Ultimate Cleanable Food grade feeder device and system for rolls, sandwiches, odd-shaped edibles and foodstuff

Abstract

A compact, ultimate, and cleanable food grade feeder device and system for quickly orienting, aligning, and feeding single rolls, sandwiches, oddly shaped edibles, and foodstuff to assemble and make ready for packaging the foodstuff.

Description

FIELD OF INVENTION

This invention relates to an Ultimate Cleanable Food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff. The present disclosure relates generally to the preparation of food products and, more particularly, but not by way of limitation, to preparing sandwiches. It also relates to a sandwich preparation apparatus or food handling system that incorporates a system that automates the process. The present invention relates to a clean product aligning device. This invention relates to an apparatus for the assembling of biscuit or roll sandwiches. More particularly, it relates to an apparatus for the faster, more compact assembling of biscuit sandwiches ready for packaging by a centrifugal feeder bowl. Also, because of its food-grade materials, it relates to a large capacity centrifugal precision feeder which can be utilized to aid in packaging, for instance, food, medical, pharmaceutical, and military special handling products.

FEDERALLY SPONSORED RESEARCH

None.

SEQUENCE LISTING OR PROGRAM

None.

BACKGROUND—FIELD OF INVENTION and PRIOR ART

This section is not Applicable to Provisional Applications. However, as far as known, there are no Ultimate Cleanable Food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff or the like. It is believed that this product is unique in its design and technologies.

Background

This background as to food machinery for fast processing should be useful. A significant portion of the cost of manufacturing certain food products results from the labor cost in handling such products during manufacturing and/or packaging. Conventional hamburgers have a meat patty in a bun along with various condiments and sauces. A variety of other types of hamburgers and sandwiches have recently become popular and are in high demand at food outlets. These include, for example, such items as the teriyaki burger (adding teriyaki sauce to a conventional hamburger), bacon and lettuce burgers, cheeseburgers with different types of cheeses, barbecue sauce burgers, fish sandwiches, chicken sandwiches, and roast beef sandwiches. New types and kinds of products are being introduced regularly. The words “hamburger” and “sandwich” are interchangeably used in this specification unless otherwise specified. One sees that a demand for increased productivity has arisen as a result of an increase in the number of consumers and increasingly diversified tastes.

Most of the food preparation has been manually performed. Each section for the preparation is independent of the others. Conventional kitchen productivity has been examined, analyzed, and improved many times, and it is difficult to make more improvements. An automated hamburger fixing apparatus has been developed to increase efficiency and reduce the required manual labor. Some of the apparatuses use a feeding and adding mechanism for each different element, condiment, or sauce. The application of this apparatus is limited due to the large/long footprint and amount of space required for the feeding and adding of multiple mechanisms. Changes are unwieldy due to the need to add another feeding and adding mechanism every time a new sauce or condiment is added to the menu. In addition, the control system of the machine has to be modified every time a change for feeding another condiment is made. Further, it is impossible to install such a long and complex apparatus in a small conventional kitchen or even a larger food preparation area.

In some other industries, various parts or products are placed into packets or pouches for health, sterile, convenience or protective reasons. These are then placed in large quantity boxes or other containers for ultimate delivery to the consumer or customer. Currently, placement of the food or other packets into the boxes or other shipping containers is done by hand, which is labor intensive and time consuming. Centrifugal precision feeders can be developed to aid in this process but they must be manufactured from a food grade material. The materials or food stuff can be then placed on the flexible, cleanable inner disc and are transferred from the inner disc to sorting mechanism and eventually fed to a next station. The use of a food grade centrifugal feeder system can remove the skewed orientation which traditionally has prevented rapid packaging of the material or the packages before they are placed in the shipping containers. Necessarily, equipment is needed for the efficient packaging of the food product. Quite often the equipment must be individually designed and built for the intended food product to be packaged. The equipment must be capable of receiving food in bulk, separating, or segregating it to desired serving sizes and packaging it. The equipment must be capable of handling copious amounts of the raw food product in a very fast manner so as to work efficiently and competitively with manual packaging operations. One food product in particular which is becoming more popular in package form are sandwiches. Hamburger and sausage sandwiches are quite common; however, they typically are not assembled by the food processor and packaged as a complete product ready for consumption. One reason for this is the lack of equipment to efficiently handle bread, buns or biscuits and combine them with a pre-cooked meat patty or fillet in sandwich form.

Problem Solved

The improved combination of an ultimate, cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff, is a system that is a compact footprint, is capable of automating the preparation of foodstuff with a process that is far more consistent and reliable. The machine is configured as a single path of belt which means it is easier to clean, permits the excess foodstuff and particulate to fall through an open belt design instead of recirculating in the system, is more hygienic, requires half the belt material, is easier to do maintenance, eliminates the need of a bearing chain, and permits an increase to the max speed of the unit due to less drag when running the system. The configuration has eliminated all horizontal surfaces, has a solid angle iron frame with the 90 degree angle pointed up and the “legs/sides” point downward at 45 degrees, has a feeder that has a vertical tool mounting ring and no longer uses horizontal tool segment plates to orient product rather it is a vertical holder such that the vertical tooling that does not need to be removed for cleaning, is faster for cleanup time, is faster for change overs between products, is easier for operators to run production/food preparation and is easier for an operator to perform maintenance. The ultimate configuration continues to have food grade surfaces for equipment, is on wheels to permit portability and fast installation, is washable and resistant to steam, continues to be a compact footprint for less use of floor space, has a versatile design for use with various foodstuffs (for changeover, and uses sort and feed components in the new combination and configuration.

The improved food grade feeder device and system is for rolls, sandwiches, oddly shaped edibles, and foodstuff. The improved centrifugal feeder with food grade components is a fast, precise, clean, and compact way to align and position food products such as rolls, meat, produce, and garnishments in way to reduce time and labor as well as fit into small locations. The invention overcomes a long-sought need of the food preparation industry that feeds millions at fast food restaurants, convenient marts, coffee houses and other “food on the go” companies.

Prior Art

A novelty search was completed for an Ultimate Cleanable Food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff. It revealed the following:

• • A. U.S. Pat. No. 9,532,575 by Donis, et al. was issued in 2017 is for an automated sandwich assembly unit. This teaches an automatic sandwich maker designed to automate the process of preparing sandwiches, including hamburgers, is included. This automated sandwich maker is designed for use in commercial kitchens, including small commercial kitchens, such as fast-food kitchens. The apparatus and method for automatically making sandwiches overcomes the drawbacks and limitations of the prior art. The individual sandwich process can be controlled by communications interface with a point of sales system. The inventive apparatus and method reduces manpower requirements for restaurants, provides enhanced ingredient control, and improves overall product quality.
  • B. U.S. Pat. No. 7,383,937 by Perreault, et al. was issued in 2008 is for an article feeder and spacer. This demonstrates a feeder for orienting and aligning disorderly incoming items includes a rotatable table having a peripheral wall and a discharge opening in the peripheral wall, the discharge opening allowing the items in a predetermined orientation to be successively withdrawn from the rotatable table in a single file line, the rotatable table being fed with disorderly items; a first carrier disposed proximate to the discharge opening, the first carrier recovering the oriented items exiting through the discharge opening; and an item spacer mounted proximate to the first carrier, the item spacer providing a predetermined spacing between two consecutive oriented items. It also relates to a method for doing same.
  • C. U.S. Pat. No. 7,228,953 by Perreault, et al. was issued in 2007 for an article feeder and spacer. Portrayed is a feeder for orienting and aligning disorderly incoming articles includes a table having a peripheral wall, a rotary surface surrounded by the peripheral wall, and a discharge substantially tangential to the peripheral wall, the discharge being sized to receive one article at a time from the rotary surface in a predetermined orientation; and at least one pile eliminating member extending above the rotary surface and defining a gap with the rotary surface, the gap being sized to solely permit passage of non-superposed articles laying in the predetermined orientation on the rotary surface. It also relates to a method for doing same and a method and an apparatus for removing obstructing blocks from the discharge.
  • D. U.S. Pat. No. 6,237,741 by Guidetti was issued in 2001 and is for a Process for controlling the operation of machines for processing articles, for example for packaging food products, and the machine thereof. Taught is a process for controlling the operation of machines for processing articles includes the step of synchronously controlling the movement or speed of a feeding device and an intake branch of the machine. The process provides a method of adapting a processing machine to adjust to discontinuities in an otherwise continuous flow of articles being supplied to the machine for processing. The process provides for the speed of the feeding device and the speed of the intake branch to both be reduced simultaneously. The speed of the feeding device is slowed sufficiently that it obtains a minimum speed at the time that the perceived discontinuity reaches the interface of the feeding device and the intake branch. Simultaneously, the speed of the intake branch is reduced to a substantially standstill condition at the time that the feeding device obtains its minimum speed. The process may further provide for the standstill condition of the intake branch to be maintained until the first article, positioned after the detected discontinuity, reaches the intake branch. The process may then provide for the reactivation of the intake branch so as to bring the feeding device and the intake branch back to their normal operating conditions.
  • E. U.S. Pat. No. 5,634,551 by Francioni, et al. was issued in 1997 and is for a Method and apparatus for regulating the advancing movement of articles, for example in installations for the automatic packaging of food products. Shown and explained is a device for regulating the advancing movement of articles in a given direction comprises a plurality of conveyors, such as for example belt conveyors, between an input supply conveyor and a positive drive output conveyor operating to supply, for example, a packaging machine. To adapt automatically to the handling of articles with different lengths, at least some of the aforesaid conveyors, intended to perform a phasing action of the advancing movement of the articles, are chosen with different lengths so as to form a set which is able to deal with the possible range of variation in the length of the articles dealt with, by coupling several conveyors in cascade. Preferably, the conveyor at the downstream end has a selectively controllable length varied in dependence on the length of the articles being handled.
  • F. U.S. Pat. No. 5,540,943 by Naramura was issued in 1996 is for a Sandwich preparation apparatus. Displayed is a sandwich preparation apparatus includes a food material conveyor having an upstream end region and a downstream finishing end region. The bottom part of a sandwich or burger, including a bun half or slice of bread, has sauces and condiments, and a patty if necessary, automatically added by a first automatic fixing section in the upstream end region. The upper part of the sandwich, optionally including additional sauces, condiments, and patties, is completed by a second automatic fixing section in the downstream finishing end region. Between the two regions is a manual fixing section for an operator to manually add various food materials to the sandwich. The operator controls the automatic fixing sections through first and second input devices and an order display device. The operator is able to change the order or sequence of sandwiches between the upstream end region and the downstream end region using the second input device. The operator is thus able to make allowances for different cooking or preparation times for different types of sandwiches.
  • G. U.S. Pat. No. 5,299,675 by Schumann, et al. was issued in 1994 is for a Pouch feeder method and device with angled rim. Here is shown a precision feeding device for soft and hard packaged articles includes an angled rim for improved feeding and alignment. Separated rollers are placed between a rigid plate and a flexible disc to further enhance the operation and durability of the device.
  • H. U.S. Pat. No. 5,101,716 by Cones, Sr. et al. was issued in 1992 and is for an Apparatus for assembling biscuit sandwiches. Provided is an apparatus for the assembly of biscuit and meat sandwiches comprises a feeder station for receiving whole biscuits, a slicer station for slicing the biscuits in half, a separator station for separating the two halves of the biscuit and sending them along separate pathways, and an assembly station having a hold station where precooked meat patties are held and where the biscuit halves and the meat patties are assembled into a sandwich ready for packaging. A series of conveyors transport the food components between the stations.
  • I. U.S. Pat. No. 5,044,487 by Spatafora, et al. was issued in 1991 is for a Product aligning device, particularly for supplying wrapping machines. Demonstrated is a device for aligning products, wherein an annular body turning about its axis presents an annular end surface defining a first route for the product items arranged in line, and an inner lateral surface defining, with the upper surface of a flat disc turning about its axis and on to which the product is fed in bulk, a second annular route for the product; the annular body being inclined in relation to the disc; so as to define a first junction between the first and second route, and a second junction between the first route and a third route defined by an output conveyor tangent to the annular body; the disc being fed in bulk with the product items, which are fed, by centrifugal force, on to the second route and then, one by one, on to the first route via the first junction and on to the third route via the second junction.
  • J. U.S. Pat. No. 4,530,632 by Sela issued in 1985 was issued for a Stacking apparatus for flexible, generally planar food products. This apparatus is an apparatus for counting and stacking food products such as tortillas. The tortillas are initially placed on an entry chute containing a large number of air outlets for creating a cushion of air to allow the tortilla to slide down the entry chute onto an incline conveyor belt. The conveyor belt is of an open mesh design and it is supported on a belt support having a large number of air inlets which create a vacuum that maintains the tortilla in contact with the belt. The tortillas are carried by the belt down one end of the belt support and along the underside of the belt support with contact between the tortilla and belt being maintained by vacuum creating air inlets formed in the belt support. The air inlets terminate at a location on the underside of the belt support thereby allowing the tortillas to drop from the conveyor belt. The tortillas drop onto a stationary rack formed by rods which are interleaved with conveyor belts moving together as a unit. The conveyor belts are normally positioned beneath the upper surface of the rack. However, when a predetermined number of tortillas have been stacked, the belt is lifted thereby carrying the tortillas from the rack. The mechanism for lifting the belts is actuated by a counter which counts a predetermined number of tortillas passing past a counting station and delays actuating the belt lifting mechanism until the final tortilla has dropped onto the rack. The belts discharging the stacks of tortillas move in the direction opposite the direction that the tortillas are delivered to the rack to minimize the time required to remove the tortillas from the rack before an additional tortilla may be placed thereon. And,
  • K. U.S. Pat. No. 3,224,554 by J. E. Mouldert et. al. was issued in 1965 is for an Automatic Orientation, Alignment, and input feeding machinery for confectionary articles. This shows an automatic systems for handling large masses of confectionary articles and in particular to automatic input feeding machinery for lining up and feeding confectionary articles in predetermined orientation into apparatus for further operations to be performed upon them. The automatic input machinery described herein as illustrative of the invention is particularly adapted for receiving a large group or bulk of freshly made non-circular confections in random orientation and for gently sorting out this large mass of the confections and for feeding them along a line into positions and at a proper supply rate and in predetermined orientation for further operations on the confections, while avoiding any damage or marring of the freshly made product.

As can be observed, none of the prior art has anticipated or caused one skilled in the food processing and preparation art to see this new invention as obvious to one skilled in the industry. The Ultimate Cleanable Food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff provides an answer to a clean, compact, and fast manner to organized, align and singularly foodstuffs such as rolls, buns, meats, and other food in a compact and efficient manner.

SUMMARY OF THE INVENTION

This invention is an ultimate, cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff. Taught here are the ways that food preparation can be clean, fast, compact, and efficient. The newly invented feeder device has various applications.

The preferred embodiment is an ultimate food grade feeder device and system comprised of: (a) a centrifugal feeder bowl with a cone cap made of a durable and food grade material, and a rigid disk base plate; (b) a group of selection devices; (c) a support structure; (d) an electrical drive motor and gear box to rotationally turn/spin the centrifugal base plate with a feeder vertical drive shaft and at least two bearings for rotationally securing drive shaft to the feeder support structure; and (e) a single conveyor system configured as a single path of belt with a drive system including a motor, a gearbox, a driven sprockets/pulleys, and a shaft for each conveyor wherein the ultimate food grade feeder device and system organizes, orients, and aligns a group of foodstuff item so that the aligned group of foodstuff items can be transferred to other machinery and/or humans to further process and package the foodstuff items.

OBJECTS AND ADVANTAGES

There are several objects and advantages of the food grade feeder device and system for rolls, sandwiches, oddly shaped edibles, and foodstuff. These various advantages and benefits include:

Item Advantages
1    Configured as a single path of belt
     1) Easier to clean
     2) Particulate falls through open belt design
     instead of recirculating in the system
     3) More hygienic
     4) Requires half the belt material
     5) Easier to do maintenance
     6) Eliminated the need of bearing chain
     7) Was able to increase the max speed of the
     unit due to less drag when running
2    Eliminated all horizontal surfaces
     1) Solid angle iron frame with point up
     2) Vertical Feeder mount plate no longer uses
     horizontal tool segment plates to orient
     product
     3) Instead uses vertical tooling that does not
     need to be removed for cleaning
     4) Faster clean up times
     5) Faster change overs between products
     6) Easier for operators to run production
     7) Easier to perform maintenance
3    Food grade surface for equipment
4    On wheels to permit portability and fat
     installation
5    Washable and resistant to steam
6    Compact footprint for less use of floor space
7    Versatile designs for use with various foodstuffs—can
     be easily changed to handle different shapes
     and styles of foodstuffs
8    Uses a set of sort and feed components in a new combination

Finally, other advantages and additional features of the present Ultimate Cleanable Food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff

• • will be more apparent from the accompanying drawings and from the full description of the device. For one skilled in the art of fast-food preparation and food preparation, it is readily understood that the features shown in the examples with this product are readily adapted to other types of compact and fast-food processing equipment and tools.

DESCRIPTION OF THE DRAWINGS—FIGURES

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate an embodiment of the ultimate, cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff that is preferred. The drawings together with the summary description given above and a detailed description given below serve to explain the principles of the ultimate, cleanable food grade feeding device. It is understood, however, that the feeding device and system is not limited to only the precise arrangements and instrumentalities shown.

FIG. 1 A through 1 D are sketches of the ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff.

FIGS. 2 A through 2 E are sketches of the ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles and foodstuff from a top, front, sides, and an isometric view, with components and features noted.

FIGS. 3 A and 3 B are sketches of isometric views with and without the conveyor belt and with components and features noted.

FIGS. 4 A and 4 B are another isometric sketch of the ultimate, cleanable food grade feeder and a side view of the food grade feeder with the conveyor belt removed to demonstrate the support structure as well as the path of the conveyor belt.

FIGS. 5 A and 5 B are sketches of the ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles and foodstuff food grade feeder device and system for rolls, sandwiches, oddly shaped edibles, and foodstuff, from generally a left-handed and a right-handed isometric view with components and features noted.

FIGS. 6 A and 6 B are top views of the ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff shown with and without the conveyor belt and portraying the components and features.

FIGS. 7 A and 7 B are side views of the ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff portraying the components and features.

FIG. 8 is a front view of the ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff demonstrating the components and features.

FIG. 9 A through 9 E are sketches of prior art.

DESCRIPTION OF THE DRAWINGS—REFERENCE NUMERALS

The following list refers to the drawings:

TABLE B
Reference numbers
Ref #   Description
30      ultimate cleanable food grade feeder device
        and system 30 for rolls, sandwiches, odd-
        shaped edibles, and foodstuff
30T     top view 30T of the ultimate cleanable food grade
        feeder device and system 30
30I     isometric view 30I of the ultimate cleanable food
        grade feeder device and system 30
30RS    right side view 30RS of the ultimate cleanable food
        grade feeder device and system 30
30LS    left side view 30LS of the ultimate cleanable food
        grade feeder device and system 30
30      side view with wheels and no belt 30 No Belt
No Belt of the food grade feeder device and system 30
30F     front view 30F of the ultimate cleanable food
        grade feeder device and system 30
35      single conveyor system 35 of the food grade
        feeder device and system 30 configured as a
        single path of belt with singulation or
        separate and feed one part at a time
36      side view 36 of single belt path
37      dual conveyor system 37 of the food grade
        feeder device and system 30 configured as a
        dual path of belt with singulation or separate
        and feed one part at a time
38      side view 38 of single belt path
40      centrifugal feeder bowl 40
40A     exterior surface 40A of feeder bowl 40
41      selection sensor 41
42      food grade ABS plastic, stainless steel, food
        grade composite materials, or equal durable
        material cone cap 42
43      rigid disk base plate 43 (bottom of cone 42)
46      feeder vertical drive shaft 46
47      at least two bearings 47 for rotationally
        securing drive shaft 46 to feeder support
        structure 50
48C     a drive system 48C—motor, gearbox, driven
        sprockets/pulleys, and shaft for the single
        belt conveyor 35
48D     drive system 48D—motor, gearbox, chain/belts
        between drive and driven sprockets/pulleys
        between motor 48D and shaft 46 to ultimately
        turn the centrifugal base plate 43
49      height qualifier 49 shaft, plate, or equal
50      support structure 50 under the food grade
        feeder device and conveyors—has a solid angle
        iron frame with the 90-degree angle pointed up
        and the ″legs/ sides″ point downward at 45
        degrees
54      wheels or castors 54 at the floor of the
        structure 50 legs
70      electrical power and control panel 70 with
        feeder operator control
80      return channel 80
81      good food channel 81
82      flip device 82
90      foodstuff and rolls 90 being oriented and fed
        through the food grade feeder device and
        system 30
93      selection tooling (orientation and quantity)
        and zone 93
95      support plate pads/feet 95
100     prior art 100 U.S. Pat. No. 5,299,675 by Schumann,
        et al. issued in 1994 is for a Pouch feeder
        method and device with angled rim.
101     prior art 101 U.S. Pat. No. 5,540,943 by Naramura
        issued in 1996 is for a Sandwich preparation
        apparatus.
102     prior art 102 U.S. Pat. No. 5,101,716 by Cones,
        Sr. et al. issued in 1992 is for an Apparatus
        for assembling biscuit sandwiches.
103     prior art 103 U.S. Pat. No. 9,532,575 by Donis, et
        al. issued in 2017 is for an Automated
        sandwich assembly unit.
104     prior art 104 U.S. Pat. No. 10,988,324 by
        Schombert in 2021 is for a food grade feeder
        device and system for rolls, sandwiches, odd-
        shaped edibles, and foodstuff

DETAILED DESCRIPTION OF PREFERRED EMBODIMENT

This invention relates to an ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff. The present disclosure relates generally to the preparation of food products and, more particularly, but not by way of limitation, to preparing sandwiches. It also relates to a sandwich preparation apparatus or food handling system that incorporates a system that automates the process. The present invention relates to a clean product aligning device. This invention relates to an apparatus for the assembling of biscuit or roll sandwiches. More particularly, it relates to an apparatus for the faster, more compact assembling of biscuit sandwiches ready for packaging by a centrifugal feeder bowl. Also, because of its food-grade materials, it relates to a large capacity centrifugal precision feeder which can be utilized to aid in packaging, for instance, food, medical, pharmaceutical, and military special handling products.

The advantages for the ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff are listed above in the introduction. Succinctly the benefits are that the device and system:

• • A. Configured as a single path of belt
    • 1) Easier to clean,
    • 2) Particulate falls through open belt design instead of recirculating in the system,
    • 3) More hygienic,
    • 4) Requires half the belt material,
    • 5) Easier to do maintenance,
    • 6) Eliminated the need of bearing chain, and
    • 7) Was able to increase the max speed of the unit due to less drag when running;
  • B. Eliminated all horizontal surfaces
    • 1) Solid angle iron frame with point up—has a solid angle iron frame with the 90-degree angle pointed up and the “legs/sides” point downward at 45 degrees,
    • 2) Feeder no longer uses horizontal tool segment plates to orient product,
    • 3) Instead uses vertical tooling that does not need to be removed for cleaning,
    • 4) Faster clean up times,
    • 5) Faster change overs between products,
    • 6) Easier for operators to run production, and
    • 7) Easier to perform maintenance;
  • C. Food grade surface for equipment;
  • D. On wheels to permit portability and fat installation;
  • E. Washable and resistant to steam;
  • F. Compact footprint for less use of floor space;
  • G. Versatile designs for use with various foodstuffs—can be easily changed to handle different shapes and styles of foodstuffs; and
  • H. Uses a set of sort and feed components in a new combination.

The preferred embodiment is an ultimate food grade feeder device and system 30 comprised of: (a) a centrifugal feeder bowl 40 with a cone cap 42 made of a durable and food grade material, and a rigid disk base plate 43; (b) a group of selection devices; (c) a support structure 50; (d) an electrical drive motor and gear box 44 to rotationally turn/spin the centrifugal base plate 43 with a feeder vertical drive shaft 46 and at least two bearings 47 for rotationally securing drive shaft 46 to the feeder support structure 50; and (e) a single conveyor system 35 configured as a single path of belt with a drive system including a motor, a gearbox, a driven sprockets/pulleys, and a shaft for each conveyor wherein the ultimate food grade feeder device and system organizes, orients, and aligns a group of foodstuff item so that the aligned group of foodstuff items can be transferred to other machinery and/or humans to further process and package the foodstuff items.

There is shown in FIGS. 1-9 a complete description and operative embodiment of the ultimate and cleanable food feeder device and system 30. In the drawings and illustrations, one notes well that the FIGS. 1-9 demonstrate the general configuration and use of this product. The various example uses are in the operation and use section, below.

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate an embodiment of the ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles, and foodstuff that is preferred. The drawings together with the summary description given above and a detailed description given below serve to explain the principles of the ultimate and cleanable food feeder device and system 30. It is understood, however, that the device and system 30 is not limited to only the precise arrangements and instrumentalities shown. Other examples of food feeding machines and systems and their uses are still understood by one skilled in the art of food feeding equipment and devices to be within the scope and spirit shown here.

FIGS. 1 A through 1 D are sketches of the ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles, and foodstuff. Viewed here are: an ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles, and foodstuff; a top view 30T of the ultimate cleanable food grade feeder device and system 30; an isometric view 301 of the ultimate cleanable food grade feeder device and system 30; and a front view 30F of the ultimate cleanable food grade feeder device and system 30.

FIGS. 2 A through 2 E are sketches of the ultimate cleanable food grade feeder device and system for rolls, sandwiches, odd-shaped edibles and foodstuff from a top, front, sides, and an isometric view, with components and features noted. Shown in these sketches are: an ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles and foodstuff; a top view 30T of the ultimate cleanable food grade feeder device and system 30; a isometric view 301 of the ultimate cleanable food grade feeder device and system 30; a right side view 30RS of the ultimate cleanable food grade feeder device and system 30; a left side view 30LS of the ultimate cleanable food grade feeder device and system 30; a front view 30F of the ultimate cleanable food grade feeder device and system 30; a dual conveyor system 37 of the food grade feeder device and system 30 configured as a dual path of belt with singulation or separate and feed one part at a time; a centrifugal feeder bowl 40; an exterior surface 40A of feeder bowl 40; a selection sensor 41; a food grade ABS plastic, stainless steel, food grade composite materials, or equal durable material cone cap 42; a drive system 48C—motor, gearbox, driven sprockets/pulleys and shaft for the single belt conveyor 35; a drive system 48D—motor, gearbox, chain/belts between drive and driven sprockets/pulleys between motor 48D and shaft 46 to ultimately turn the centrifugal base plate 43; a height qualifier 49 shaft, plate, or equal; a support structure 50 under the food grade feeder device and conveyors—has a solid angle iron frame with the 90-degree angle pointed up and the “legs/sides” point downward at 45 degrees; a set of wheels or castors 54 at the floor of the structure 50 legs; an electrical power and control panel 70 with feeder operator control; a return channel 80; a good food channel/exit/transfer point 81; a flip device 82; a foodstuff and rolls 90 being oriented and fed through the food grade feeder device and system 30; and a set of selection tooling (orientation and quantity) and zone 93 on a vertical tool holding ring.

FIGS. 3 A and 3 B are sketches of isometric views with and without the conveyor belt and with components and features noted. Seen here are an ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles and foodstuff; a side view with wheels and no belt 30; No Belt of the food grade feeder device and system 30; a single conveyor system 35 of the food grade feeder device and system 30 configured as a single path of belt with singulation or separate and feed one part at a time; a centrifugal feeder bowl 40; an exterior surface 40A of feeder bowl 40; a selection sensor 41; a food grade ABS plastic, stainless steel, food grade composite materials, or equal durable material cone cap 42; a drive system 48C—motor, gearbox, driven sprockets/pulleys and shaft for the single belt conveyor 35; a drive system 48D—motor, gearbox, chain/belts between drive and driven sprockets/pulleys between motor 48D and shaft 46 to ultimately turn the centrifugal base plate 43; a height qualifier 49 shaft, plate, or equal; a set of wheels or castors 54 at the floor of the structure 50 legs; a good food channel/exit/transfer point 81; a foodstuff and rolls 90 being oriented and fed through the food grade feeder device and system 30; and support plate pads/feet 95.

FIGS. 4 A and 4 B are another isometric sketch of the ultimate, cleanable food grade feeder 30 and a side view 35 of the food grade feeder with the conveyor belt removed to demonstrate the support structure as well as the path of the conveyor belt. Demonstrated by these sketches are the following: an ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles and foodstuff; a single conveyor system 35 of the food grade feeder device and system 30 configured as a single path of belt with singulation or separate and feed one part at a time; a side view 36 of single belt path; a centrifugal feeder bowl 40; an exterior surface 40A of feeder bowl 40; a selection sensor 41; a food grade ABS plastic, stainless steel, food grade composite materials, or equal durable material cone cap 42; a rigid disk base plate 43 (bottom of cone 42); a feeder vertical drive shaft 46; at least two bearings 47 for rotationally securing drive shaft 46 to feeder support structure 50; a drive system 48C—motor, gearbox, driven sprockets/pulleys and shaft for the single belt conveyor 35; a drive system 48D—motor, gearbox, chain/belts between drive and driven sprockets/pulleys between motor 48D and shaft 46 to ultimately turn the centrifugal base plate 43; a height qualifier 49 shaft, plate, or equal; a support structure 50 under the food grade feeder device and conveyors—has a solid angle iron frame with the 90-degree angle pointed up and the “legs/sides” point downward at 45 degrees; a set of wheels or castors 54 at the floor of the structure 50 legs; a foodstuff and rolls 90 being oriented and fed through the food grade feeder device and system 30; a selection tooling (orientation and quantity) and zone 93; and a set of support plate pads/feet 95.

FIGS. 5 A and 5 B are sketches of the ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles and foodstuff food grade feeder device and system for rolls, sandwiches, odd, shaped edibles, and foodstuff, from generally a left-handed and a right-handed isometric view with components and features noted. Demonstrated in these sketches are: an ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles and foodstuff; an isometric view 301 of the ultimate cleanable food grade feeder device and system 30; a dual conveyor system 37 of the food grade feeder device and system 30 configured as a dual path of belt with singulation or separate and feed one part at a time; a centrifugal feeder bowl 40; an exterior surface 40A of feeder bowl 40; a selection sensor 41; a food grade ABS plastic, stainless steel, food grade composite materials, or equal durable material cone cap 42; a rigid disk base plate 43 (bottom of cone 42); a drive system 48C—motor, gearbox, driven sprockets/pulleys and shaft for the single belt conveyor 35; a drive system 48D—motor, gearbox, chain/belts between drive and driven sprockets/pulleys between motor 48D and shaft 46 to ultimately turn the centrifugal base plate 43; a height qualifier 49 shaft, plate, or equal; a support structure 50 under the food grade feeder device and conveyors—has a solid angle iron frame with the 90-degree angle pointed up and the “legs/sides” point downward at 45 degrees; a set of wheels or castors 54 at the floor of the structure 50 legs; an electrical power and control panel 70 with feeder operator control; a return channel 80; a good food channel/exit/transfer point 81; a flip device 82; and a set of selection tooling (orientation and quantity) and zone 93.

FIGS. 6 A and 6 B are top views of the ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles, and foodstuff shown with and without the conveyor belt and portraying the components and features. Portrayed here are: an ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles and foodstuff; a top view 30T of the ultimate cleanable food grade feeder device and system 30; a top view with wheels and no belt 30 No Belt of the food grade feeder device and system 30; a dual conveyor system 37 of the food grade feeder device and system 30 configured as a dual path of belt with singulation or separate and feed one part at a time; a centrifugal feeder bowl 40; an exterior surface 40A of feeder bowl 40; a selection sensor 41; a food grade ABS plastic, stainless steel, food grade composite materials, or equal durable material cone cap 42; a height qualifier 49 shaft, plate, or equal; an electrical power and control panel 70 with feeder operator control; a return channel 80; a good food channel/exit/transfer point 81; a flip device 82; a foodstuff and rolls 90 being oriented and fed through the food grade feeder device and system 30; and a set of selection tooling (orientation and quantity) and zone 93.

FIGS. 7 A and 7 B are side views 30LS, 30RS of the ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles, and foodstuff 90 portraying the components and features. These drawings show: an ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles and foodstuff; a right side view 30RS of the ultimate cleanable food grade feeder device and system 30; a left side view 30LS of the ultimate cleanable food grade feeder device and system 30; a drive system 48C—motor, gearbox, driven sprockets/pulleys and shaft for the single belt conveyor 35; a drive system 48D—motor, gearbox, chain/belts between drive and driven sprockets/pulleys between motor 48D and shaft 46 to ultimately turn the centrifugal base plate 43; a support structure 50 under the food grade feeder device and conveyors—has a solid angle iron frame with the 90-degree angle pointed up and the “legs/sides” point downward at 45 degrees; a set of wheels or castors 54 at the floor of the structure 50 legs; and an electrical power and control panel 70 with feeder operator control.

FIG. 8 is a front view 30F of the ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles, and foodstuff demonstrating the components and features. Representative sketches show: an ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles and foodstuff; a front view 30F of the ultimate cleanable food grade feeder device and system 30; a dual conveyor system 37 of the food grade feeder device and system 30 configured as a dual path of belt with singulation or separate and feed one part at a time; an exterior surface 40A of feeder bowl 40; a drive system 48C—motor, gearbox, driven sprockets/pulleys and shaft for the single belt conveyor 35; a support structure 50 under the food grade feeder device and conveyors—has a solid angle iron frame with the 90-degree angle pointed up and the “legs/sides” point downward at 45 degrees;

• • a set of wheels or castors 54 at the floor of the structure 50 legs; and an electrical power and control panel 70 with feeder operator control.

The anticipated materials 39 include: for the part contact surfaces—an ABS Plastic Disc, a 304 Stainless Steel Tooling ring, an FDA approved Acetal belt material or equal for each conveyor, a 304 Stainless Steel Reorientation Cam, a 304 Stainless Steel Height Qualifier, Frame Construction—a 304 Stainless Steel Tubing with wash down casters and docking station. Sizes and construction details anticipated are: Center Disc 50-inch diameter Minimum; Inner conveyors 45 inch diameter minimum; Outer conveyors 65 to 70 inch diameter minimum; three (3) wash down motor/gearbox w/common part numbers; all bearings to be sealed and greasable with Zerk fittings and pointing outwardly for access; and, a drive pulley to be of a griptwist material or equal. As durable and high temperature composite materials are developed, it is anticipated they can replace some of the Stainless-Steel components.

FIG. 9 A through 9 E are sketches of prior art. Here former patents and applications for food feeding machinery devices and systems are shown. These include: prior art 100 U.S. Pat. No. 5,299,675 by Schumann, et al. issued in 1994 is for a Pouch feeder method and device with angled rim; prior art 101 U.S. Pat. No. 5,540,943 by Naramura issued in 1996 is for a Sandwich preparation apparatus; prior art 102 U.S. Pat. No. 5,101,716 by Cones, Sr. et al. issued in 1992 is for an Apparatus for assembling biscuit sandwiches; prior art 103 U.S. Pat. No. 9,532,575 by Donis, et al. issued in 2017 is for an Automated sandwich assembly unit; and, a prior art 104 U.S. Pat. No. 10,988,324 by Schombert issued in 2021 is for a food grade feeder device and system for rolls, sandwiches, odd-shaped edibles and foodstuff. As can be seen, the novel and ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles, and foodstuff as compared to prior art is a unique combination and use as described herein.

The details mentioned here are exemplary and not limiting. Other specific components and manners specific to describing an ultimate cleanable food feeder device and system 30 may be added as a person having ordinary skill in the field of the art of food feeding equipment and their uses well appreciates.

Operation of the Preferred Embodiment

The ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles, and foodstuff has been described in the above embodiment. The manner of how the device operates is described below. One notes well that the description above and the operation described here must be taken together to fully illustrate the concept of the new ultimate, cleanable food feeder device 30. The preferred embodiment is an ultimate food grade feeder device and system 30 comprised of: (a) a centrifugal feeder bowl 40 with a cone cap 42 made of a durable and food grade material, and a rigid disk base plate 43; (b) a group of selection devices; (c) a support structure 50; (d) an electrical drive motor and gear box 44 to rotationally turn/spin the centrifugal base plate 43 with a feeder vertical drive shaft 46 and at least two bearings 47 for rotationally securing drive shaft 46 to the feeder support structure 50; and (e) a single conveyor system 35 configured as a single path of belt with a drive system including a motor, a gearbox, a driven sprockets/pulleys, and a shaft for each conveyor wherein the ultimate food grade feeder device and system organizes, orients, and aligns a group of foodstuff item so that the aligned group of foodstuff items can be transferred to other machinery and/or humans to further process and package the foodstuff items.

The feeding system theory of operation is as follows:

• • A. rolls are dumped manually onto center disc;
  • B. center disc rotates clockwise and transfers rolls at random onto inner conveyor at the load area;
  • C. The transfer conveyor and center disc speed approximately 50 feet per minute;
  • D. There is a vertical stainless steel “tooling ring” at load area;
  • E. Rolls incline from the feeder to a height qualifying cam that rejects double stacked rolls back onto center disc for recirculation. Rolls are still in random orientation;
  • F. After rolls are single layer, they are directed to the exit lane 81 that is running at a speed of approximately 70 feet per minute;
  • G. The selection sensor determines the orientation of the roll;
  • H. If the roll is right side up it allows it to pass downstream to slicer or next step in the process;
  • I. If roll is upside down, selection cylinder extends pushing the roll back onto the return chute 80;
  • J. Upside down roll travels through return tooling to flip the roll right side up and onto the outer conveyor below;
  • K. The re-oriented roll travels unobstructed on the conveyor behind the load area;
  • L. Re-oriented rolls are directed back onto the disk 42 for re-orientation; and
  • M. When downstream high-level sensor on the slicer conveyor is satisfied, a high-level reject cylinder extends and rejects all rolls back onto center disc for recirculation until sensor calls for product.

Many different uses are anticipated for the ultimate, cleanable food feeder and system 30. Some examples, and not limitations, are shown in the following Table.

ITEM DESCRIPTION
1    sandwich rolls and buns
2    disk-like vegetables such as
     lettuce, onions, tomatoes
3    include preform meat patties
4    pre-cooked meats such as ham,
     hamburgers, turkey, pork, etc.
5    preformed cheese disks or strips

With this description it is to be understood that the ultimate cleanable food grade feeder device and system 30 for rolls, sandwiches, odd-shaped edibles, and foodstuff and is not to be limited to only the disclosed embodiment of product. The features of the present invention 30 are intended to cover various modifications and equivalent arrangements included within the spirit and scope of the description.

While certain novel features of this invention have been shown and described and are pointed out in the annexed claims, it is not intended to be limited to the details above, since it will be understood that various omissions, modifications, substitutions and changes in the forms and details of the device illustrated and in its operation can be made by those skilled in the art without departing in any way from the spirit of the present invention. Without further analysis, the foregoing will so fully reveal the gist of the present invention that others can, by applying current knowledge, readily adapt it for various applications without omitting features that, from the standpoint of prior art, fairly constitute essential characteristics of the generic or specific aspects of this invention.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which these inventions belong. Although any methods and materials similar or equivalent to those described herein can also be used in the practice or testing of the present inventions, the preferred methods and materials are now described above in the foregoing paragraphs.

Other embodiments of the invention are possible. Although the description above contains much specificity, these should not be construed as limiting the scope of the invention, but as merely providing illustrations of some of the presently preferred embodiments of this invention. It is also contemplated that various combinations or sub-combinations of the specific features and aspects of the embodiments may be made and still fall within the scope of the inventions. It should be understood that various features and aspects of the disclosed embodiments can be combined with or substituted for one another in order to form varying modes of the disclosed inventions. Thus, it is intended that the scope of at least some of the present inventions herein disclosed should not be limited by the particular disclosed embodiments described above.

The terms recited in the claims should be given their ordinary and customary meaning as determined by reference to relevant entries (e.g., definition of “plane” as a carpenter's tool would not be relevant to the use of the term “plane” when used to refer to an airplane, etc.) in dictionaries (e.g., widely used general reference dictionaries and/or relevant technical dictionaries), commonly understood meanings by those in the art, etc., with the understanding that the broadest meaning imparted by any one or combination of these sources should be given to the claim terms (e.g., two or more relevant dictionary entries should be combined to provide the broadest meaning of the combination of entries, etc.) subject only to the following exceptions: (a) if a term is used herein in a manner more expansive than its ordinary and customary meaning, the term should be given its ordinary and customary meaning plus the additional expansive meaning, or (b) if a term has been explicitly defined to have a different meaning by reciting the term followed by the phrase “as used herein shall mean” or similar language (e.g., “herein this term means,” “as defined herein,” “for the purposes of this disclosure [the term] shall mean,” etc.). References to specific examples, use of “i.e.,” use of the word “invention,” etc., are not meant to invoke exception (b) or otherwise restrict the scope of the recited claim terms. Other than situations where exception (b) applies, nothing contained herein should be considered a disclaimer or disavowal of claim scope. Accordingly, the subject matter recited in the claims is not coextensive with and should not be interpreted to be coextensive with any particular embodiment, feature, or combination of features shown herein. This is true even if only a single embodiment of the particular feature or combination of features is illustrated and described herein. Thus, the appended claims should be read to be given their broadest interpretation in view of the prior art and the ordinary meaning of the claim terms.

Unless otherwise indicated, all numbers or expressions, such as those expressing dimensions, physical characteristics, etc. used in the specification (other than the claims) are understood as modified in all instances by the term “approximately.” At the very least, and not as an attempt to limit the application of the doctrine of equivalents to the claims, each numerical parameter recited in the specification or claims which is modified by the term “approximately” should at least be construed in light of the number of recited significant digits and by applying ordinary rounding techniques.

The present invention contemplates modifications as would occur to those skilled in the art. While the disclosure has been illustrated and described in detail in the figures and the foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only selected embodiments have been shown and described and that all changes, modifications and equivalents that come within the spirit of the disclosures described heretofore and or/defined by the following claims are desired to be protected.

Claims

1. An ultimate food grade feeder device and system (30) comprised of: (a) a centrifugal feeder bowl (40) with a cone cap (42) made of a durable and food grade material, and a rigid disk base plate (43);(b) a group of selection devices;(c) a support structure (50);(d) an electrical drive motor and gear box (44) to rotationally turn/spin the centrifugal base plate (43) with a feeder vertical drive shaft (46) and at least two bearings (47) for rotationally securing drive shaft (46) to the feeder support structure (50); and(e) a single conveyor system (35) configured as a single path of belt with a drive system including a motor, a gearbox, a driven sprockets/pulleys, and a shaft for each conveyor;

2. The food grade feeder device and system (30) in claim 1 further comprised with wheels (54) attached to the support structure (50).

3. The food grade feeder device and system (30) in claim 2 wherein the durable and food grade material of the cone cap is selected from a group consisting of a food grade ABS plastic, a stainless steel, and a food grade composite material.

4. The food grade feeder device and system (30) in claim 2 wherein the selection device is selected from a group consisting of selection sensor (41), a height qualifier plate (49), a flip device (82), a return channel (80), and a good food channel (81).

5. The food grade feeder device and system (30) in claim 2 wherein the foodstuff item is selected from a group consisting of rolls, sandwiches, oddly shaped edibles, and other materials.

6. The food grade feeder device and system (30) in claim 1 wherein the gearbox for the single conveyor item is selected from a group consisting of a gear box with sprockets and chains and a gearbox with pulleys and belts.

7. An ultimate food grade feeder device and system (30) comprised of: (a) a centrifugal feeder bowl (40) with a cone cap (42) made of a durable and food grade material, and a rigid disk base plate (43);(b) a group of selection devices;(c) a support structure (50);(d) an electrical drive motor and gear box (44) to rotationally turn/spin the centrifugal base plate (43) with a feeder vertical drive shaft (46) and at least two bearings (47) for rotationally securing drive shaft (46) to the feeder support structure (50); and(e) a dual conveyor system (37) configured with a double path of belt with a drive system including a motor, a gearbox, and a shaft for each conveyor

8. The food grade feeder device and system (30) in claim 7 further comprised with wheels (54) attached to the support structure (50).

9. The food grade feeder device and system (30) in claim 8 wherein the durable and food grade material of the cone cap is selected from a group consisting of a food grade ABS plastic, a stainless steel, and a food grade composite material.

10. The food grade feeder device and system (30) in claim 9 wherein the selection device is selected from a group consisting of selection sensor (41), a height qualifier plate (49), a flip device (82), a return channel (80), and a good food channel (81).

11. The food grade feeder device and system (30) in claim 9 wherein the foodstuff item is selected from a group consisting of rolls, sandwiches, oddly shaped edibles, and other materials.

12. The food grade feeder device and system (30) in claim 7 wherein the gearbox for the dual conveyor item is selected from a group consisting of a gear box with sprockets and chains and a gearbox with pulleys and belts.