[0001] The invention relates to the preparation of particulate cereal grain foods and to
the destruction of insect infestations in particulate cereal grains.
[0002] The middlings produced in flour milling, essentially small pieces of endosperm free
from bran and germ, are sold as farina and are often consumed as a breakfast food.
Farina is usually enriched with vitamins and minerals and can be flavored. To reduce
cooking time, about 0.25 percent of disodium phosphate can be added; some products
require as little as one-half minute of boiling before serving.
[0003] One known method of destroying insect infestation in milled grain is to heat the
infested milled grain, for example, wheat flores or wheat middlings, to a temperature
sufficient to kill the insects, larvae and eggs. The heating step is expensive, can
dehydrate the particles and can destroy some of the vitamin content of the particles.
The heated milled grain is then mixed with flavorants, vitamins and/or other additives.
The resultant mixture, which is also at comparatively elevated temperature is placed
in boxes and sealed.
[0004] U.S. Patent No. 3,102,781 discloses a centrifugal impact milling apparatus for destroying
insect infestation in particulate materials. The patent refers also to the use of
the impact milling machine of the type disclosed in U.S. Patent No. 2,529,679. The
centrifugal impact mill of U.S. Patent No. 3,452,937 is an improvement of the centrifugal
impact mill of U.S. Patent No. 3,102,781.
[0005] U.S. Patent No. 2,339,737 discloses a centrifugal impact milling apparatus for destroying
insect infestations in particulate materials. The patent states that it may be desirable
to destroy the insect life or infestation without changing the character of the product
in any manner, or it may be desirable to carry on a predetermined controlled process
such, for example, as milling, blending, etc.
[0006] U.S. Patent No. 2,644,740 discloses a centrifugal - impact milling apparatus for
grain infestation destruction.
[0007] Other centrifugal impacting apparatus are disclosed in U.S. Patent Nos. 4,083,504;
4,022,749; 2,981,490; 3,229,923; 3,023,973; 3,171,604; 4,113,191; and 3,433,422.
[0008] U.S. Patent No. 3,463,313 discloses a centrifugal impacting mill particle classifier
for milling soybeans and the like.
[0009] U.S. Patent No. 3,430,932 discloses contacting continuous and disperse phase substances
using centrifugal and centripetal forces.
BROAD DESCRIPTION OF THE INVENTION
[0010] An object of the invention is to provide a non-thermal process of eliminating insect
infestations in flour without significantly reducing the particle size profile or
increasing the fines content of such flour. Another object of the invention is to
provide an economical process for preparing particulate cereal grain containing additives,
which can be cooked for human consumption. Other objects and advantages of the invention
are set out herein or are obvious herefrom to one ordinarily skilled in the art.
[0011] The objects and advantages of the invention are achieved by the processes and composition
of the invention.
[0012] The invention involves a process for destroying insect infestation in particulate
cereal grain. The process includes treating the insect-infested particulate cereal
grain in centrifugal impact milling apparatus. Preferably the treating step is conducted
at room or ambient temperature. The centrifugal milling apparatus has a casing and
a rotatable rotor is rotated at a peripheral velocity which is sufficient to cause
destruction of the insect infestation in the particulate cereal grain by impelling
by centrifugal force the particulate cereal grain in contact with the peripheral region
of the rotor against the inner wall of the casing and/or impactors located inside
of the casing. But the centrifugal is of such a magnitude as not to significantly
decrease the particulate range profile of the particulate range profile of the particulate
cereal grain. Importantly, the amount of fines of the particulate cereal grain is
not significantly increased.
[0013] Basically, the centrifugal impact milling apparatus has a rotor with a plurality
of impacting elements against which the particulate material to be processed is impelled
by centrifugal force at high speed. Since milling is avoided in the invention process,
it is probably more appropriate within the context of the invention to refer to the
apparatus as centrifugal impact apparatus.
[0014] In this invention, the centrifugal impact milling apparatus is operated at conditions
so as to kill the insects, larvae and eggs without milling the cereal grain particles.
The procedure must be done in such a manner as to insure total destruction of any
insect life present, regardless of form of the insect life. It is important to obtain
proper distribution of the product in the treating area of the machine. To obtain
total destruction of the insects in the product, the product must be delivered to
the impactors in the treating rotor in such a manner that every particle of the product
as well as every insect, regardless of its stage of development, is engaged by one
or more of the impactors. If too much product is fed to the impactors per unit of
time, there is the danger that the insect life will be cushioned and accordingly protected
by the excess product and pass through the impactors unharmed. On the other hand,
if the film of product delivered to the impactors is too thin, the treating capacity
of the machine is so greatly reduced as to make it uneconomical.
[0015] The critical criterion for the operation of the rotor of the centrifugal impact milling
apparatus is the peripheral velocity of the rotating rotor. The criterion is not expressed
in revolutions per unit of time for the rotor because the desired centrifugal force
is determined by the peripheral velocity of the rotating rotor. Peripheral-velocity
is dependent both upon the radius of the rotor and the revolutions per unit of time
of the rotor.
[0016] The invention also includes a process for preparing particulate cereal grain containing
at least one additive, which can be subsequently cooked for human consumption. The
process includes treating the particulate cereal grain, which may be infested with
insects, in centrifugal impact milling apparatus. Preferably the treating step is
conducted at ambient or room temperature. The centrifugal impact milling apparatus
has a casing and a rotor rotatably mounted in the casing. The rotatable rotor is rotated
at a peripheral velocity which is sufficient to cause destruction of the insect infestation
in the particulate cereal grain by impelling by centrifugal force the particulate
cereal grain in contact with the peripheral region of the rotor against the inner
wall of the casing and/or impactors located inside of the casing. But the centrifugal
force is of such a magnitude as not to significantly decrease the particle range profile
of the particulate cereal grain. The particulate cereal grain is removed from the
centrifugal impact milling apparatus and then the particulate cereal grain is mixed
with at least one edible additive. Preferably the mixing step is conducted at room
or ambient temperature.
[0017] The processes of this invention are applicable to any cereal grain flour, but is
most advantageously used with wheat middlings. The cereal grain flour can be, for
example, wheat flour, barley flour, sorghum flour, corn (maize) flour, oats flour,
rye flour, rice flour and millet. The flour can be from non-cereal starch- yielding
plants, for example, cassava flour (i.e., tapioca flour), soybean flour, potatoe flour
and buckwheat flour.
[0018] The outer covering of wheat grain, which has been separated in extraction of the
flour from the grain, is in a state of subdivision and is composed of bran and the
finer, more floury outer coverings termed middlings. Depending on particle size profile,
middlings are often termed coarse middlings and fine middlings.
[0019] The centrifugal impact milling machines are well known. In achieving grain infestation
destruction in the invention process, grain or grain products such as middlings which
may contain live insects is applied to the working area of the high speed rotor situated
in a closed chamber or casing. In one form the rotor is connected at the bottom of
a vertical shaft and rotates substantially in a horizontal plane. The rotor may consist
of a solid circular bottom plate and an annular top plate which is supported on the
bottom plate by a plurality of upstanding "impactors" disposed between the plates
near the periphery thereof. The flour is fed to the bottom plate via an inlet in the
casing which is coupled to a space between the inner edge of the annular top plate
and the rotor shaft. A circular vertical wall or collar, sometimes known as the "distributor,"
depends from the lower surface of the top of the rotor casing to assist in preventing
the flour from escaping from the processing action of thi- rotor. The speed of rotation
of the rotor is such that the flour is impelled outwardly from the inlet area, between
the rotor plates, into contact with the moving impactors at a velocity sufficient
to kill the insects. If desired, a ring of stationary impactors can be placed surrounding
the moving impactors.
[0020] While the film of the product is passing outwardly past the impactors, every minute
particle thereof is violently engaged by one or more of the impactors. These impactors
inflict upon the insect life severe physical mutilation with the resultant destruction
of all of the insect life, regardless of its stage. This destruction is accomplished
without significantly particle size profile reduction or fines increase.
[0021] The insect destruction is obtained by impacting actions which are produced within
the treatment zone.
[0022] The rotor preferably is rotating at a peripheral velocity of 7,000 to 10,000 feet
per minute, more preferably 7,500 to 9,000 feet per minute and most preferably at
about 8,000 feet per minute. Control of the amount of energy imparted to the infested
wheat middlings is very important as the impact force must fit within the invention
parameters.
[0023] It is important to prevent the production of fines as the presence of excessive fines
in the final flavored product will cause the cooked product to gell and to be too
starchy and gummy. The invention product has an excellent taste and texture. Preferably
the impacting step does not increase the amount of fines or small particles in the
particulate cereal grain more than 1.0 percent (and most preferably the increase is
less than 0.5 percent). In the case of middlings, the amount of particles going through
a 100 mesh sieve (U.S. Standard) should not be more than 2.5 percent. Basically the
invention uses a rotor peripheral velocity which does not cause any affect as regards
particle size.
[0024] The invention step of non-thermal insect infestation destruction is advantageous
over the prior art in that it does not require an expensive heating step (to destroy
the insects, larvae and/or eggs) and avoids drying out the particulate cereal grain.
[0025] The additives can be dried fruits, spices, other flavorants, etc.
[0026] Enrichment with minerals and vitamins is preferred. The ability to use a mixing step
in which the middlings is at room temperature is a significant advantage over the
prior art methods where the middlings were heated to 170°F. to destroy any insect
infestation. Previously the hot middlings were mixed with additives, such as, minerals,
vitamins and flavorants, and the mixture was put into boxes while at about 140°F.
and the boxes sealed. The heat treatment can destroy some of the original vitamin
content, which must be made up by vitamin addition. The mixing with the heated middlings
can destroy or impair some of the added vitamins. This disadvantage does not exist
with the invention process.
[0027] The invention further includes the particulate cereal grain containing additives,
which can be subsequently cooked for human consumption, prepared by the process of
the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
[0028] In the drawings:
Figure 1 is a side elevation view of a typical centrifugal impacting machine, partly
sectional;
Figure 2 is an enlarged fragmentary and sectional view of the rotor and its environment
take along the line 2-2 shown in Figure 1;
Figure 3 is a fragmentary plan view of part of the rotor shown in Figure 2 looking
in the direction of the arrows associated with the line 3-3 of Figure 2; and
Figure 4 is a plan view of the rotor shown in Figures 1, 2 and 3.
DETAILED DESCRIPTION'GF THE INVENTION AND DRAWINGS
[0029] As used herein, all parts, percentages, ratios and proportions are on a weight basis
and all temperatures are expressed in degrees Fahrenheit, unless otherwise stated
herein or obvious herefrom to one skilled in the art.
[0030] The invention process generally prepares edible cereal product prepared from at least
one wheat farina or farina-like product, preferably wheat middlings. The wheat used
must have been subdivided into a reduced-size state, but preferably into the farina
state. The farina used usually has an average particle size between about 20 to 40
mesh (U.S. Series). The Federal Specification for farina requires that: 100 percent
of the product passes through a U.S. Standard No. 20 woven-wire-cloth sieve; not more
than 10.0 percent passes through a
U.S. Standard No. 45 sieve; and not more than 3.0 percent passes through a U.S. Standard
No. 100 sieve.
[0031] Flour by-products, derived from the outer coverings of the wheat grain separated
in extraction of the flour from the grain, are bran and the finer, more floury outer
coverings are termed middlings. The middlings produced in flour milling, essentially
small pieces of endosperm free from bran and germ, are termed farina. The composition
of middlings can vary a great deal depending on the wheat used and the amount of endosperm
present. In the manufacture of farina, it is necessary to use-hard wheat as a raw
material since soft wheat yields a product which becomes excessively pasty upon cooking.
A typical wheat coarse middlings contains 19.0 percent of protein, 5.'8 percent of
fat, 65.0 percent of carbohydrates, 6.0 percent of fiber and 4.20 percent of ash.
A typical wheat fine middlings contains 18.0 percent of protein, 3.9 percent of fat,
73.1 percent of carbohydrates, 2.2 percent of fiber and 2.8 percent of ash.
[0032] The process of the invention can also be used to prepare cereal products from other
than wheat farina. For example, cereal grains such as rice, barley, oats, rye, corn,
millet, etc., can be used in the invention process in place of the wheat farina, or
at least part thereof. Such cereal grains should be used in the particulate form which
has a particle size within the approximate particle size range of wheat farina.
[0033] In Figure 1, a supporting generally rectangular frame 9 is provided which includes
four vertical cylindrical posts 10 (two of which, namely 10a and 10b are shown) to
which four horizontal beams are connected, two of these beams running lengthwise of
the structure and two running transverse thereto. One of the lengthwise beams is a
beam 11a which is shown in full. Two crossbeams llb and llc are shown in section;
the fourth lengthwise beam is not shown for simplicity of illustration. These beams
are fixedly connected as by welding (or bolting) to four curved plates or sockets
12 (two of which, 12a and 12b, are pictured) which are curved to match the contour
of the surfaces of the vertical columns 10a and 10b. The sockets are permanently affixed
to 10a and 10b. The sockets are permanently affixed to the vertical columns by welding
(or bolting) for example, as desired.
[0034] A heavy-duty motor 13 is bolted, as shown, to a vertical motor support member 14
having a horizontal portion 7 which rests on the longitudinal beams. Either the portion
7 or the longitudinal beams (or both) may have slots running lengthwise of the frame.
A bolt assembly 8 extends through the slot in the portion 7 or in the beam to anchor
the slides in the desired horizontal position once adjustment of the spacing of the
motor 13 from the rotary processing part of the apparatus has been made by means of
the turnbuckle 34.
[0035] In order to support the rotary processing equipment there is also provided a spanning
transverse Z-beam 15 connected at its ends, as by welding, to the two longitudinal
beams 11. A rotor casing or chamber indicated generally at 16 depends from the supporting
structure 9 by connections to the transverse spanning beam 15 and to the member 11c
as is explained in detail below. The rotor casing 16 includes a top casing member
17 which is essentially cylindrical in shape. Connected to, and extending upwardly
and outwardly from the top 17 are two input chutes one of which, designated by-the
number 18 (see also Figure 2), is on the side of the pulley shaft 30 toward the reader.
There is an identical chute (not shown) on the other side of shaft 30. At the tops
of, and connecting these two chutes is a horizontal rectangular plate section 19 integral
with the chutes 18 which extends transversely of the longitudinal beam 11. Plate section
19 has a central round-apertured portion 43 through which the shaft 30 passes and
two rectangular openings 22 for the chutes on either side thereof. To the plate section
19 a flanged input conduit (not shown) may be connected, for example, for supplying
the material in which the insect infestation is to be destroyed.
[0036] The plate 19 has apertures through which bolt 23, on the side of the shaft 30 toward
the reader, and another bolt (not shown) on the other side of the shaft, are passed
to suspend the top 17 of the casing 16 from the
Z-beam 15. The casing top 17 is also suspended from the transverse beam llc by a bolt
connection 21 to a
C-beam 26 whose upper surface is fixedly connected, as by welding to the cross beam
llc.
[0037] The rotor casing 16 also includes a lower hopper portion 24 which is secured to the
upper portion 17 by clamps 25 connected to the top and bottom members 17 and 24 at
various points around the junction of the lower edge of the top portion 17 and the
upper rim of the lower portion 24. These clamps 25 permit the casing 16 to be disassembled
to allow access to the rotor 27, for example, or to permit the hopper 24 to be cleaned.
[0038] Referring now principally to Figures 1 and 2, a rotor 27 is located within the general
confines of the top casing portion 17. Rotor 27 is keyed or otherwise attached to
the lower shaft portion 28 which is a continuation of the upper shaft portion 30.
The upper shaft portion 30 is mounted in a spindle assembly or yoke 35 consisting
of two planar horizontal members 35a and 35c connected by an intermediate vertical
member
35b. Between the members 35a and 35c and mounted fixedly on the upper shaft portion 30
is a pulley sheave
31. The member 35c may be bolted or otherwise fixedly connected to the midsection of
the plate section 19. The top end of shaft portion 30 is journalled in a top bearing
assembly 29 and its lower end passes through lower bearing assembly 20.
[0039] Opposite the sheave- 31 and parallel thereto is a sheave 32 fixedly mounted on the
rotor shaft of the motor 13. Around both sheaves are disposed a plurality of belts
33 for transmitting energy from the motor 13 to the rotor 27. As previously mentioned,
the horizontal spacing between the sheaves 31 and 32 and consequently the tension
on belts 33 can be adjusted by turning the turnbuckle 34 connected to the plate 14
and to the spanning Z-beam 15.
[0040] As seen in the enlarged view of Figure 2 the rotor 27 consists of an essentially
disc-like bottom plate 36 fixedly connected to the hub 45 which is mounted fixedly
around the lower shaft portion 28. The rotor 27 also includes an annular upper plate
37 which is supported on the lower plate 36 by a series of movable vertical impactors
38. Impactors 38, which can be hollow cylindrical steel members, are fixed in place
between upper and lower plates 37 and 36, by bolts 39 passing through their bore which
thread into apertures in the lower plate 36. The movable impactors 38 are disposed
in a circular row near the outer edges of plates 36 and 37 (
Fig. 4). In some models stationary impactors 40 are arranged in a concentric row surrounding
the row of movable impactors 38. Impactors 40 are fixedly (and preferably demountably)
connected, as by bolts passing through them, which thread into holes in a liner 41
mounted near the peripheral vertical wall of the top casing member 17.
[0041] When the motor 13 is in operation, the rotor 27 rotates at desired speeds which produce
the desired peripheral velocities. Material to be de-infested is fed via the input
chute 18 (and its counterpart on the other side of the shaft 30) to the upper surface
of the bottom rotor plate 36 near the hub 45. The input area is substantially segregated
from the area where the impact infestation-destruction action occurs by a circular
vertical collar (distributor) or wall member 35 which depends from the horizontal
interior surface of the top 17 or which may actually be formed as part of the lower
surface of top 17. This member 35 prevents the greater part of the incoming particulate
material from moving upward and over the top plate 37 into the hopper 24.
[0042] As may be seen by reference to Figure 2, the solid arrows indicate the direction
of flow of the input mate-
rial. As the rotor 27 spins, the applied material is hurled by the generated centrifugal
force outward until it strikes the row of impactors 38 with force sufficient to kill
any insect life within the material. In the case of flour, an insect known as the
"confused flour beetle" often is an infestant but when the flour hits the impactors
38 the insects are destroyed. The flour impacted by the impactors 38 also strikes
the outer row of impactors 40 which doubly insure that all insects passing through
the processing area are destroyed, but such that there is.no significant reduction
of the flour particle size.
[0043] Since the bearings and the other mountings of the rotor 27 have finite tolerances
and since the rotor may spin at high speeds, the components of the rotary motion may
cause the axis of revolution of the rotor shaft 30 to wander sideways a bit. Consequently
there is provided an annular space 42 of about 1/16" between the collar 35 and the
inner edge of the top plate 37.
[0044] When the material to be applied is fed via the chutes 18 at a very high rate, an
undesirably high number of live insects can be mixed in with the
pro- cessed flour in the hopper 24. It was first thought that the insects were able
to get through the spaces between adjacent ones of the impactors 38. This is a case
of the insect life being able to bypass the impacting area by going or being borne
by air currents through the space 42, over the top rotor plate 37 and finally into
the hopper 24. One way of correcting this trouble is to provide means considered but
the one finally adopted was found to be associated with the rotation of the rotor
27 to generate a current of air in the space 42 in such a direction that insect life
would not be able to move upwards and through. Accordingly, as shown in Figures 2,
3 and 4, eight solid bars 44 are mounted on the upper side of the top rotor annulus
37. The bars 44 are spaced equal distances from one another and arranged radially
with respect to the hub 45. When the rotor 27 moved, the bars 44 cause an air current,
as shown by the broken-line arrows in Fig. 2, to move down through the space 42 and
then out toward and through the impacting region.
[0045] While the utility of the invention has been explained in terms of very small insects
being borne through the space 42, it should be appreciated that insect eggs or larvae
as well as adult insects are destroyed by the impactor milling apparatus.
[0046] Although the invention has been explained in connection with one particular type
of centrifugal impact-milling machine, it is just as applicable to other types having
rotating impacting elements of different shapes and sizes, or different numbers of
impactors, or different numbers and kinds of stationary impactors. For example, the
centrifugal impact mill of
U.
S. Patent No. 3,452,937, which is an improvement of the above-described centrifugal
impact milling apparatus, can be used if the grain is somewhat damp or moist.
[0047] Any suitable impact milling apparatus can be used in the invention process. Examples
of suitable impact milling apparatus are those of U.S. Patent Nos. 3,102,781; 3,452,939;
4,083,504; 2,981,490; 2,644,740; 2,529,679; 3,229,923; 3,023,973; 3,171,604; 4,113,191;
3,433,422 and 2,339,737. While such impact milling apparatus are capable of milling
grain or reducing the particle size of already-milled cereal, the invention process
uses such impact milling apparatus in such a manner so as to destroy insect infestation
in already-milled cereal without significantly reducing the particle size profile
and increasing the fines of such already-milled cereal. A centrifugal impact milling
apparatus is not used if it cannot meet the operational conditions and results required
by the invention.
[0048] The pertinent portions of U.S. Patent No. 3,102,781 are incorporated herein by reference.
U.S. Patent No. 3,102,781 discloses a centrifugal impact milling apparatus for grain
infestation destruction. The centrifugal processing apparatus includes a rotor housed
in a casing which is constructed to permit the passage through it of said materials
for application to the rotor which thereupon impels the materials by centrifugal force
to insect-destroying elements located toward the periphery of the rotor. The housing
include a wall member between the elements and the area of the rotor to which the
materials are applied. The wall member is separated from the rotor by a predetermined
space having dimensions such that insect life in the applied material is able to pass
through it and thereby avoids lethal contact with the insect-destroying elements.
There is means for producing in the space a current of the violent atmosphere in a
direction such as to prevent the insect life from escaping lethal contact with the
insect-destroying elements.
[0049] The pertinent portions of U.S. Patent No. 2,339,737 are incorporated herein by reference.
U.S. Patent No. 2,339,737 discloses centrifugal impact milling apparatus for destroying
infestation in flour. The apparatus includes a base, a casing mounted on top of the
base, a motor mounted in the casing and means for cooling the motor during operation
thereof. The motor has a heavy armature shaft. There is an anti-friction bearing secured
to the casing for journaling the upper end of the shaft, a heavy anti-friction bearing
housed in the base for journaling the lower end of the shaft, and means forming an
oil seal about the shaft and the lower bearing. There is further a treating rotor
secured to the lower end of the shaft, a casing secured to the under side of said
base and surrounding the rotor, a product inlet conduit formed in the base and adapted
to deliver the product to the rotor, and a distributor secured to the base adjacent
to the upper central portion of the rotor and adjacent to the delivery end of the
inlet for receiving the product from the inlet and for distributing it uniformly to
the rotor. The delivery end of the distributor is positioned adjacent the center portions
of the rotor. One portion of the delivery end of the distributor is further spaced
from' the rotor portion than that portion of the delivery end of the distributor immediately
underlying the inlet.
[0050] The pertinent portions of U.S. Patent No. 2,529,679 are incorporated herein by reference.
U.S. Patent No. 2,529,679 discloses an impact milling apparatus. The apparatus includes
means forming a casing having a product-inlet opening at the top and a product-discharge
opening at the bottom, and a rotor mounted within the casing beneath the inlet opening
and adapted upon rotation to subject the product particles to an impacting action
agai-nst the side of the casing and to impart to the product particles rapid rotary
movement. An inwardly tapering scouring shell is mounted beneath the rotor and is
adapted to receive the product as it is discharged from the rotor and to direct the
product downwardly in a thin unimpeded annular stream. There is conical surface forming
means forming with the bottom of the shell an annular product-directing chute including
baffle structure to stop the rotary movement of the product and to direct the product
downwardly and radially-outwardly. There is also means forming an annular aspirating
passageway exteriorly of the shell and including an annular aspirating gap at the
exit end of the chute and across which the product flows. There is further means to
flow a stream of air upwardly through the aspirating passageway and through the product
at the gap.
[0051] The pertinent portions of U.S. Patent No. 2,644,740 are incorporated herein by reference.
U.S. Patent No. 2,644,740 discloses a centrifugal impact milling apparatus for grain
infestation destruction. The apparatus includes a rotor defining an annular treatment
zone through which the product flows to impart rotary movement thereof, and a downwardly
extending casing construction surrounding the rotor and defining at the periphery
of the rotor a discharge zone having an impact surface against which the rotating
stream of the product passes. There is means forming a pair of separation hoppers
beneath the zone and connected thereto. The means includes a separating wall member
having openings therethrough and separating the upper portions of the hoppers directly
adjacent and below said discharge zone whereby the rotating annular stream of the
product passes along the separating wall with the smaller particles passing through
the openings and with the larger particles passing downwardly along the wall.
[0052] The pertinent portions of U.S. Patent No. 3,452,937 are incorporated herein by reference.
U.S. Patent No. 3,452,937 discloses a centrifugal impact mill wherein material processed
by a high speed rotor is flung outwardly toward a surrounding gas-permeable wall member.
To prevent adhesion of the material to the wall member, the latter is surrounded by
a chamber to which air or other gas is fed under pressure. The gas is forced through
the pores of the wall member toward the interior of the apparatus thereby tending
to dislodge any material sticking to the inside surface of the wall member or tending
to repel such material before adhesion to the wall member. Means are provided within
the apparatus for drawing off the gas from the interior.
[0053] The pertinent portions of U.S. Patent No. 3,229,923 are incorporated herein by reference.
U.S. Patent No.
3,229,923 discloses a centrifugal impacting apparatus.
[0054] The pertinent portions of U.S. Patent No. 3,023,973 are incorporated herein by reference.
U.S. Patent No. 3,023,973 discloses a centrifugal impacting apparatus.
[0055] The pertinent portions of U.S. Patent No. 3,171,604 are incorporated herein by reference.
U.S. Patent No. 3,171,604 discloses a centrifugal impacting apparatus.
[0056] The pertinent portions of U.S. Patent No. 4,083,504 are incorporated herein by reference.
U.S. Patent No. 4,083,504 discloses a centrifugal impacting machine.
[0057] The pertinent portions of U.S. Patent No. 2,981,490' are incorporated herein by reference.
U.S. Patent No. 2,981,490 discloses a centrifugal impact milling apparatus.
[0058] The pertinent portions of U.S. Patent No. 4,113,191 are incorporated herein by reference.
U.S. Patent No. 4,113,191 discloses a centrifugal impact milling apparatus.
[0059] The pertinent portions of U.S. Patent No. 3,433,422 are incorporated herein by reference.
U.S. Patent No.
3,433,422 discloses a centrifugal impact mill and subsequent particle classifier.
[0060] The suitable centrifugal impact milling apparatus allows treatment of or can be adapted
to treat a product in such a manner that the infestation is physically mutilated and
thereby destroyed. The physical mutilation is inflicted by passing the product through
a treatment zone, and during this movement impacting, squeezing, or otherwise maltreating
the various forms of infestation. The treatment zone is formed by an annular rotor
which is rotated at a sufficiently high speed and the product is fed to the center
of the rotor and is thrown outwardly as a result of the rotation. It is important
from a commercial standpoint to effect a total destruction of the infestation, for
if this treatment is anything less than 100 percent effective, the produce cannot
be stored without danger of reinfestation. (The rotation of the rotor can move the
particulates to and through the treatment zone.)
[0061] In destroying insect life in this manner, each portion of the product must be given
a thorough treatment; however, it is important that the apparatus be used efficiently,
as large quantities of the product must be handled and the apparatus must not occupy
a large amount of space. To obtain this thorough action in an efficient manner, the
entire rotor should be used at all times, and thus, it has been found that it is highly
important to provide for the effective and dependable distribution of the product.
For example, if the product is improperly distributed, with the result that an excessive
quantity passes through one portion of the rotor, the product may cushion the mutilating
action so that there is no complete life-destroying mutilation, and, as a result,
some of the insect life may pass through the treatment zone without being destroyed.
The possiblity of such a cushioning action becomes more likely when the apparatus
is being used to treat the product at the maximum rate_. Furthermore, under such circumstances
it is highly important that the product be properly distributed in order to prevent
congestion in localized portions of the apparatus as such congestion might stop all
flow.
[0062] The dry wheat farina or farina-like material, at this stage in the process, is mixed
with additional ingredients, such as, vitamins, minerals, dried fruits, flavoring
and antioxidants. Such additional ingredients should not usually be present in an
amount greater than 40 weight percent, based on the total dry weight of the dry wheat
farina or farina-like material. Vitamins, if added during the invention process, are
preferably added to a dry composition. Usually salt (NaCl) in the amount of about
0.5 to 4.0 percent by weight is added, although some of the NaCl can be replaced by
KC1.
[0063] Fortifying and other additives, flavoring, colorant, salt, sugars, minerals, wheat
germ, cocoa, antioxidants and the like can be incorporated into the dried wheat middlings.
The additives include B-complex vitamins,, malt, soluble iron compounds, vitamin A,
vitamin C, BHA and BHT. Also, non-fat dry milk solids, (i.e., milk powder) or soybean
protein may be added in an amount sufficient to create a final protein level of up
to 10 to 20 percent. (About 0.25 percent of disodium phosphate can be added to reduce
the cooking time of the final product.)
[0064] Further about 5 to 8 percent of at least one fruit can be incorporated into the dried,
wheat material. The more popular dry or semi-dry fruits that can be used in the invention
process include raisin, apple, apricot, blackberry, boysenberry, cherry, current,
plum, elderberry, fig, gooseberry, grape, guava, loganberry, nectarine, peach, pear,
pineapple, quince, raspberry, strawberry and other fruits or flavors. Also, an emulsifier
does not have to be used in the process or product of the invention.
[0065] The preferred types of flavored final products are raisin, maple, apple cinnamon,
apple raisin spice and raisin cinnamon.
[0066] The final flavored (or unflavored) product is usually placed in air-tight boxes in
a conventional manner.
[0067] The product can be cooked in water or milk for a few minutes to provide a flavored,
cooked farina, which is usually eaten in a bowl with added milk (or water) and added
sweetener.
[0068] By way of example, an insect-infested wheat middling (at room temperature) having
the particle analysis:
![](https://data.epo.org/publication-server/image?imagePath=1987/39/DOC/EPNWA2/EP87400541NWA2/imgb0001)
is treated at room temperature in a centrifugal impact milling apparatus using a peripheral
velocity for the rotor of 8,000 feet per minute. The insect, larva and egg infestation
in the wheat middlings is destroyed by the treatment. The treated wheat middlings
has the particle analysis:
![](https://data.epo.org/publication-server/image?imagePath=1987/39/DOC/EPNWA2/EP87400541NWA2/imgb0002)
[0069] The treated wheat middlings are mixed with raisins, minerals and vitamins at room
temperature and then are boxed in air-tight containers. One box is opened, one cup
of the contents is mixed with one-third cup of water, is cooked for 3 to 5 minutes
and mixed with milk and sugar in a bowl. The cooked material has an excellent taste
and texture and is not gummy, lumpy or starchy.
1. Process for destroying insect infestation in particulate cereal grain comprising
treating said insect-infested particulate cereal grain in centrifugal impact milling
apparatus, said centrifugal milling apparatus having a casing and a rotor rotatably
mounted in said casing, said rotatable rotor being rotated at a peripheral velocity
which is sufficient to cause destruction of said insect infestation in said particulate
cereal grain by impelling by centrifugal force said particulate cereal grain in contact
with the peripheral region of said rotor against the inner wall of said casing and/or
impactors located inside of said casing, but which is of such a magnitude as not to
significantly decrease the particulate range profile of said particulate cereal grain.
2. Process as claimed in Claim 1 wherein said particulate cereal grain is infested
with insects, insect larvae and/or insect eggs.
3. Process as claimed in Claim 2 wherein said particulate cereal grain is wheat middlings.
4. Process as claimed in Claim 3 wherein said centrifugal force has a magnitude which
does not significantly increase the amount of the smaller particles or fines of said
particulate cereal grains.
5. Process as claimed in Claim 3 wherein said peripheral velocity of said rotor is
from about 7,000 to about 10,000 feet per minute.
6. Process as claimed in Claim 3 wherein said peripheral velocity of said rotor is
from about 7,500 to about 9,000 feet per minute.
7. Process as claimed in Claim 3 wherein said peripheral velocity of'-said rotor is
about 8,000 feet per minute.
8. Process as claimed in Claim -3 wherein said insect-infestation destruction step
is conducted at or about room temperature.
9. Process of preparing particulate cereal grain containing at least one additive,
which can be subsequently cooked for human consumption, comprising:
(a) treating said particulate cereal grain, which may be infested with insects, in
centrifugal impact milling apparatus, said centrifugal impact milling apparatus having
a casing and a rotor rotatably mounted in said casing, said rotatable rotor being
rotated at a peripheral velocity which is sufficient to cause destruction of said
insect infestation in said particulate cereal grain by impelling by centrifugal force
said particulate cereal grain in contact with the peripheral region of said rotor
against the inner wall of said casing and/or impactors located inside of said casing,
but which is of such a magnitude as not to significantly decrease the particle range
profile of said particulate cereal grain; and
(b) removing said particulate cereal grain from said centrifugal impact milling apparatus
and mixing said particulate cereal grain with at least one edible additive.
10. Process as claimed in Claim 9 wherein said particulate cereal grain is infested
with insects, insect larvae and/or insect eggs.
11. Process as claimed in Claim 10 wherein said particulate cereal grain is wheat
middlings.
12. Process as claimed in Claim 11 wherein said insect-infest destruction step and
said mixing step are conducted at or about ambient temperature.
13. Process as claimed in Claim 11 wherein said centrifugal force has a magnitude
which does not significantly increase the amount of the smaller particles or fines
of said particulate cereal grains.
14. Process as claimed in Claim 11 wherein said peripheral velocity of said rotor
is from about 7,000 to about 10,000 feet per minute.
15. Process as claimed in Claim 11 wherein said peripheral velocity of said rotor is
from about 7,500 to about 9,000 feet per minute.
16. Process as claimed in Claim 11 wherein said peripheral velocity of said rotor is
about 8,000 feet per minute.
17. Process as claimed in Claim 11 wherein said mixture is placed in at least one
box and said at least one box is sealed.
18. Process as claimed in Claim 11 wherein said boxing step is conducted at or about
ambient temperature.
19. Particulate cereal grain containing at least one additive, which can be subsequently
cooked for human consumption, prepared by the process of Claim 1.