1. Field of the Invention
The present invention is concerned with improved apparatus and methods for the commercial-scale production of elongated cooked food items such as hot dogs, corn dogs and sausages, e.g., Vienna sausages, without the use of casings. More particularly, the invention is directed to such devices and methods wherein automated injector heads coupled with a supply of meat emulsion create successive, predetermined weight portions or charges of emulsion which are then partially or completely cooked in elongated heat exchange cooking tubes. The equipment is preferably designed so that the products are statically heated using a plurality of tubes so as to achieve a batch-continuous operation. Advantageously, the equipment provides a plurality of cooking tube arrays, and delivers meat emulsion to at least one tube array while also removing cooked product from a second array and applying oil to a third array.
2. Description of the Prior Art
Presently, elongated cooked meat products such as hotdogs, the inner meat portions of corn dogs, and Vienna sausages are produced using casings. Generally speaking, a starting meat emulsion is pumped into a casing, and the casing is twisted in order to initially form the product, followed by cooking and/or smoking to fully cook and gelatinize the protein in the emulsion. The product is chilled and the casing is stripped from the cooked product and is discarded. Such use of casing represents a very significant cost to the food processors. Indeed, many large scale plants purchase several million dollars worth of casings per year.
Attempts have been made in the past to process these meat products without the use of casings. However, these efforts have not met with any significant commercial acceptance. The principal difficulty with these prior devices has been that the products are not equivalent to the typical products made with casings. For example, the products may not have the same shape, color, or texture as the conventional counterparts, and are thus unacceptable to consumers.
U.S. Pat. No. 4,113,890 to Long describes a continuous stuffing machine 30 that feeds a tube 32 which injects emulsion into a coil 10 that is covered by a jacket 12. A heat transfer medium, such as steam or hot water, flows through the jacket in a direction opposite to the flow of the emulsion through the coil 10. Metal-core plugs 36 are also inserted into the coil 10 automatically by a loader 62. The loader 62 has two similar chambers 72, 74 that rotate about a central axis 70 that is connected to a gear 64, which may be driven by an external motor. One chamber 74 accepts (by the use of a hydraulic ram 78) a plug 36 from a supply line 60, while at nearly the same time, the other chamber 72 injects (by the use of a hydraulic ram 76) a plug 36 into a feed line 10c. The chambers 72, 74 rotate and perform reciprocal tasks in repeated fashion. The plugs 36 and the partially-cooked hot dogs exit the coil 10 onto conveyor 52, where the plugs 36 are separated by a magnetic roller 54 from the hot dogs which continue on conveyor 56. The plugs 36 are dropped into a receptacle 58.
U.S. Pat. No. 3,502,018 discloses a system for fully cooking sausages without casings. The system includes a staffer 14 that forces meat emulsion into a tube which extends through multiple stages 10, 11, 12 of heating. Cooked sausage exits the tube 16 and is carried on a belt 26 through a cooling chamber 13. Cooled sausage exits the cooling chamber 13 and may be cut by blade 32 before being transported by conveyor 36.
U.S. Pat. No. 3,889,013 discloses a system for preparing frankfurters or sausages by creating a casing from the meat product itself. The system includes a supply tank 2 that supplies the meat product to a metering pump 6 which delivers pressurized meat product to a heating unit 8. The meat product is heated in a cylindrical mold 20 to cook the outer surface of the meat product so that it forms a casing. The meat product is then cooled by the cooling unit 10.
See also U.S. Pat. Nos. 2,182,211, 3,421,434, 4,726,093, 4,989,505, 5,056,425, 5,118,519, 6,203,832, 6,322,832, and 6,326,039.
Notwithstanding these efforts, no commercially successful has heretofore been devised which is capable of properly cooking sausage-type products without casings and while retaining the appearance, taste, and mouth feel of traditional products.
There is accordingly a real and unsatisfied need in the art for improved methods and apparatus capable of producing elongated, partially or fully cooked meat products such as hotdogs or sausages without the use of casings, while still providing finished products equivalent in all respects to conventional products of these types made using casings.
The present invention overcomes the problems outlined above and provides greatly improved methods and apparatus for the production of elongated comestible products, and especially sausage-type products such as hot dogs, without the need for disposable casings. Thus, the invention entirely eliminates the costly expedient of using disposable casings, which greatly minimizes production costs. Moreover, the invention is characterized by reduced energy consumption owing to the use of conduction cooking, reduced labor costs, and improved food safety. The system of the invention also discharges product in an organized fashion wherein the products are oriented end-to-end in straight lines, which facilitates downstream product management.
Generally speaking, the apparatus of the invention includes a plurality of elongated, separate, individual cooking tubes, each presenting a longitudinal axis and an inlet end. A loading station is provided which includes structure operable to load comestible material (e.g., meat emulsion) into the inlets of the tubes. Shifting mechanism is also provided which is operable to shift the tubes in a first direction transverse to the longitudinal axes thereof and into the loading station for successive loading. The shifting movement may be of any suitable type, such as circular or reciprocal. The overall apparatus further has a cooking arrangement to at least partially cook the comestible material within the tubes, as well as a discharge station separate from the loading station and including discharge structure for discharge of the at least partially cooked material from the cooking tubes. To this end, the shifting mechanism is also operable to successively shift the tubes containing the at least partially cooked comestible material in a second direction also transverse to the longitudinal axes and into the discharge station.
Preferably, the cooking tubes have open inlet and outlet ends and are arranged in a circular pattern with the tubes substantially parallel with each other and in circumferentially spaced apart relationship. In this embodiment, the tubes are incrementally moved in the same direction (i.e., either clockwise or counterclockwise) into and out of the loading and discharge stations during rotation of the tube pattern. Advantageously, and in order to increase production capacity, an array of radially spaced apart tubes are provided at each circumferentially spaced apart tube position, and the loading and discharge stations are appropriately equipped to simultaneously load and discharge plural tubes. The arrays may have tubes of different diameters, so that differentially sized products may be produced on the same machine. In such an arrangement, the tubes are located within a cylindrical, axially rotatable, water-tight housing, and energy exchange media (e.g., heated water and/or steam) surrounds the tubes for cooking of the comestible material within the tubes during tube rotation.
In order to create properly formed hot dog and related products, the loading station includes structure for successively introducing forming plugs into the tubes between successive portions of the comestible material. Thus, at the loading station, each cooking tube is filled with individual portions of material with a plug on either end of and in engagement with the portion. In such operations, the discharge station is equipped with specialized apparatus for recovery of the plugs as they are discharged, in order to return the plugs to the loading station for reuse. A particularly useful feature is that the plug recovery apparatus maintains the plugs in a substantially parallel alignment with the longitudinal axes of the tubes throughout the recovery sequence. Thus, the tubes are handled in the most efficient manner and without the need for manual manipulation thereof.
The loading station of the system of the invention preferably includes an improved apparatus for loading of the cooking tubes with both portions of comestible material and forming plugs. This apparatus broadly includes a magazine operable to hold a plurality of the elongated plugs and to individually deliver the plugs to a plug delivery location. An elongated, axially shiftable plug seating rod is adjacent the magazine and is oriented to engage and move successive plugs from the plug delivery location. An elongated, axially rotatable plug and meat injection rod is provided, which is spaced from the seating rod and is located proximal to the tube inlet end, with the longitudinal axis of the injection rod being substantially coaxial with the tube longitudinal axis. The apparatus also has a portioning assembly spaced from both of the rods and includes structure for successively forming and delivering individual portions of the comestible material, as well as an input for the comestible material.
A shiftable plate is located between the injection rod and the cooking tube open end and has a plug seating and injection bore, a material conveying bore, and a material delivery bore. Shifting mechanism is coupled with the plate for selective shifting thereof between a first position wherein the seating and injection bore is aligned with the seating rod, and the material delivery bore communicates the portioning assembly with the tube inlet, and a second position wherein the seating and injection bore is aligned with the injection rod and the tube inlet, and the material conveying bore communicates the input and the portioning assembly. An operating mechanism is coupled with the plate shifting mechanism, the seating rod, the injecting rod, and the portioning assembly. This serves to shift the plate to the first position thereof and to cause (a) shifting of the seating rod to shift a plug from the plug delivery location and into the seating and injection bore of the plate, and (b) to operate the portioning assembly in order to deliver a portion of the material to the tube inlet. The operating mechanism also subsequently shifts the plate to the second position thereof and causes (c) shifting of the injection rod to shift the seated plug from the seating and injection bore and into the tube through the tube inlet, and (d) to operate the portioning assembly to create a portion of the material for subsequent delivery to the cooking tube behind the injected plug.
The preferred systems of the invention are provided with an output conveyor for finished product also having a spray assembly for the application of liquids to the cooked 20 products, in order to increase the palatability thereof, and to facilitate downstream additional processing or packaging. A plug recovery assembly is also provided in order to recover plugs from the output conveyor and to direct these plugs for reuse; if desired, the plugs may be washed during recovery thereof.
An additional feature of the invention is the provision of a plug storage assembly, which is an adjunct of the plug recovery assembly. The storage assembly is operable to create accumulated rows of plugs from the discharge station and to successively move such rows onto a receiving rack.
In another aspect of the invention, apparatus for the production of at least partially treated, elongated comestible products without the use of casings includes a stationary enclosure defining at least one heat exchange zone. A plurality of elongated, generally horizontally oriented heat exchange tubes operable to receive comestible materials are supported in generally aligned, spaced apart relationship using mechanism operable to selectively shift the tubes into and through the heat exchange zone(s) of the enclosure. A heat exchange assembly is provided for applying heat exchange media to the exteriors of the tubes within the zone(s) to thereby treat (e.g., at least partially cook) the material within the tubes by alteration of the temperature thereof. A loading assembly operable to individually load the tubes with comestible material at a loading station is also provided, together with a discharge assembly operable to discharge the treated material at a discharge station.
Turning now to the drawings, a processing system 50 is illustrated in
In more detail, the cooking drum assembly 56 includes an elongated, axially rotatable, cylindrical housing 70 supported on a frame assembly 72. The latter has upright corner posts 74 with interconnecting lateral frame members 76, 78 and a pair of upright central posts 80 at each end of the frame assembly. The housing 70 comprises an outer wall 71, an inner wall 84, with end spacers 105 (see
Internally, the assembly 56 has a plurality of radially extending, circumferentially spaced apart tube arrays 92. Each such array is made up of two smaller diameter cooking tubes 94 and two larger diameter cooking tubes 96. Each tube has an inlet end presenting an inwardly extending, plug-retaining shoulder 97 (see
A stationary steam injection assembly 112 is positioned within housing 70 and includes a steam injection pipe 114 extending through the forward portion of mounting member 104 and terminating in an injection manifold 116 (
The ends of the housing 70 are defined by solid, apertured fore and aft bulkheads 99a and 99b, which have the identical pattern of apertures of the corresponding plates 98, 100 (see FIGS. 2 and 12-14). The bulkheads also have a solid section 124 inboard of the arrays 92, equipped with central nylon bearings engaging the bearing surfaces 106, 108. The bulkheads 99a, 99b are secured to housing 70 by means of threaded fasteners extending through the bulkhead margins and coupled with internal spacer rings 105.
Referring to
Referring now to exemplary cooking
Referring to
Referring to
The control panel 60 is secured between the upper and lower crosspieces 160, 162 by means of standoff connectors 178. The control panel 60 is itself conventional, and includes the usual digital control components for system 50. It also receives inputs from the sensors described below.
Referring to
In order to provide enhanced automated control, the channels 210, 212 are each provided with upper and lower proximity sensors 210a, 210b. These sensors are operable to sense the presence of plugs 208 within the respective channels, and to monitor the plug output through the lower outlet passageway structures 215.
The preferred forming plugs 208 are illustrated in
The plate 228 is shiftable fore and aft by means of four pancake cylinders 244, each having and extendable rod 246. The position of the pancake cylinders 244 is monitored by way of proximity sensors 245 (
The plate 228 has two lower meat emulsion delivery openings 262 there through, as well as a pair of plug and meat injection openings 264. The openings 264 are designed to receive tubular delivery elements 265, each having a beveled outlet end 265a equipped with a sealing ring 265b (see
The rods 256 support a pair of upright plates 270, 272. Plate 270 includes a pair of vertical, apertured spacers 274, and also has a series of openings through the plate between the spacers 274. In particular, the plate 270 has a pair of plug and meat emulsion injection openings 276, a lower pair of meat emulsion delivery openings 278, each equipped with a stationary, tubular, projecting fitting 279, and a pair of vacuum openings 280, which receive the fittings 268. It will be observed (
The plate 272 has a pair of upper plug-receiving openings 286 equipped with entry ferrules 288, and a pair of lower meat emulsion conveying openings 290 with tubular beveled inserts 292 therein. The plate 272 also has a pair of injector rod openings 294 between the openings 286 and 290, and a pair of vacuum openings 296 equipped with vacuum fittings 298. The vacuum openings 296 communicate with the opposite face of plate 272. The face of plate 272 remote from plate 270 is provided with attachment screws 304, 306 to permit attachment of actuating cylinder structure, as described below.
A pair of plug injection seating rods 348 are located in registry with the openings 215a and are supported by a crosspiece 350. A small pneumatic actuating cylinder 352 having extensible rod 354 is secured to crosspiece 350 in order to simultaneously move the rods 348. Cylinder 352 is supported on an elongated bracket 356 secured to plate 272.
As best viewed in
The assembly 282 also has a meat emulsion delivery unit 358 operable to deliver meat emulsion from a pressurized source to the system 50. Preferably, the meat emulsion is generated by a Marlen twin piston pump, although any suitable food pump may be used. The unit 358 includes a primary emulsion conduit 360 with an upstanding delivery pipe 362 (
The ejection assembly 63 includes a water block 372 having a pair of water inlets 374 and a corresponding pair of tubular water outlets 376. Each outlet 376 is equipped with an o-ring seal 378 (
Referring to
A trough 432 extends the full length of conveyor 64 below the lower run of belt 384 and has three section sections: a first water collection section adjacent the forward end of the frame 382; a second vinegar collection section separated from the first section by a baffle plate; and third section separated from the second section by another baffle plate and terminating at an open end adjacent output end 390 of the conveyor. The first water collection section of the trough 432 has an oblique discharge outlet 434. The outlet 434 is typically equipped with a discharge hose or similar device for water disposal purposes. The second vinegar collection section also has an outlet similar to the outlet 434.
The block 404 and tubes 412-418 are shiftable between a standby position (
The plug recovery assembly 66 includes a driven wire belt 438 having an inclined stretch and a horizontal stretch. The belt 438 is trained about a lower roller 440 and a mating upper roller (not shown). The roller 440 has a magnetic core serving to magnetically pick up the plugs 208 as they travel along the length of belt 438 after exiting mechanism 402, and thus separates the plugs from the finished product. The plugs are then conveyed upwardly and horizontally as shown. A portion of the belt 438 passes through the housing 442 where a wash/drain assembly is provided for washing the plugs as they travel through the housing 442. This wash/drain assembly is an optional feature of the system 50.
A pair of laterally spaced apart plug conveyors 450, 452 are provided downstream of the horizontal stretch of belt 438 and receive the plugs from the latter. Each conveyor 450, 452 has a pair of vertically spaced apart forward rollers 454, a rearmost driven roller 456, and an idler roller 458. A motor 460 is provided to power each of the belts 450, 452. The upper runs 450a, 452a convey the plugs 208 toward and into the corresponding elevators 184, where they are picked up by the magnetic pickups 196 carried on the roller chains 188 (see
An elongated rod assembly is situated within each of the tubes 476-482 and includes a forward most swab piston 484 associated with the larger diameters tubes 476 and 480 and a smaller diameter piston 486 associated with the smaller diameter tubes 478, 482. Elongated rods 488 extend rearwardly from the swab pistons 484, and likewise elongated rods 490 extend rearwardly from the swab pistons 486. Each rod has a piston 487 of appropriate diameter secured to the rearmost end thereof. The tubes 476-482 and internal rods 488, 490, are of essentially the same length as the cooking tubes 94, 96 and these components extend rearwardly below the lower run of conveyor belt 384.
The block 462 includes four oil inlet passageways 492 coupled with nipple 493, each located adjacent the rear face of a swab piston 484, 486. The block also has four other oil inlet passageways 494 coupled with nipple 495 spaced rearwardly of the corresponding inlets 492. A stationary, apertured bushing 496 of appropriate diameter is situated within each of the bores 468, 470 immediately in front of the rearwardly-extending tubes 476-482.
In order to maintain automated control, four proximity sensors 498 are provided for the bores 468, 470, and a sensor 500 is provided to sense the condition of the pancake cylinders 466.
As best seen in
During production runs using the system 50, the plugs 208 are continuously reused as cooked product is produced. However, at the end of a production run during cleanup, or when a different sized product is to be produced, the plugs 208 are conveniently stored for subsequent use. To this end, a plug storage assembly 69 is provided above the cooking drum assembly 56, close to the input end thereof. In general, the assembly 69 has a pair of left- and right-hand storage units 518. Inasmuch as the units are identical, only the lefthand unit 518 will be described in detail.
In particular, the unit 518 includes a box frame 520 presenting sidewalls 522, 524 and an end wall 526. A pair of transverse shafts 528 and 530 extend along the length of the unit within box frame 520. Each of the shafts 528, 530 has a pair of sprockets 532, 534 thereon, which support a pair of laterally spaced roller chains 536, 538. A drive motor 540 is operably coupled with shaft 530 in order to move the roller chains 536, 538. A plurality of elongated, generally L-shaped flights 542 are attached to aligned links of the roller chains 536, 538, and extend the full lateral distance between sidewalls 522, 524. The outwardly extending segments 544 of the flights 542 are sized to engage and convey a row of plugs 208, as later described.
The box frame 520 also is equipped with a gate mechanism 546 comprising a pair of individually shiftable gates 548, 549. Each gate 548, 549 has a mounting element 550 within a corresponding slot 552 respectively adjacent the inner surfaces of the side walls 522, 524. The gates are individually movable by means of a small pneumatic piston and cylinder assembly 554, 555. In the retracted position of the gate mechanism (
The unit 518 also includes a magnetic pickup roller 556, which is situated adjacent belt run 450a and has a row of magnets 558 each operable to pick up a respective plug 208 of a row thereof. The roller 556 is mounted between the gates 548, 549 as shown, and rotates by means of motor 560. An arcuate plug retainer guide wall 562 extends from the periphery of roller 556 remote from belt run 450a downwardly to a rack loading location.
The unit 518 is equipped with a plug rack 564 or 566 for receipt of smaller or larger diameter plugs 208. The selected rack is supported beneath the roller chains 536, 538 by means of a rack elevator assembly 568. As best seen in
The unit 518 is also provided with proximity sensors 589a to facilitate control thereof during operation, as described below.
In the ensuing discussion, the production of hot dog products using system 50 will be described, wherein only the small diameter cooking tubes 94 are employed. Hence, the larger diameter tubes 96 are not used for any purpose. For such operation, the gate assembly is closed and latched with slide frame 230 is in the upper position thereof as depicted in
In general, the operation of system 50 involves continuous cooking and plug recovery, with intermittent indexing movement of the cooking drum assembly 56. When the drum assembly 56 is stationary after each increment of rotation, three individual operations occur substantially simultaneously, namely (1) filling of empty and previously oiled small diameter tubes 94 of an array 92a with injection of successive charges of meat emulsion and forming plugs 208; (2) oiling of empty tubes 94 in an array 92b immediately adjacent and upstream of the array 92a being filled; and (3) ejection of cooked product and plugs from the tubes 94 of another array 92c spaced two arrays from the array 92b.
Cooking occurs owing to the fact that the housing 70 is filled with water, with steam injection into pipe 114, so that the steam travels through the stems 118 and the steam tubes 120. This serves to inject steam into the surrounding water so as to heat the latter and thus effect cooking of product within the tubes 94. The temperature probes 86 are continuously monitored in order to maintain proper cooking temperatures within the housing 70 As indicated, this cooking step occurs continuously during operation of system 50.
It is next assumed that the cooking drum has been indexed to a new incremental position by the operation of indexing drive 130, while the assemblies 63, 65 and 68, and subassembly 182, are in their standing positions spaced from the ends of the cooking tubes (see
Next, the pancake cylinders 244 of subassembly 180 are actuated in order to shift the latter towards housing 70 until the open ends of the delivery elements 265 come into mating engagement with the inlet ends of the cooking tubes 94 of array 92a (
Ejection of cooked product and plugs 208 from the tubes 94 of array 92c is accomplished by directing pressurized water from block 372 and outlets 376 into these tubes behind the closest plugs 208 (
Oiling of the tubes 94 of array 92b is effected by directing a pressurized mixture of lecithin and vegetable oil though the nipple 493 of block 462 for passage through inlets 492 immediately behind the swab pistons 486. This progressively moves the swab pistons through the length of the tubes 94 (
Referring now to
It is also contemplated that pressurized air may be injected into the cooking tubes during emulsion cooking, either continuously or intermittently throughout all or a portion of the cooking sequence. This serves to cook the emulsion under positive pressure to assist in product formation. In such a situation, a plurality of the sealing plug and tubular injector assemblies would be positioned adjacent to the output ends of the tubes 94, and would be shiftable into engagement with the output ends, in the manner of the assemblies 65 and 68. Hence, during indexing movement of the housing 70, the sealing plug and tubular injector assemblies would be retracted, and once the housing 70 was indexed to its next position, these assemblies would be moved back into operative engagement with the outlet ends of the tubes 94. This serves to cook the emulsion portions under compressive pressure within the tubes 94.
It will thus be appreciated that the tubes 94 of array 92a will be successively filled with plugs 208 and intermediate portions of meat emulsion. This operation is facilitated by the presence of the thin film of lecithin/oil on the inner surfaces of the tubes 94. In this fashion, all of the portions are cooked to essentially the same degree. The lecithin/oil coating has been found to facilitate ejection of cooked product from the tubes 94, without disrupting the skinned surfaces of the products.
As explained, the steps of filling the tubes 94 of array 92a, the application of oil to the tubes 94 of array 92b, and the ejection of cooked product and plugs from the tubes 94 of array 92c, occur substantially simultaneously. Once these steps are completed for a given set of arrays 92a-92c, the assemblies 63, 65, and 68, and subassembly 182, are separated from the ends of the tubes 94 by operation of the associated pancake cylinders, to assume the standby positions thereof. This permits a further indexing operation of the housing 70 using the indexing drive 130, whereupon the foregoing assemblies and subassemblies are again moved into operative engagement with the tubes 94 and the above steps repeat.
As the housing 70 is successively indexed and the tubes 94 of the arrays are filled with meat emulsion and plugs, cooking of the emulsion portions within the tubes is carried out. The system 50 is operated so that by the time filled tubes 94 successively reach the ejection assembly 63 and the finished product and plug delivery assembly 65, the emulsion portions are cooked to the desired degree.
The plug recovery assembly 66 operates essentially continuously and serves to pick up the plugs 208 from the belt 384 and direct these plugs to the plug elevators 184. In this regard, two streams of cooked product and plugs 208 are successively deposited upon the conveyor 386. As the plugs reach the magnetic roller 40, they are separated from the cooked products and two parallel streams of plugs pass along the conveyor belt 438. At the end of the belt 438, the plugs are transferred to the individual conveyors 450 and 452. This serves to move the plugs 208, again in separate plug streams, to the respective plug elevators 184 where the plugs are picked up by the magnetic pickups 196. The plugs then descend through movement of the roller chains 188 until they reach the detachment segments 216 of the channels 210, 212 (
As indicated, during production operations of system 50, the plug storage assembly 69 is not used. However, during system shutdown, for purposes of cleanup or size changeover, the plugs 208 are collected, and assembly 69 is used for this purpose. Accordingly, the proper sized rack 564 or 566 is inserted into each unit 518 by sliding the racks into the spaces above the depending walls 573 until the racks engage the rack stops 567. Next, the racks are elevated using the assemblies 568 so that the screws 588a thereof engage the undersides of the corner blocks 525 and raise the racks to their loading positions in the units 518.
At this point, the roller 556 is rotated so as to pick up the entire row of plugs 208 between the gates, and to deposit this row onto a flight 542. As the roller chains 538 continue to move, the transferred row of plugs 208 is moved downwardly along the path of wall 562 until the row of plugs is deposited on the proximal recess provided in the plug rack 564. This operation is continued and as additional plug rows are created and transferred, the flights 542 move the previously collected plug rows to successive plug recesses spaced from roller 556.
When the rack 564 is filled, the rack elevator assembly 568 is actuated to lower the filled rack out of the path of the chain flights 542, allowing the filled rack to be removed from the unit 518. Specifically, the assembly 568 is operated to shift the filled rack 564 supported on the screws 588a to the lowered position thereof, thereby permitting sliding withdrawal of the filled rack from the unit 518.
The above description has focused on the production of smaller diameter hot dog-type products making use of the smaller diameter cooking tubes 94 and related components. When it is desired to produce larger diameter products, the tubes 96 are used and the previously described change parts are installed on the system 50 in lieu of the smaller diameter change parts (see, e.g.,
In preferred forms, the tubes 94, 96 and all other meat emulsion-conveying components are the system 50 are formed from extruded Teflon. It has been found that this material gives an advantageous balance between cooking efficiency while avoiding problems of sticking and the like, which can degrade the integrity of the finished products. In other instances, however, materials such as stainless steel may be used.
The provision of plug-retaining shoulders 265c on the elements 265, and shoulders 97 on the cooking tubes 94, 96 is important in that it inhibits backward travel of the plugs 208 after insertion thereof. It has been found that without such shoulders, the plugs 208 can migrate backwardly, owing to the pressure conditions within the tubes, and thus disrupt production. The shoulders 265c and 97 have been found to mitigate this problem. However, along with the shoulders 97, positive pressure air or mechanical stops could be employed at the input ends of the tubes 94 after complete filling thereof as an additional means of preventing backward migration of the plugs 208. In the former case, seal and injector assemblies of the type illustrated in
The preferred embodiment of the invention makes use of cooking tubes 94, 96, which are axially fixed, and operating assemblies 62, 63 and 68, which move axially relative to the cooking tubes between standby and operating positions.
In greater detail, the system 600 broadly includes a stationary housing or enclosure 602, a plurality of elongated, generally horizontally oriented, open-ended heat exchange material treatment tubes 604, a tube support mechanism 606, and a heat exchange assembly 608. Further, the system 600 has the previously described forming plug and injection assembly 62, water injection assembly 63, output conveyor 64, finished product and plug delivery assembly 65 (not shown), plug recovery assembly 66, an oil application assembly 68, and plug storage assembly 69. These previously described components are illustrated only schematically to facilitate an understanding of the present embodiment, but are configured and operate in the same manner as those of the system 50.
In more detail, the enclosure 602 is in the form of an upright, box-like housing having opposed sidewalls 610 and opposed end walls 612, together with bottom wall 614 and a removable top wall 616 provided with a pair of tube-clearing slots 618 adjacent the sidewalls 610. The walls 610-616 are preferably insulated. An internal, insulated divider wall 620 extends between top and bottom walls 616, 614 and divides the enclosure 602 into a pair of side-by-side heat exchange zones 622, 624. The divider wall 620 also has a tube-clearing slot 626 therein located adjacent bottom wall 614.
The material treatment tubes 604 are each identical and of constant diameter. Each tube presents an inlet end 628 and an opposed outlet end 630. The tubes are advantageously formed of metal, such as stainless steel, to facilitate heat transfer through the walls thereof; in other instances, the tubes could be formed of a synthetic resin material such as Teflon.
The tube support mechanism 606 includes a pair of continuous chains 632 and 634 respectively supported on a pair of upper aligned drive and idler sprockets 636, 638. The drive sprockets 636 are supported on a common drive shaft 640 and, in like manner, the idler sprockets 638 are supported on a common idler shaft 642. As best seen in
The heat exchange assembly 608 has, for each zone 622, 624, a piping assembly 646 including a centrally located, main supply line 648 with a plurality of laterally extending secondary supply lines 650, which extend substantially the full length of the enclosure 602. A plurality of spaced apart spray nozzles 652 are mounted on each of the secondary lines 650 and are operable to generate spray patterns 654 directed toward the chains 632, 634, and particularly the tubes 604 supported thereby. The overall heat exchange assembly 608 further includes for each of the zones 622, 624 one or more drain lines 656 (or a single continuous drain) extending from bottom wall 614 and leading to a sump 658. A recirculation conduit 660 extends from each sump 658 to a pump 662. The output of pump 662 is secured to the main supply line 648, as best illustrated in
The forming plug and injection assembly 62 is situated above enclosure 602 and has a pair of plug and material injection subassemblies 182 and associated plug handling structure proximal to the lefthand or input side of enclosure 602, as viewed in
Also, the water injection assembly 63, finished product and plug delivery assembly 65, plug recovery assembly 66, oil application assembly 68, and plug storage assembly 69 are situated in suitable locations above enclosure 602 to permit these components to carry out their intended functions.
In the operation of system 600, the inlet ends of tubes 604 are filled with comestible material to be treated and, at a minimum, a pair of endmost plugs, such as the plugs 208. In the case of meat products, a meat emulsion would typically be used to fill the tubes 604, and if short length products are desired, intermediate plugs 208 would be injected, as previously described with reference to system 50. After filling, the tubes 64 are progressively and incrementally moved downward through and into the heat exchange zone 622 where water or other heat exchange media is sprayed onto the exterior surfaces of the tubes so as to treat (e.g., partially cook) the comestible material within the tubes. When the tubes reach the lower slot 626, they pass through the divider wall 620 and enter the second heat exchange zone 624. The tubes then move upwardly until they exit the enclosure 602 through the slot 618. As this occurs, the heat exchange fluid from the zones 622, 624 is collected in the sumps 656 and is recirculated by the pump 662. If desired, a heat exchanger (not shown) operably coupled with the main supply lines 648, may be used to heat the fluid prior to reuse thereof.
When the filled tubes having treated comestible material therein reach the water injection assembly 63, the treated comestible material and plugs are ejected onto conveyor 64. The plugs are separated from the comestible products by means of the recovery assembly 66. At this point, the tubes may be cooled using the assembly 663. The assembly 68 is next actuated to apply oil to the interior surfaces of the tubes 604. The oil may be in the form of any suitable vegetable oil or the like, and may also include lecithin and/or a color development agent, such as acetic acid. The oiled tubes are then reloaded with material and plugs, the latter being retrieved from the assembly 69. Thereupon, the filled tube ends are sanitized by assembly 664 before entry into the heat exchange zone 622. These steps are then repeated for essentially continuous production of at least partially treated (e.g., cooked) comestible products.
This embodiment makes use of tubes 406, which are axially fixed during operation of the system 50. However, as depicted in
The system 600 has a number of advantages. First, the provision of plural heat exchange zones allows staged treatment of comestible material within the tubes 604. For example, the material may be heated to a relatively high temperature in one of the zones, followed by lower temperature processing or cooling in another zone. The system also permits longer processing times as compared with the system 50. Use of stationary heat exchanger(s) and shiftable tubes permits the tubes to be cooled and/or sanitized prior to refilling thereof with comestible material. The ability to cool the tubes 604 prior to refilling thereof can also be a significant advantage, particularly when the tubes are heated during passage through the heat exchange zones 622, 624. That is, in such instances, a previously heated tube, if not cooled, can differentially heat the material during loading the loading operation, making it more difficult to provide a uniform partial or complete cook to the material. However, cooling prior to refilling avoids this potential problem. Finally, recirculation of the fluid heat exchange media results in lower energy input to the system.
This application is a continuation of identically titled application Ser. No. 13/212,840, filed on Aug. 18, 2011, which is a continuation-in-part of identically titled application Ser. No. 12/943,747, filed Nov. 10, 2010. This application also claims the benefit of Provisional Application Ser. No. 61/152,576, filed Feb. 13, 2009, and of Provisional Application Ser. No. 61/222,765, filed Jul. 2, 2009. Utility application Ser. No. 13/212,840 and Ser. No. 12/943,747, and the above-identified provisional applications are incorporated by reference herein in their entireties.