding or other similar process to seal the lid film and base film together to form a completed pouch.
The foregoing mechanism is typical of rotary form fill and seal pouch forming machine with a base forming drum producing a travelling web of adhered films interspersed with filled product component chambers. The description to follow describes apparatus and method in accordance with this disclosure for separation of the product component pouches from the travelling web. This apparatus and method provide the capability to produce individual pouches of unique configurations, which, in this illustration, is circular.
A pouch separation station 380 is located after, or downstream from the location at which the base film 202 and the lid film 204 are secured together to form the web of adhered films. It comprises a rotary blade drum assembly 280 configured in accordance herewith to coact with the base forming drum 220 to individually separate each completed pouch 200 from the travelling web of adhered films.
The cooperative machine elements and their functional coaction are illustrated and described in detail below in relation to production of the unique pouch configuration illustrated in
A key component of the disclosed separation system is base forming drum 220, seen in
As illustrated, each long bar 221 includes a transverse row of mold configurations 224. Each mold configuration 224 defines a mold cavity surrounded by continuous perimeter land 230. Each cavity is divided into multiple chambers by divider lands 229. With the long bars assembled, as shown in
In operation, the base film 202 for a pouch is supported upon the outer film support surface 223 during the pouch forming and filling steps of the pouch making process. After filling, lid film 204 is adhered to the base film 202 in a well-known manner. Rotating base forming drum 220 carries the travelling web of adhered films through completion of the pouch forming process. The combined web of adhered films advances to the pouch separation system 380, with the completed pouches retained by vacuum within the cavities of mold configurations 224. The resultant pouch here has a perimeter flange 211 with perimeter edge 215 follows the profile of the mold configuration 224. The illustrative pouch, produced by the principles of this disclosure is a multi-compartment pouch with three separate chambers; however, the principles of this disclosure are equally applicable to single compartment pouches, as well as pouches with any number of chambers.
With reference to the mold configuration 224 of
The pouch defining chambers are encircled by continuous perimeter land 230, which is co-extensive with smooth outer film support surface 223 of base forming drum 220. Continuous perimeter land 230 includes outer perimeter edge 232. The radial extent of perimeter land 230, inward from perimeter edge 232 to the mold cavity defines the width of the surrounding web of adhered films or perimeter flange 211 of pouch 200, seen in
Referring to
A perimeter separation land 240 surrounds each groove 238, defining the radial outer extent of the blade groove 238. Land 240 is coextensive with, and forms a part of, outer film support surface 223 of base forming drum 220. Thus, as can be appreciated, base film 202 disposed upon film support surface 223, is in contact with cylindrical end portions 219, leading edge lands 227 and trailing edge lands 228, divider lands 229 continuous perimeter land 230 and perimeter separation land 240, all of which comprise the outer film support surface 223 for base film 202 on base forming drum 220.
Referring to
Best seen in
Trailing film retention chambers or cavities 244 are formed between trailing edge lands 228 and the merged perimeter separation lands 240. Trailing film retention chambers or cavity 244 adjacent cylindrical end portions 219 of film support surface 223 terminate at cylindrical end portions 219.
As will become apparent in accordance with this disclosure, the film retention chambers 243 and 244 are significant to the achievement of successful separation of completed pouches 200 from the travelling web of adhered films 202 and 204.
As seen in
Ports or apertures 246 within leading film retention chamber 243 and trailing film retention chambers 244 are connected via conduits or passageways to valve ports or openings 248 positioned in a circular pattern concentric to the pattern of ports 247 on vacuum distribution plate 222, again, one for each long bar 221.
Turning now to
Slots 262 and 264 of stationary plate 260 are concentric arcuate segments of a circle extending from a “vacuum applied” end 265 to a “vacuum not applied” end 267. With base forming drum 220 rotatably mounted on the machine frame, slots 262 and 264, respectively, overlie valve port openings 247 and 248 and provide communication between the vacuum source, regulators 254 and 255, and ports or apertures 245 and 246, mold configurations 224 and leading and trailing edge chambers 243 and 244.
The arcuate length of slots 262 and 264 between vacuum “applied” and vacuum “not applied” ends determines the period of vacuum application at mold cavity ports or apertures 245 and ports or apertures 246 of film retention chambers 243 and 244.
Note that grooves 262 and 264 are discontinuous at ungrooved portions 269 of stationary distribution plate 260. This interruption provides isolation of the vacuum elements of bars 221 at the pouch separation station 380 from bars at the base film roller 342.
Notably, the vacuum system 250 of this disclosure includes two separate branches, one to serve as a vacuum source for the pouch cavities, or mold configurations 224 through ports 245, and another to serve as a vacuum source for leading film retention chamber 243 and trailing film retention chambers 244 through ports 246. With separate regulators 254 and 255 and separate timing distribution grooves 262 and 264 vacuum timing and intensity may be controlled independently, if desired. Notably, conduits 256 and 258 have separate connections to the separated portions of the slots 262 and 264 to ensure uniform vacuum intensity at the bars 221 undergoing disposition of film 202 on drum 220 unaffected by downstream fluctuations.
As is readily appreciated, base film 202 is subjected to vacuum within mold configurations 224 upon initial disposition of film 202 upon outer generally cylindrical film support surface 223 of base forming drum 220 at base film roller 342. Such vacuum causes the deposited film to conform to the shape of the product receiving cavities of the mold configurations 224. The vacuum is maintained throughout travel of the rotating drum from initial contact of the film 202 through each processing station, including pouch separation at separation station 380. This vacuum is impressed at ports 247 of rotating plate 222 through slot 262 connected to vacuum pump 252 through conduits or passageways 256. Vacuum timing within the mold configurations is controlled by the arcuate length between the ends 265 and 267 of groove or slot 262.
In this disclosure, vacuum of system 250 is also applied to leading film retention chamber 243 and trailing film retention chambers 244, causing base film 202 to conform to the cavities defined by these void areas of the generally cylindrical film support surface 223. As a result, the portions of base film 202 overlying perimeter separation lands 240, continuous blade grooves 238 and continuous perimeter lands 230 of mold configurations 224 are retained against dislodgement or undesirable movement.
The vacuum to leading film retention chamber 243 and trailing film retention chambers 244 is applied at ports 248 of rotating plate 222 through slot 264, connected to vacuum pump 252 by conduit or passageways 258. The position of the ends 265 and 267 of groove 264 control the vacuum timing, which is maintained throughout the pouch forming process, including separation.
The resultant stability of the web of films 202 and 204 on generally cylindrical film support surface 223 at the pouch separation station 380 enhances the capability of the separation station performance creating pouches in accordance herewith. The separation system 380, including illustrated rotary blade drum assembly 280 described below, separates each completed pouch 200 from the moving web of films 202 and 204 carried on base forming drum 220 along the entire perimeter edge 215 of circular flange 211 of each pouch 200.
Referring to
Rotary blade drum assembly 280 is positioned downstream of the forming, filling and sealing stations and is thus arranged to engage the travelling web of adhered base and lid films 202 and 204 after formation of filled and sealed pouches 200, which, at this juncture, are integral to the adhered films. As is normal in such a machine, it is contemplated that the base film 202 remains under vacuum within the mold configuration cavities 224 through ports 245 (
As can be appreciated and best seen in
Rotary blade drum assembly 280 is powered by the form, fill and seal machine to rotate in synchronization with the base forming drum 220 and in registry with mold configurations 224, and consequently, the advancing films 202 and 204 supported on film support surface 223 of drum 220. Rotary blade drum assembly 280 may be carried by a slidable carriage for translation toward and away from base forming drum 220 to operatively associate these for the pouch separation process. A servo-driven ball screw actuator, or any other suitable mechanism, may be employed to move the rotary blade drum assembly 280 relative to the forming drum 220.
The rotatable forming drum 220 and rotary blade drum assembly 280 may be powered, for example, by synchronous servo-motors with computerized control circuitry to ensure proper operational positioning and interaction. Rotary blade drum assembly 280 may be powered, as previously described, for controlled rotational movement about an axis parallel to the axis of rotation of base forming drum 220 in direction “B” shown in
As seen in
Rotary blade drum assembly 280 roller portion 282 has a drum outer cylindrical contact surface 286 defined by resilient insulating layers 288 and 297, described more fully below. The roller portion 282 has an axial length generally coextensive with the transverse width of base forming drum 220. When the base forming drum 220 and rotary blade drum assembly 280 are in operative association to each other, drum outer cylindrical contact surface 286 is in rolling contact with lid film 204 of the travelling web of adhered films 202 and 204. Of course, as explained, base film 202 is carried upon film support surface 223 of base forming drum 220, and is deformed by vacuum into the cavities of mold configurations 224, leading film retention chamber 243 and trailing film retention chambers 244.
The rotary blade drum assembly 280 is urged toward rotating base forming drum 220 to maintain this operating relationship. The effective diameter of the drum outer cylindrical contact surface 286, defined by the outer surfaces of insulating layer 288, is such that the outer film support surface 223 and the cylindrical drum contact surface 288 of rotary blade drum assembly 280 travel at the same linear velocity.
As seen in
In this illustrated embodiment, the blades 290 each include a distal edge 294 that extends radially outward of drum outer cylindrical contact surface 280. Blades 290 are configured to mesh with the generally circumferential continuous blade groove 238. The grooves 238 of each mold configuration surround each mold configuration 224. Consequently, the blades define perimeter edge 215 of each formed pouch 200. In this regard, each blade 290 forms a separation pattern sized and arranged to progressively engage the web of films 202 and 204 from leading edge 291 to trailing edge 292 within associated groove 238 and separate a single pouch 200 along the entire perimeter of each groove 238.
Blades 290 are circular in shape. In the direction of rotation of blade drum 280 each blade 290 leading edge at 291 first contacts the travelling web of adhered films 202 and 204 within a continuous blade groove 238. On contact with the films, the leading edge 291 initiates the separation process, which, by virtue of the rotation of base drum 220 and rotary blade drum assembly 280, progresses transversely and circumferentially about the perimeter land 230 until it completes separation at trailing edge 292. (See
As can be appreciated, the continuous blade groove 238 of each mold configuration 224 completely surrounds the entire circular perimeter edge 232 of continuous perimeter land 230 of the mold configuration. Cylindrical blades 290 are also sized and arranged to enter, sequentially, groove 238 and completely surround the continuous perimeter land 230 as the separation process proceeds. The interaction of the heated blades 290 and associated groove 238 forms the circular perimeter edge 215 and circular flange 211 of each separated pouch 200.
In accordance with the disclosure, the shape of the continuous perimeter groove 238 groove of each mold configuration and coacting blade 290 of the blade drum 280 can be any pattern desired. Examples of pouches with an irregular shaped perimeter flange are found in the previously mentioned U.S. Publication 2018/0137819. Exemplary of the capabilities available through implementation of the principles described here, the disclosure of U.S. Publication previously identified, shows other shapes that could be created with a pouch separation system having a rotary blade drum assembly operatively associated with a base forming drum containing a pattern of mold configurations with a blade receiving surrounding perimeter groove. These principles are applicable to such unique shapes as well as to rectangular or square shapes where a blade configuration forms the entire perimeter edge of the pouch.
As stated, the distal edges 294 of the blades 290 extend somewhat beyond the insulating layer 288. This allows the blades to enter the grooves 238 of base forming drum 220 without touching the drum. At maximum penetration, the distal edges 294 of the blades 290 enter the grooves 238, typically about ⅛″ (inch) (3.175 mm.) and usually not less than 1/16″ (inch) (1.58 mm.). Note that this dimension is important to extraction of each pouch 200 from the travelling web of adhered films 202 and 204. The greater the penetration, the higher the separation force applied to the web of films by the blades 290 within grooves 238.
The blades 290, one for each mold configuration of a long bar 221, are arranged in a transverse linear pattern along the length of the rotary blade drum 280. Hence, all pouches formed by mold configurations 224 in a single long bar 221 are separated from the film simultaneously. Here, each long bar includes eight mold configurations 224. Thus, each row of circular blades 290 of rotary blade drum includes eight blades 290. In the circumferential direction of rotation of rotary blade drum 280, the pattern of blades 290 advances sequentially from long bar to long bar of rotating base forming drum 220.
As illustrated, the rotary blade drum assembly 280 has four rows of blades spaced circumferentially of drum 280. The illustrated base forming drum 220 is comprised of numerous long bars 221 forming the cylindrical drum outer film support surface 223. Rotary blade drum assembly 280 has a diameter substantially smaller than the diameter of base forming drum 220. However, blades 290 are in register with grooves 238. Thus, the circumferential spacing between the leading edge 291 of one blade 290 and the leading edge 291 of the blade in the adjacent row must equal the distance between the leading and trailing edge 225 and 226 of a bar 221. As explained, the outer film support surface 223 and drum outer cylindrical contact surface 286 travel at the same linear velocity to maintain synchronous registry between the blades 290 and grooves 238.
It should be noted that in order to efficiently separate the web of adhered films and pouches, the rotary blade drum assembly 280 includes axial bores into which are inserted wound cartridge resistive heating elements 295, seen in
To prevent the heated rotary blade drum 280 from damaging the pouches 200 during separation, each intermediate area within the perimeter of cylindrical blades 290 is provided with insulating material in the form of the pads or discs 297. Such insulating pads or discs 297 may be made of silicone or other suitable material and have a durometer of 40 to 80. They may have a radial thickness of ½″ (inch) or more. Notably, insulation layer 288 forming blade drum outer cylindrical contact surface 286 may be made from the same material.
Pads or discs 297 protect the pouches in the area within cylindrical blades 290 from undesired contact with heated metal elements of rotary blade drum assembly 280.
Importantly, these rotary elements are disposed on opposite sides of the travelling web of films 202 and 204 with their respective axis of rotation spaced such to ensure that the distal ends 294 of blades 290 are in registry to fully enter groove 238, but without contact with the drum 220. This relationship, in turn, ensures a clean (sharply defined) perimeter edge 215 of the separated pouches 200.
The uncut sheets of PVA or other film formed with integral completed pouches is carried on the surface 223 of the forming drum 220. The pouches are held within the cavities of the mold configuration 224 and the combined base and lid films 202 and 204 are stretched taut against the smooth outer surface of drum 220 at each perimeter separation land 240 around mold configurations 224 by virtue of vacuum impressed within leading film retention chamber 243 and trailing film retention chambers 244. When the heated blade 290 of rotary blade drum assembly 280 enter the grooves 238, it melts through the film creating clean separation completely surrounding the pouch to form pouch perimeter edge 215.
The distal ends 294 of blades 290 may taper to a relatively sharp edge, about 1/32″ (inch) or so. The shape concentrates the application of heat to the travelling web of adhered films to enhance penetration and formation of a precise edge for the pouch flange.
Notably, film 202 deposited within leading film retention chambers 243 and trailing film retention chambers 244 on generally cylindrical film support surface 223 of rotating drum 220, pass through all pouch processing stations, though no product feed occurs to these cavities. As explained, base film 202 is secured within the leading film retention chamber 243 and trailing film retention chambers 244 by virtue of the vacuum imposed through ports 246 throughout the pouch forming process. This securement of the base film 202 maintains it under tension in overlying relation to perimeter separation land 240 of each mold configuration 224.
Melting of the films 202 and 204 overlying each continuous blade groove 238 by a circular blade 290 occurs without disturbance of film position. Each of the film retention chambers do, however, receive an overlying portion of heated lid film 204 heated at station 340 and wetted at the wetting station 360 and then sealed or adhered to base film 202 at sealing system or station 370. The combined films 202 and 204, thereby, form unfilled or “phantom” pouches disposed in each leading retention chamber cavity 243 and trailing film retention chamber cavity 244, made of the same films, and by the same processing as the product containing pouches 200. On release of vacuum within the leading and trailing retention cavities, these pouches react in the same way (film shrinkage and pouch deformation).
As seen in
On termination of the vacuum to mold configurations 224, separated pouches 200 are deposited onto conveyor 390. The removal of completed pouches 200 from the travelling web of adhered films 202 and 204 results in a web remnant, largely intact, except for pouch-sized apertures corresponding to the shape of the blades 290, in this illustration circular. This PVA remnant is accumulated and disposed of by film disposal system 392, seen in
Turning to
The mold configurations 424 of bars 421 include a continuous perimeter land 430, surrounding a pouch defining cavity. A continuous blade groove 438 surrounds outer perimeter edge 432 of continuous perimeter land 430. A perimeter separation land 440 surrounds each mold configuration 424 and defines the radial width of continuous blade groove 438. The lands 430 and 440, as well as divider lands 429 of each mold configuration 424, define elements of the base forming drum outer generally cylindrical film support surface 423, as in the earlier embodiments. These elements of the mold configuration 424 operate as do the corresponding components described in connection with the embodiment of
Referring to
With the bars assembled to form the base forming drum 420, leading edge 425 of each bar is disposed in facing contact with trailing edge 426 of each adjacent bar. Each such joint may be provided with a vacuum seal or gasket to ensure proper vacuum within the film retention cavity thus formed. As is illustrated in
As in the previously described embodiment, vacuum impressed within the film retention cavities formed by joined portions 443 and 444, draws the base film into the cavities and secures it to the outer generally cylindrical film support surface of base forming drum 420, providing the film securement and stability for pouch separation at the separation station 380 of the form, fill and seal machine.
From this latter embodiment, it can be appreciated that the leading film retention chamber 443 and trailing retention chambers 444 and the long bars forming a base forming drum, can be provided in numerous forms. For example, in the embodiment of
It will be appreciated that the foregoing description provides examples of the disclosed system and technique. However, it is contemplated that other implementations of the disclosure may differ in detail from the foregoing examples. All references to the disclosure or examples thereof are intended to reference the particular example being discussed at that point and are not intended to imply any limitation as to the scope of the disclosure more generally. All language of distinction and disparagement with respect to certain features is intended to indicate a lack of preference for those features, but not to exclude such from the scope of the disclosure entirely unless otherwise indicated.
Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context.
Accordingly, this disclosure includes all modifications and equivalents of the subject matter recited in the claims appended hereto as permitted by applicable law. Moreover, any combination of the above-described elements in all possible variations thereof is encompassed by the disclosure unless otherwise indicated herein or otherwise clearly contradicted by context.
This application claims priority, pursuant to Title 35 U.S.C. § 119(e) to U.S. provisional application Ser. No. 62/979,174, filed Feb. 20, 2020, for “Improvements in Patterned Cut Device and Method,” and U.S. provisional application Ser. No. 63/004,988, filed Apr. 3, 2020, for “Patterned Cut Pouch Forming Machine and Method.” The specification and drawings of the foregoing applications are hereby incorporated herein by reference as if fully set forth.
Number | Date | Country | |
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62979174 | Feb 2020 | US | |
63004988 | Apr 2020 | US |