Patent Publication Number: US-5426917-A

Title: Automated line and method for preparing premade food set-ups

Description:
This is a continuation-in-part of co-pending U.S. patent application, Ser. No. 07/955,092, filed on Oct. 1, 1992, now U.S. Pat. No. 5,299,409. 
    
    
     BACKGROUND AND BRIEF DESCRIPTION OF THE INVENTION 
     The present invention generally relates to automated devices and methods for the preparation of food items and, more specifically, to devices and methods for the automated preparation of layered stacks of one or more food items (hereinafter &#34;set-ups&#34;) such as sandwich meats, hors d&#39;oeuvre servings and the like. The invention provides a method and apparatus for the large-scale preparation of set-ups made with one or more food products. Each set-up is made of layered sliced stacks of food products. The method and apparatus of the invention can make the individual layers of the set-up with more than one type of sliced food item and with the slices arranged in a preferred pattern within a single horizontal plane. Set-ups made by the invention are automatically wrapped in paper and stacked with like set-ups for subsequent packaging and shipment. The invention is particularly useful in the commercial manufacture of sandwich set-ups made with one or more sliced meats or cheeses such as those used in making so-called &#34;sub&#34; sandwiches, for example. 
     The fast food industry has generally enjoyed continued growth in recent years and has seen a sustained demand by consumers for quick and efficient service and good product quality. Improvements in products and services as well as the introduction of new products has been necessary to capture market share and attain a comfortable profit margin in an increasingly competitive industry. Controlling costs, while providing a quality product and service, is a continuing concern within the industry. Food service providers have worked to control costs by controlling the size of the food portions in meal items served to customers. Carefully controlling the amount of meat and other materials used in sandwich set ups, for example, helps to control the overall cost in making and serving various sandwiches. While optimum control over portion sizes would best be achieved using automated machinery with readily reproducible equipment settings, the art has failed to provide such machinery for the manufacture of set-ups to duplicate the arrangement and selection of food items found in hand-made or manually assembled set-ups. 
     In controlling costs, industry generally strives to utilize its work force as efficiently as possible. In the food services industry, the preparation of set-ups has required a rather inefficient use of labor since the manual production of set-ups has typically been labor intensive, often requiring the dedicated attention and efforts of one or more individuals. Automation of a large scale set-up preparation process would allow the food service retailer to obtain premade set-ups, allowing for a more efficient use of labor by freeing individuals from time-intensive manual set-up preparation. In this manner workers would be able to dedicate more time to other important duties such as customer service, for example. 
     The present invention overcomes the shortcomings of the art by providing a mechanized system and method for the automated assembly of set-ups for distribution to individual vendors. The system is an automated assembly-line including a plurality of slicers for slicing meat, cheese and like products and depositing those sliced products onto a conveyor line. Timing mechanisms are provided so that the food items from successive slicers are deposited on the conveyor in close proximity to the slice or slices from preceding food slicers to form a plurality of premade sandwich set-ups, each set-up being composed of a pattern of layered horizontally spaced food slices. The set-ups are stacked and then packaged for shipment to food service retailers for making sandwiches such as &#34;submarine&#34; type sandwiches, hors d&#39;oeuvre servings and the like. 
     The system includes at least one paper roll supply and paper feed system from which a continuous sheet or web of paper is carried down a conveyor line through a plurality of slicer stations. Each slicer station deposits slices of one or more food items onto a conveyed web to thereby form a single layer of horizontally spaced food slices. These slices are then conveyed to the next slicer station where another layer of food slices is deposited on top of the previous layer. As each set-up is conveyed down the conveyer line, each subsequent slicer station adds an additional layer of food to the set-up. The completed set-up is conveyed to a cutting station where the continuous web of paper is automatically cut with a portion of the paper used to cover and protect the set-up. The covered set-up is conveyed to a stacking station and the stacked set-ups are then conveyed to a packaging station where they are packaged for commercial shipment. 
     In an alternate embodiment, at least one additional paper feed assembly is positioned between a pair of slicer stations to provide an additional continuous web of paper separating two layers of sliced food within a set-up. Such an arrangement is preferred in the preparation of set-ups including certain food items such as Roast Beef, for example, which may have a tendency to exchange colors or flavors with other food items within layers in the set-ups. The additional web of paper separates such components from the adjoining layers of the set-up to preserve the original colors and flavors of the food and thereby maintain the integrity of the completed set-up. 
     It is an object of the present invention to provide an apparatus and method for the automated manufacture of premade food set-ups. 
     It is another object of the present invention to provide an apparatus for the assembly of premade food set-ups wherein the apparatus includes a plurality of slicers which are arranged and timed to deposit sliced food product onto a conveyor at predetermined intervals to thereby assemble predetermined arrangements of food product to form a finished set-up. 
     It is still another object of the present invention to provide means for automatically stacking and packaging the premade set-ups once they have been assembled. 
     These and other objects of the present invention will become more apparent to those skilled in the art upon consideration of the remainder of the disclosure including the drawings, the detailed description of the preferred embodiment and the claims. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a top plan view of an apparatus for the assembly of premade food set-ups according to the present invention. 
     FIG. 2 is a side elevational view of an apparatus for the assembly of premade food set-ups, according to the present invention. 
     FIG. 3 is a top plan view, in schematic, illustrating the assembly of a set-up. 
     FIG. 4 is another top plan view, in schematic, showing the assembly of a set-up in six stages. 
     FIG. 5 is a perspective view of a slicer used in the apparatus of the present invention. 
     FIG. 6 is a front elevational view of a paper cutter/wrapper star;ion for use in the present invention. 
     FIG. 7 is a top plan view, in section, of the cutter/wrapper station of FIG. 6. 
     FIG. 8 is a side elevational view, in section, of the cutter/wrapper station of FIGS. 6 and 7 and illustrating the wrapper folding components thereof. 
     FIG. 9 is a top plan view of an apparatus for the assembly of premade food set-ups according to another embodiment of the present invention. 
     FIG. 10 is a side elevational view of the apparatus shown in FIG. 9. 
     FIG. 11 is a side elevational view of a slicer assembly and a second paper feed assembly of the apparatus of FIG. 9 
     FIG. 12 is an end view of the paper feed assembly of FIG. 11. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The present invention provides a mechanized system and a method for the large scale production of set-ups by utilizing a plurality of slicer stations positioned along a conveyor line to deposit a patterned array of layered food slices onto the conveyor, each successive slicer depositing a new patterned layer onto the layer deposited by the preceding slicer. In describing the preferred embodiment of the system and method, reference will be made to the various figures wherein like reference numerals indicate like components. 
     Referring now to the various figures, FIG. 1 illustrates the mechanized system 10 for the automated assembly of food set-ups in accordance with the present invention. The system 10, shown in schematic in FIG. 1, includes a paper supply 12 to supply a continuous sheet or web of paper 13 to a conveyor assembly including a conveyor 14 which extends down through a plurality of slicer stations 16-26. Each slicer station, as discussed below, deposits a layer of one or more food slices onto the paper 13 as it progresses downstream on conveyor 14. In this manner, a set-up is assembled in the form of several layers of food slices wherein each layer is composed of horizontally spaced slices arranged in a predetermined pattern. It will be appreciated that the number of slicer stations in the system 10 can be varied to include any number of two or more stations. The six stations 16-26 in the preferred embodiment has been most useful in the preparation of set-ups for &#34;sub&#34; sandwiches and the like. 
     The conveyor 14 transports each set-up to a cutter/wrapper station 28. The cutter/wrapper station is equipped with a paper cutter to slice the continuous sheet 13 to predetermined lengths with each such length being sufficient to hold one set-up thereon and including a flap of excess paper. Preferably, the flap is long enough to be folded back over the set-up so that the set-ups can subsequently be stacked with the folded paper separating the individual set-ups and providing a means for the sanitary handling of individual set-ups such as when a set-up is eventually included in a sandwich, for example. The system 10 includes a wrapper assembly to fold excess paper 13 over each of the set-ups to thereby wrap the set-up prior to stacking. A stacker station 30 stacks the wrapped set-ups and conveys them on to a checkweigher 32 and from the checkweigher to a packaging station 34 where the set-ups are packaged for commercial shipment. 
     As mentioned, the system 10 is provided with a plurality of slicer stations to provide the desired number of different layers of food slices in the assembled set-ups. Each of the slicer stations are preferably equipped to deposit more than one food slice onto the paper 13 as it is conveyed by conveyor 14. Consequently, each slicer may be equipped to provide slices of one or more different types of meat, cheese and the like. 
     As shown in FIG. 2, the paper supply 12 is a paper roll stand accommodating a feed roll 36 and a spare roll 38 to facilitate changing paper supplies when the feed roll 36 is spent. In the preferred embodiment, the paper supply 12 is a combined splicer and paper roll stand unit, capable of automatically splicing in a new roll of paper at the end of the roll in service. Commercially available units, like those available from Serco USA, are adequate. The paper 13 is fed from the feed roller 36 onto the conveyor 14 through a paper guide roller 40 and a paper feeder 42, including nip rollers 44 for guiding the paper 13 onto the conveyor line 14. The paper 13 proceeds from the paper feeder 42 through nip rollers 44 down the conveyor line 14 and through the slicer stations 16-26. 
     Beginning with the first slicer station 16, each food set-up is assembled by compiling multiple layers of food slices to include a variety of foods such as various meats, cheeses or combinations thereof and the like. Each of the slicer stations is preferably capable of depositing more than one slice onto the paper 13. In this manner, each slicer station in the system 10 can deposit a separate layer of horizontally spaced food slices on the paper web 13, thereby building layers of food slices as the set-up advances downstream on the conveyor 14 through the individual slicer station 16-26. 
     With particular reference to FIG. 3, a single set-up 46 is shown in various degrees of assembly. The first layer 48 of food slices are deposited on the paper 13 by first slicer station 16. As shown, the multiple food slices of the first layer 48 are deposited by the slicer station 16 onto the paper 13 in a horizontally spaced relationship. As the web 13 is carried downstream, the first layer 48 is similarly advanced and is conveyed through the second slicer station 18 where the second layer of food 50 is deposited onto the paper 13 and over the first layer 48. Most preferably, the slicer stations and the conveyor 14 are appropriately synchronized so that the second layer 50 lays directly on top of the first layer. Like the first layer 48, the second layer 50 includes horizontally spaced food slices which lie approximately within a single horizontal plane. As the set-up is conveyed further through the system 10, a third layer of food 52 is deposited thereon by slicer station 20 and is again deposited in a horizontally spaced relationship. In the embodiment herein, the third layer 52 consists of two slices of food. The next slicer station 22 similarly deposits the fourth layer 54 of food slices onto the set-up and subsequent slicer stations 24, 26 similarly deposit additional layers of food slices 56 and 58, respectively. 
     For illustrative purposes, FIG. 4 shows a somewhat different arrangement of food slices in a second set-up composed of a variety of food. Again, the first layer 60 is deposited by slicer station 16 and the subsequent layers of food slices 62, 64, 66, 68, and 70 are similarly deposited by slicer stations 18, 20, 22, 24 and 26, respectively. It will be understood that FIGS. 3 and 4 provide only two examples of many possible set-up arrangements. Those skilled in the art will understand that various different arrangements of food placement onto the paper 13 are possible, limited only by the selection of food items and the capacity of the slicers stations 16-26. The slicers are preferably capable of depositing more than one food item onto the paper 13 and the number of items which can be deposited by each of the individual slicers is limited by the capacity of the slicer as well as the size of the food casings, as discussed below. 
     Regarding the individual slicer stations, each station is preferably equipped with an assembly 72, as shown in FIG. 5. The assembly 72 is mounted over the conveyor assembly 14 and the paper 13 conveyed thereon. The assembly 72 is of known construction, and commercial slicers such as those available from J. E. Grote Pepp-A-Matic Co., Inc. of Columbus, Ohio are suitable. As shown one or more moveable canisters 74 each receive an elongated cylinder or log of food product 76 such as cheese, meat and the like. Each of the log 76 is vertically oriented and held within a canister 74. The canisters 74 are supported by a frame assembly 78 which is also equipped with a tray 80 to support the uppermost portions of the food products 76 as well as providing an area for the temporary storage of refill food products. 
     The frame assembly 78 supports the canisters 74 to allow the bottoms thereof to simultaneously move above a slicer blade 82 positioned beneath the canister in a closely spaced relation thereto. Each log 76 projects slightly beneath the bottom of its canister 74 to allow the blade 82 to slice the food product and to have the food slices fall onto the paper web 13 in a predetermined pattern. As shown, the blade 82 provides a constant cutting motion to the food products by rotation around a pair of blade pulleys 83 and driven by motor 81 at a constant and predetermined rate of speed. In this manner, the blade 82 operates like a band saw, providing a cutting surface to quickly and easily slice through a plurality of food logs 76 within the canisters 74. 
     The canisters 74 are driven by an oscillating cable drive which is powered by the line shaft 86 or the like by the operation of a drive assembly. The line shaft 86 rotates at a constant velocity, preferably about 900 rpm, to drive the conveyor assembly 14 in a known manner at a velocity of about 27 inches per second. The line shaft 86 also drives the drive assembly preferably through a conventional cable and pulley connection to a gear box 79 to reduce the rotational drive of line shaft 86 from about 900 rpm to about 600 rpm. The drive assembly 88 directs the rotational input from the line shaft 86 and the aforementioned gear box through phaser 89 and an air clutch 91 to an oscillator 90 which operates in a known manner to convert the constant rotational input to an oscillating output. The rotational input into oscillator 90 from the air clutch 91 is preferably about 150 rpm which is translated into an oscillating motion of about 21.52 degrees, through oscillator 90, to a cable pulley 93 which is associated with an overload clutch (not shown). Cable 84 is reeved around an oscillating drive pulley 93 and the large diameter driven pulley 95. The drive pulley 93 is driven by oscillator 90 at an appropriate rate of oscillation. A smaller diameter cable pulley 97 is associated with the driven pulley 95 to drive the cable pulley 100 with associated cable 101. 
     Through the aforementioned arrangement of parts, the cable drive 84 drives a linkage assembly 92 and, the linkage assembly 92 moves the canisters 74 across the slicer blade 82 with a velocity of about 150 oscillations per minute to cut and place a food slice precisely onto the partially assembled set-up from the preceding slicer station, supplying about 150 set-ups per minute. 
     The linkage assembly 92, shown in FIG. 5, includes tierods 94, each of which is secured at one end to the carrier 74 and at its other end to a lever arm 96. Each lever arm 96 is secured to a rotatably mounted shaft 98. The cable pulley 100 is mounted on the rotatably mounted shaft 98 at one end thereof and, transmits the oscillating motion from the oscillator 90 to the shaft 98. 
     To assure synchronized operation of the various slicer stations, each station is preferably driven from a single drive assembly which can include a motor 106 to drive a common drive unit such as the line shaft 86. Phasers and reducers are preferably included within the drive chain as discussed to achieve desired timing and sequencing of the particular slicer stations. 
     Once assembled by the slicer stations, each set-up is conveyed to the cutter/wrapper station 28 which, with some modification, is of a design known to those in the art. The cutter/wrapper station 28 cuts the web 13 in front of the set-up, leaving a flap 124 (FIG. 8) of paper to extend forwardly beyond the set-up. As described below, the station 28 includes a wrapper portion which wraps the forward flap back over the set-up for the stacking and subsequent handling thereof. 
     The cutter/wrapper station 28 includes a knife assembly 108 having a cutting blade 110 and a perforating blade 111 mounted on a top plate 112. The portion of the conveyor extending through the cutter/wrapper station and beneath the knife assembly 108 is separate from the portion of the conveyor 14 extending through slicer stations 16-26. Through the cutter/wrapper station 28, set-ups are conveyed on a conveyor portion having a plurality of urethane belts 116 which are reeved around a drive roller 120 and a series of idler rollers in a known manner and driven by the drive assembly 106 and the line shaft 86 so that the speed of the belts 116 is substantially the same as the speed for the conveyor 14 extending through the slicer station 16-26. The belts 116 extend under the knife assembly 108 through slots 113 in a bottom plate 114. The slots 113 provide each of the belts 116 with a recessed track to protect the belts from the guillotine action of the knife assembly 108 and the consequent undesired slicing of the belts 116. 
     The knife assembly 108 cuts and scores the paper web 13 and is synchronously driven by the line shaft 86 to operate in concert with the belts 116 as well as the slicer station 16-26. In this manner, the cutting blade 110 first cuts the web 13 in front of each set-up before the set-up has passed under the cutting blade, leaving a leading flap 124 in front of the set-up. Preferably, the length of the flap 124 will roughly correspond with the length of the set-up, as measured along the longitudinal axis of the conveyor 14. Preferably, this length will be between about 4 and about 8 inches and, most preferably, between about 5 and about 6 inches and roughly corresponding to the length between the cutting blade 110 and the perforating blade 111. 
     Following the initial cut of the web 13, the knife assembly 108 is raised and the web and set-up continue to advance along the conveyor belts 116, next passing underneath the knife assembly 108. Once the set-up has passed the vertical plane of the cutting blade 110 so that the set-up is approximately centered between the cutting blade and the perforating blade 111, the knife assembly 108 will again descend so that the cutting blade 110 cuts the web 13 a second time directly behind the set-up thereby separating that set-up from the other set-ups still being conveyed through the slicer stations 16-26. The perforating blade 111 simultaneously scores the paper in front of the leading edge of the set-up to provide a folding line for the flap 124. 
     While the knife assembly 108 is still in its lowered position, the flap 124 is positioned over an air supply 122 extending beneath the belts 116 and supplying an upwardly directed stream of air from a series of individual openings 126 between the belts 116. The stream of air from the openings 126 of air supply 122 lifts the flap 124 while the perforating knife 111 is still applying pressure on the web 13. A series of proximity switches 127 (FIG. 6) are provided to control the air supply 122, cycling the air supply on while the flap 124 is positioned over the openings 126 and cycling off again before the set-up passes over the openings 126. In this manner, the upwardly directed stream of air will raise the flap 124 but provides no lifting force underneath the individual set-ups, thereby avoiding any alteration of the orientation of the set-ups as they are conveyed along the urethane belts 116. Use of the proximity switches 127 to cycle the air supply is accomplished in a known manner. In this arrangement, the air supply will lift the flap 124 from its horizontal orientation on the belts 116 to a vertically inclined position above the plane of the conveyor belts. The flap 124 is vertically inclined from the score line created by the perforating knife 111 to its leading edge, substantially as shown in phantom in FIG. 8. 
     With the flap 124 raised and the air supply cycled off, the set-up and flap 124 are advanced along the belts 116 to the folding roller 128 including a belt 130 conveyed around rollers 132. The folding roller 128 is positioned over the urethane belts 116 leaving sufficient space therebetween to allow the set-up to pass under the roller 128 and onto the stacker assembly 30. The speed of the folding roller 128 is synchronized with that of the belts 116. In the view shown in FIG. 8, the belt 130 is driven around the rollers 132 in a counterclockwise rotation. In this manner, the vertically inclined flap 124 encounters the belt 130 and, as the set-up advances along the belts 116, the flap 124 is folded over the set-up by the belt 130 to cover the set-up and thereby provide separation between the individual set-ups when stacked at stacker station 30 and, perhaps more importantly, to also provide a means for the sanitary handling of the individual set-ups when they are subsequently included in sandwiches by a food service retailer, for example. 
     The folded set-ups are conveyed to the stacker station 30 and on to the checkweigher 32 and the packaging station 34 for packaging of the set-ups for commercial shipment thereof. The checkweigher 32 and packaging assembly 34 are commercially available and well known to those skilled in the art. Both the cutter/wrapper station 28 and the stacker assembly 30 are driven by the line shaft 86, cycling on at any time the line shaft is turning. Preferably, the stacker assembly 30 is equipped with a reject system of a known design. A diverter system is preferably provided opposite the reject unit and is used to shift between two stackers. The stacker assembly used in the system of the present invention includes a photosensor control (not shown) wherein a photosensor eye is used to actuate the reject system along with a reject button. A second set of photosensors is located at the diverter to count set-ups and a third set of photosensors is located in front of the stacker shelves and used to move the shelf down at the correct time. 
     Referring now to FIGS. 9 through 12, a second or alternate preferred embodiment of the invention is shown. In describing this embodiment, it will be understood that components having the same reference numerals as those components previously described in the above discussion of the embodiment of FIGS. 1 through 8 are identical and will not be described further. Only the differences between the two embodiments will now be described. 
     As shown in FIGS. 9 and 10, for example, the system 210 includes a second paper supply or paper unwind/splicer station 212 positioned behind or adjacent to the paper supply 12 previously discussed. The paper supply 212 may be identical to the first paper supply 12, and includes a feed roll 236 and a spare roll 238 to supply a continuous second web 213 of paper, as is discussed below. Those skilled in the art will appreciate that the invention is not limited to any specific paper supply apparatus and, the two aforementioned paper supply units 12 and 212 need not be identical. Additionally, the relative placement of the paper supplies 12, 212 within the set-up line 210 is a design consideration and is not intended to limit the scope of this invention. 
     The second paper supply 212 supplies the continuous web of paper 213 to an overhead assembly, generally designated 214, and then to an in-line paper feed assembly 216. The overhead assembly 214 provides a means to guide the web 213 above the first paper supply 12 and one or more of the slicer stations. The in-line paper feed assembly 216 can be positioned between slicer stations 18 and 20, as shown in FIGS. 9 and 10. The overhead assembly 24 conveys the second web 213 over the first two slicer station 16 and 18 to the in-line assembly 216. The overhead assembly 214 includes supports or hangers 218, 220 and 222. An idler roller 224 is associated with the support 218 to receive the web 213 from the paper supply 212. The other hangers 220 and 222 include horizontally disposed support rods or cylinders 226 and 228 to further support the web 213. The web 213 rides over and is supported by the guide roller 224 and the rods 226 and 228 and is then pulled to the in-line paper feed assembly 216. 
     The in-line assembly 216 receives the web 213 from the overhead assembly 214 at its uppermost portion above the conveyor 14. An idler roller 230 is positioned on the uppermost portion of the frame 232 to receive the web 213 from the overhead assembly 214 and to direct the web downward and toward the partially assembled set-ups being conveyed along the conveyor 14. The roller 230 is placed at the uppermost portion of the frame 232 to maintain the web 213 substantially within the single horizontal plane established across the overhead assembly 24 as shown in FIGS. 10 and 11. After its downward turn at roller 230, the web 213 is reeved around the guide rollers 234, 236 and 238 and then inserted between feed rollers 240 and 242. The feed rollers 240 and 242 are shown to have different cross-sectional diameters and the larger diameter feed roller 242 is driven by the line shaft 86, as discussed below. The second feed roller 240 is a slave roller mounted to an arm 241 and held snugly against the driven roller 242 by the compression spring 243 affixed to the arm 241 and bracket 245. The roller 240 is preferably a bearing roller with a soft surface made of a suitable rubber or elastomer to help grip the web 213 as it is pulled through the rollers 240, 242 and then directed to the rod 247. The bracket 245 and the arm 241 are pivotally connected along a rod or shaft 249 and around a bearing 251. The shaft 249 is, in turn, affixed to the support plate 253. The assembly, including the bracket 245, arm 241 and roller 240 may be positioned at one end of the driven roller 242 with an identical assembly (not shown) disposed at the other end of the roller 242 and along the shaft 249. 
     The feed rollers 240 and 242 pull the second web 213 through the overhead assembly 214 and down through the in-line assembly 216. From the rod 247 the web 213 is deposited onto the conveyor 14 and over the partially made set-ups being conveyed therealong. Each set-up is than conveyed to the next slicer station 20 where an additional layer of food slices are deposited onto the web 213 and directly over the previously deposited layer. In this manner, the second web of paper 213 is positioned between two of the layers in the partially assembled set-up being conveyed along the conveyor 14. In the configuration depicted in FIGS. 9 and 10, for example, the web 213 would be positioned between the second and third layers in a set-up. Using the example in FIG. 3, the additional web would separate the second layer 50 from the third layer 52 within the set-up 46, for example. The use of an additional web 213 is especially useful in those set-ups which include roast beef as a component since roast beef has a tendency to exchange color and flavor components with other food items if not separated. 
     The in-line paper feed assembly 216 is driven by the line shaft 86. As shown in FIG. 11 and 12, the line shaft 86 is connected by a conventional cable/pulley arrangement to a 2 to 1 right angle gear box 244 which is a commercially available unit. The cable 257 connects the drive shaft 86 and the gear box 244 with the cable passing over a sprocket shaft 259. The preferred rate of rotation for the line shaft 86 is about 900 rpm and the gear box 244 preferably provides a reduced rotation from the 900 rpm of the drive shaft 86 to about 225 rpm for the pulley 246. The gear box 244 is, in turn, connected to a drive sprocket or pulley 250 through cable 248. Drive tensioner 261 may be provided to adjust the tension of the cable 248. 
     The drive pulley 250 is drivingly connected to the drive roller 242 through a clutch 263 and an axle 265A, 265B. The clutch 263 and sensor 267 (FIG. 11) are operatively connected and, together, serve to adjust the speed of the drive roller 242 to control the rate at which the web 213 is fed to the conveyor 14. The sensor 267 is electronically connected to the clutch 263 in a known manner and both the clutch and the sensor as well as the associated electronics are commercially available. The sensor 267 is preferably an ultrasonic device which monitors the degree to which the web 213 is bowed along portion 213A which spans the space between the feed roller 240 and the rod 247. As noted above, the web 213 is taken up by the conveyor 14 after it passes over the rod 247. When the conveyor slows down for some reason, the speed at which the web 213 is fed onto the conveyor must be adjusted to compensate for the change in the speed of the conveyor 14. The sensor 267 first detects the degree to which the portion or &#34;belly&#34; 213A of the web 213 is bowed. A certain amount of bow is normal and no adjustment to the speed of the feed roller 242 is required. If, however, the conveyor is slowed down for some reason, the belly 213A becomes more pronounced and this is detected by the sensor 267. The sensor 267 then relays an electronic signal to the clutch 263 which is activated to slow down the drive roller 242 enough to compensate for the change in the speed of the conveyor 14. The clutch 263 is subsequently disengaged when the sensor 267 detects that the belly 213A has regained an accepted or normal configuration. 
     An additional sensor/controller unit 269 is provided to adjust the position of the web 213 within the idler and feed rollers of the in-line assembly 216. The unit 269 is a commercially available unit and is operatively associated with idler roller 234. The position of the web 213 on the roller 234 is monitored by a photosensor within the sensor/controller unit 269. When the web 213 comes out of a centered position or alignment on the roller 234, the sensor detects the misalignment and activates a motor to adjust the web 213 by adjusting slightly the horizontal axis of the roller 234 to thereby center the web 213 on the roller. 
     The sensor/controller unit 269 and the clutch 263 and ultrasonic sensor 267 control both the speed at which the web 213 is fed onto the conveyor 14 as well as the relative position of the web 213 on the rollers of the in-line assembly 216. In this manner, the web 213 is maintained in a proper position along the conveyor 14 to effectively separate at least two layers within the partially assembled set-ups being conveyed from the slicer station 18. 
     It will be understood that the configuration and arrangement of parts generally depicted in FIGS. 9 and 10 is not limiting and that the various parts discussed above can be re-arranged. The in-line assembly 216, for example, can be positioned wherever needed within the set-up line 210. Likewise, the paper supply 212 can be positioned elsewhere and, other components may be added to the line along with the various components discussed herein. While the preferred embodiments of the invention have been described along with a preferred method for the automated formation of set-ups, those skilled in the art will understand that the described embodiment can be modified by those skilled in the art without departing from the true spirit and scope of the invention, as defined in the following claims.