Food or edible material: processes – compositions – and products – Measuring – testing – or controlling by inanimate means
Reexamination Certificate
2001-03-27
2002-11-19
Yeung, George C. (Department: 1761)
Food or edible material: processes, compositions, and products
Measuring, testing, or controlling by inanimate means
C099S348000, C099S353000, C366S141000, C425S135000, C425S148000, C426S516000
Reexamination Certificate
active
06482453
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention is broadly concerned with material processing systems and methods characterized by a minimum of down time between individual runs and with comparatively little waste of starting materials during the course of the runs. More particularly, the invention is concerned with such methods and systems wherein the processing systems include a preconditioner and a downstream processor such as an extruder or pellet mill coupled in series with a variable speed discharge device therebetween; in use, the systems are run so as to maintain the discharge device in a full choke condition for as long as possible so that the processing unit receives material at a continuous and non-varying rate throughout substantially all of a given run. This allows proper processing of almost all of the starting material while permitting rapid clearing of the system so that a new run can be almost immediately commenced. In preferred forms, a staged vertical cascade-type dryer forms a part of the system and permits drying/cooling of the individual products from the extruder in a continuous and product-segregated fashion.
2. Description of the Prior Art
Extrusion systems have long been used for the production of a variety of food and other products. For example, many pet and human foods are produced using such equipment. Many extrusion systems include a preconditioner and an extruder in series relationship. Dry materials are fed from a bin system into the preconditioner outlet, where the materials are moisturized and partially cooked through application of steam and/or water and intense mixing. Such preconditioning materials are then fed into the inlet of an extruder equipped with one or more elongated, axially rotatable augers and an endmost apertured extrusion die. In the extruder, the materials are subjected to intense heat, pressure and shear and are forced through the extrusion die for complete cooking and shaping. Thereafter, the extruded products are typically dried and cooled in a multiple-pass dryer.
While extrusion systems of this type are common, significant operational problems remain. One such issue is the amount of waste involved in any given production run. Specifically, at the start up of a run waste is generated while the system comes into equilibrium and essentially continuous flow rates, pressures, temperatures, and residence times are established. Even more significant, however, is the waste problem encountered at the end of an extrusion run. Thus, when the last of a quantity of starting material is fed to the preconditioner, there inevitably follows a period where the flow of material to the extruder falls off until the preconditioner is emptied. Normally, the product produced during this last run stage is unacceptable and must be discarded. When it is considered that preconditioners hold from 900-1800 pounds of material, it will be appreciated that the last-stage waste is significant.
The above problem may not be deemed overly serious where large production runs are involved. Thus, if a 40-ton run is scheduled, the loss of 1,000 pounds of starting material may be sustainable. However, there is an increasing tendency to schedule short production runs of 5,000 pounds or less. In such cases the loss of 1,000 pounds at the end of the production run is economically unacceptable. This problem is so acute that some processors report that they obtain only a 60% yield on 4-ton batch runs.
Another adverse factor in extrusion processing stems from the down time associated with run changeovers. That is, where a processor wishes to change over a given system between two different products, down times of an hour or more are not uncommon. Again, where large-volume runs are scheduled, an operator can live with long down times. However, if a series of short (e.g., 5-ton or less) runs are scheduled on a production day, it will be seen that the changeover problem becomes significant.
The short run phenomenon also has a potentially adverse consequence for the postextrusion drying operation. That is, the end-stage extrudate from a first run must not be allowed to commingle with the first-stage product from the next succeeding run. Therefore, unless special steps are taken, the extruder must be shut down between runs to allow sufficient time for passage and clearance of all the extruded product through the dryer.
These same problems also occur in connection with other processing devices such as pellet mills where users want or desire quick-changeover short run capabilities.
There is accordingly a need in the art for improved processing systems and processes which overcome the problems outlined above and provide a quick changeover capability while also minimizing product loss.
SUMMARY OF THE INVENTION
The present invention overcomes the problems outlined above and provides improved processing systems, components thereof, and methods, applicable with a variety of processing devices such as extruders or pellet mills. Broadly speaking, the extrusion systems of the invention include an extruder having an elongated barrel with at least one axially rotatable, flighted auger therein, with the barrel presenting an inlet and an outlet and a die mounted at the barrel outlet. Such systems also include a preconditioner having shiftable mixing elements therein and an inlet for receiving material and an outlet coupled with the extruder barrel for feeding preconditioning material to the latter. A bin assembly and a variable speed inlet feeder screw are also normally coupled with the preconditioning inlet for feeding starting materials to the preconditioner.
An important part of the extrusion systems of the invention involves the use of a variable speed, variable output discharge feeder such as a screw feeder between the preconditioner outlet and the extruder inlet. In order to maximize usage of starting material, the system is run so that the screw feeder is maintained in a choke full condition for as long as possible. In this way, a steady and substantially constant flow of preconditioned material is delivered to the extruder for final processing. In order to accomplish this end, the control for the system may be set so as to alter preconditioner operation toward the end of a given extrusion run. To give one example, where a horizontally oriented preconditioner is employed the system may be set up so that, towards the end of the run, the preconditioner operation is altered to maintain the choke full condition at the discharge feeder. Such alteration may involve reversing the rotation of the preconditioner mixing paddles to force more material forwardly to sustain the choke full condition.
In another related aspect of the invention, the extrusion systems include one or more detectors coupled with a microprocessor controller such as a programmable logic controller (PLC). A detector assembly is operatively associated with at least the preconditioner (and usually the bin assembly as well) in order to determine the flow rate of material passing therethrough. Preferably, the mass flow rate is determined, but a volumetric flow rate could also be measured. The controller can then adjust system operation to maintain constant flow to the extruder for as long as possible. Preferably, a first detector (preferably in the form of a weighing device such as a load cell) is coupled with the bin assembly for determining when substantially the last of a predetermined quantity of starting material has been fed to the preconditioner. A second detector (also preferably a load cell) is coupled with the preconditioner and the two detectors are used to determine the flow rate through the preconditioner.
In order to further minimize down time, the systems of the invention preferably include a specialized multiple-position die assembly which can be rapidly shifted between first and second separate dies without the need for laborious changeovers which stop production. The preferred die assembly of the invention includes a head assembly including first and second spaced outlets wi
Hauck Bobbie W.
Wenger Lavon G.
Hovey & Williams, LLP
Wenger Manufacturing Inc.
Yeung George C.
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