Food product handling machine

FIELD OF THE INVENTION

This invention relates to food handling machines and more particularly, to machines that convey food portions between various food processing machines.

BACKGROUND OF INVENTION

In modern food production, the food product undergoes a number of processes in a complex system of food processing machinery to transform the raw product into a finished product suitable for packaging. This food processing machinery may include, among others, food preparation, portioning, and packaging machines as well as the machinery required to convey the food product from one processing machine to another.

A conveyor system commonly found in the production of food product that is of a solid or semi-solid form is the pocket conveyor. Pocket conveyors consist of a number of linked-together pockets that are transported from one machine to another. Each pocket receives a food portion at one machine and conveys the food portion to a second machine. The linked-together pockets are carried by a single lane conveyor, driven by a drive chain, in a continuous circuit between a first machine and a second machine and back again to the first machine. The chain, or in other designs, the linked-together pockets themselves, is coupled between a drive sprocket and an idler sprocket where the drive sprocket is driven by a motor.

Pocket conveyors are frequently used between a machine that portions the food product into portions suitable for packaging and a machine that packages the food portion into containers. The chained or linked-together pockets travel in a continuous circuit between the portioning machine and the packaging machine. Machines of this type require that the chain of pockets be incrementally stopped for each pocket at the portioning machine in order for a pocket to receive a portion of food. The chain is restarted and incrementally stopped again at the packaging machine to present the portion of food to the packaging machine. The starting and stopping movement of the chain is not conducive to efficient processing or reliable machinery. Further, throughput speed is hindered by the slowest component of the food processing machinery, commonly, but not always, the portioning machine.

Additionally, there are mechanical constraints and maintenance issues related to pockets being coupled to a chain or being linked together. Chains require lubrication and are prone to jamming and failure because of there multi-part components. Pockets coupled together with links have similar issues as chain, and also can make pocket change-out more labor intensive.

There is a need for a pocket conveyor wherein the pockets are not chained or linked together resulting in a more reliable food processing machine. Further, there is a need for a pocket conveyor wherein the processing speed of one processing machine does not effect the processing speed of other processing machines along the food processing line. Additionally, there is a need for a pocket conveyor to provide for multiple conveying paths to service multiple processing machines. The present invention fulfills these needs.

SUMMARY OF INVENTION

One embodiment of the present invention provides a pocket conveyor for use in food processing in which the transfer pockets move independently from each other. Each transfer pocket contains a portion of food which is conveyed from one processing machine to another in the course of food production. Independent movement of the transfer pockets provides for, among other things, greater efficiencies in food production by allowing independent operation of the various processing machines along the pocket conveyor as well as allowing the use of multiple processing machines for each of one or more processes. Further, independent movement of the transfer pockets eliminates the maintenance issues associated with transfer pockets which are chain-linked, such as chain and motor related failure.

The transfer pockets are conveyed from one location to another by any one or combination of conveying means. In one embodiment, the transfer pockets are carried by one or more continuously moving belts which provide mobility to the transfer pockets as well as moving freely beneath the transfer pockets as the transfer pockets are obstructed from moving, such as when the transfer pockets are receiving or discharging food portions or when waiting in queue for the same.

In another embodiment of a conveying means, the transfer pockets are pushed along the conveyor by one or more drive turrets. The teeth of the drive turrets entrain the transfer pockets and push the transfer pockets down-line as the drive turrets rotate. The transfer pockets remain in close proximity to each other but are not linked or chained together. The abutment of subsequent transfer pockets cause the transfer pockets to advance along a stationary track.

In another embodiment of the invention, the machine for conveying food portions from a portioning machine that prepares the food portions to a container handling machine that prepares containers to receive the food portions, comprises a plurality of transfer pockets and a conveyor, the conveyor adapted to convey each transfer pocket independently from another from the portioning machine to the container handling machine, the transfer machine arranged to present one or more transfer pockets to the food portioning machine to collect food portions, and the transfer machine arranged to present one or more transfer pockets containing food portions to the container handling machine for subsequent depositing of the food portions into food containers.

In another embodiment of the invention, the machine comprises a portioning machine, a transfer machine and container handling machine. The portioning machine processes bulk food product to form food portions of a determined size, shape, weight and consistency. The portioning machine deposits the food portions into individual transfer pockets of the transfer machine. The transfer machine is arranged to move the transfer pockets independently from the other transfer pockets from the portioning machine to the container handling machine along one or more transfer lanes. The transfer pockets are independent from each other allowing the portioning machine to operate independently from the container handling machine. The container handling machine presents an open container to the filled transfer pocket for transfer of the food portion into the food container.

The present invention provides for a food handling machine that permits the various components of the machine, such as the portioning machine and the filling machine, to operate at their own speed, independent from each other, providing greatly increased processing speed through the food handling machine. The present invention also provides a food handling machine that permits the use of multiple processing machines, such as multiple container filling machines, to operate with one or more machines, such as a portioning machine. The increased speed of one type of machine is thus optimized as it handles the transfer pockets independently from a slower machine. The present invention is compatible with many variations of tray, pouch, and can filling machines in both speed fluctuations and container spacing.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1A

is a top view of an embodiment of a pocket conveyor in accordance with the invention;

FIG. 1B

is a top view of another embodiment of a pocket conveyor in accordance with the invention;

FIG. 1C

is a side view of the embodiment of a pocket conveyor in accordance with

FIG. 1B

as viewed on view lines

1

C—

1

C;

FIG. 1D

is a top view of another embodiment of a pocket conveyor in accordance with the invention;

FIG. 2A

is a view of an embodiment of the food processing machine in accordance with the invention;

FIG. 2B

is a view of another embodiment of the food processing machine in accordance with the invention;

FIG. 2C

is a view of an embodiment of the food processing machine in accordance with the invention;

FIG. 2D

is a view of another embodiment of the food processing machine in accordance with the invention;

FIG. 3A

is a view of another embodiment of the food processing machine in accordance with the invention;

FIG. 3B

is a view of another embodiment of the food processing machine in accordance with the invention;

FIG. 4

is a view of another embodiment of the food processing machine in accordance with the invention;

FIG. 5

is a view of another embodiment of the food processing machine in accordance with the invention;

FIG. 6

is a view of the food processing machine of

FIG. 5

as viewed on view lines

6

—

6

;

FIG. 7

is a view of a portion of the machine of

FIG. 5

;

FIG. 8

is a view similar to

FIG. 5

illustrating another embodiment of a food processing machine in accordance with the invention; and

FIG. 9

is a view similar to

FIG. 6

illustrating another embodiment of a food processing machine in accordance with the invention.

DESCRIPTION

In the following detailed description, reference is made to the accompanying drawings which form a part hereof wherein like numerals designate like parts throughout, and in which is shown by way of illustration specific embodiments in which the invention may be practiced. It is to be understood that other embodiments may be utilized and structural or logical changes may be made without departing from the scope of the present invention. Therefore, the following detailed description is not to be taken in a limiting sense, and the scope of the present invention is defined by the appended claims and their equivalents.

FIG. 1A

illustrates a pocket conveyor

10

for use in food processing in accordance with one embodiment of the invention. The pocket conveyor

10

consists of a plurality of transfer pockets

142

a

and a conveyor

50

a

. The transfer pockets

142

a

are moved along the conveyor

50

a

from one location to another in a continuous circuit. The transfer pockets

142

a

are not coupled to each other, but are in close proximity or in touching relationship to each other.

The transfer pockets

142

a

comprise a topless and bottomless container which can be of any shape suitable for the particular purpose, such as, but not limited to, a box, cylinder, and octagon shape. The transfer pockets

142

a

as shown in

FIG. 1A

are in the shape of open-ended cylinders. Each transfer pocket

142

a

receives a portion of food from above and subsequent emptying of the food portion from below. The transfer pocket

142

a

supports the food portion during the conveying process. The transfer pocket

142

a

is supported from the bottom by the conveyor

50

a

to contain the food portion within.

The transfer pockets

142

a

are conveyed from one location to another by any one or combination of conveying means. In one embodiment as shown in

FIG. 1A

, the conveyor

50

a

comprises two drive turrets

52

. The drive turrets

52

comprise a plurality of spaced-apart teeth

53

. The space between adjacent teeth

53

conforms to the shape of the transfer pocket

142

a

. In operation, the turrets

52

rotate in the desired direction to push the transfer pockets

142

a

along the conveyor. As a transfer pocket

142

a

approaches one of the turrets

52

, the transfer pocket

142

a

is entrained by the teeth

53

imparting forward movement to the transfer pocket

142

a

. As the transfer pocket

142

a

is advanced and released by the turret

52

, the transfer pocket

142

a

abuts and pushes against the transfer pocket

142

a

before it, thereby pushing the transfer pockets

142

a

along the conveyor

50

a

. The conveyor

50

a

incorporates guard rails

54

to restrain the transfer pockets

142

a

to the desired path.

In another embodiment of the invention, as shown in

FIGS. 1B-C

, the pocket conveyor

12

comprises a conveyor

50

b

having two parallel but oppositely rotating belts

55

, and two semi-circular end chutes

56

. The transfer pockets

142

a

are carried in one direction by one belt

55

, deposited on the end chute

56

, and subsequently propelled along the chute

56

, and carried back in the opposite direction by the second belt

55

to the origin. The transfer pockets

142

a

move along the chute

56

by any number of means, including, but not limited to, the momentum transferred by the belt

55

to the transfer pockets

142

a

, or from the impact of advancing transfer pockets

142

a

. The two belts

55

continuously move imparting forward mobility to the transfer pockets

142

a

. The belts

55

move freely beneath transfer pockets

142

a

that are held stationary, such as when the transfer pockets

142

a

are receiving or discharging food portions, or when waiting in queue for the same. The transfer pockets

142

a

are independent of each other; that is, there is no connection between each transfer pocket

142

a

. Therefore, each transfer pocket

142

a

can be processed independently from the processing of any other transfer pocket

142

a.

In another embodiment of the invention, as shown in

FIG. 1D

, the pocket conveyor

14

comprises a conveyor

50

c

having two parallel but oppositely rotating belts

55

, and two drive turrets

52

. The transfer pockets

142

a

are advanced onto one of the belts

55

by the rotation of one of the drive turrets

52

, carried in one direction by the belt

55

, received and advanced by the second of the drive turrets

52

, and carried back in the opposite direction by the second belt

55

to the origin. The two belts

55

continuously move imparting forward mobility to the transfer pockets

142

a

. The belts

55

move freely beneath transfer pockets

142

a

that are held stationary, such as when the transfer pockets

142

a

are receiving or discharging food portions, or when waiting in queue for the same. The transfer pockets

142

a

are independent of each other; that is, there is no connection between each transfer pocket

142

a

. Therefore, each transfer pocket

142

a

can be processed independently from the processing of any other transfer pocket

142

a.

FIG. 2A

illustrates a portion of a food processing machine

100

a

in accordance with an embodiment of the invention wherein individual food portions are processed independently from each other. The machine

100

a

comprises a portioning machine

120

, a transfer machine

140

, and a container-handling machine

160

a

. The portioning machine

120

prepares food product into a food portion based on desired parameters, such as size, shape, weight, and consistency. The transfer machine

140

transports food portions between the portioning machine

120

and the container-handling machine

160

a

. The container-handling machine

160

a

receives the food portions from the transfer machine

140

for packaging into food containers

170

a

, such as pouches, jars, and cans.

The portioning machine

120

can be one of many types of machines suitable for preparing food portions to be presented to the transfer machine

140

. Portioning machines

120

are known and used by those in the food processing industry. A portioning machine

120

can be used singularly or in combination with other portioning machines

120

to present the desired food portions to the transfer machine

140

.

The container-handling machine

160

a

can be one of many types of machines suitable for accepting food portions from the transfer machine

140

. Container-handling machines

160

a

are known and used by those in the food processing industry. The container-handling machine

160

a

can be used singularly or in combination with other container-handling machines

160

a

to accept the desired food portions from the transfer machine

140

. The container-handling machine

160

a

presents empty containers

170

a

to the transfer machine

140

to be filled with the food portions, wherein the filled containers

170

a

are subsequently further processed, down-line.

The transfer machine

140

comprises a plurality of transfer pockets

142

a

that transport food portions from the portioning machine

120

to the container-handling machine

160

a

. A food portion is deposited into a transfer pocket

142

a

and the transfer pocket

142

a

carries the food portion to the container-handling machine

160

a.

The transfer pocket

142

a

can be of any number of shapes, sizes, and configurations, including open ended cylinders and boxes, as discussed below.

The transfer machine

140

comprises two parallel but oppositely rotating belts

55

and two drive turrets

52

. The transfer pockets

142

a

are advanced onto one of the belts

55

by the rotation of one of the drive turrets

52

, carried in one direction by the belt

55

, received and advanced by the second of the drive turrets

52

, and carried back in the opposite direction by the second belt

55

to the origin. The two belts

55

continuously move imparting forward mobility to the transfer pockets

142

a

. The belts

55

move freely beneath transfer pockets

142

a

that are held stationary, such as when the transfer pockets

142

a

are receiving or discharging food portions, or when waiting in queue for the same.

The function of the drive turrets

52

may be performed by a processing machine along the food processing machine

100

a

line. For example, the portioning machine

120

and/or the container-handling machine

160

a

can be of the type that comprises a transfer pocket drive mechanism, which would take the place of one of the drive turrets

52

, that advances the transfer pockets

142

a

to the corresponding belts

55

.

In the embodiment of

FIG. 2A

, in accordance with the present invention, the transfer pockets

142

a

are independent of each other; that is, there is no connection between each transfer pocket

142

a

. Therefore, each transfer pocket

142

a

can be processed independently from the processing of any other transfer pocket

142

a

. A transfer pocket

142

a

is filled by the portioning machine

120

and does not interfere with a second transfer pocket

142

a

being processed by the container-handling machine

160

a

. This provides the ability to independently control the portioning machine

120

and the container-handling machine

160

a

. Independent control is desired for processing efficiencies. Further, each component of the food processing machine

100

a

can be operated at optimal speeds independently from the other components.

The container-handling machine

160

a

provides the containers

170

a

on a continuously moving conveyance

452

a

. The transfer pockets

142

a

move into alignment with the containers

170

a

at the container-handling machine

160

a

during the filling operation. When the transfer pockets

142

a

are aligned with the containers

170

a

, the food portion is dropped through the bottom of the transfer pocket

142

a

into the container

170

a

below. The turret

52

indexes the transfer pockets

142

a

such that the transfer pockets

142

a

are positioned in proper alignment with the containers

170

a

. In this embodiment, the transfer pockets

142

a

and the containers

170

a

are in continuous movement.

Simultaneously with the filling of the containers

170

a

, other transfer pockets

142

a

are being filled with food portions by the portioning machine

120

. The container-handling machine

160

a

will not be hindered by the portioning machine

120

as each transfer pocket

142

a

can move independently from the others. This is especially beneficial when the portioning machine

120

operates by stopping each transfer pocket

142

a

while depositing a food portion therein.

The transfer machine

140

provides the capability of using processing machines of different types and speeds. For example, one processing machine, such as the portioning machine

120

that operates most efficiently by holding the transfer pockets

142

a

stationary, can be used along the same processing line with another processing machine, such as the container-handling machine

160

a

that operates most efficiently in a continuously moving conveyance. The processing machines operate simultaneously and without interference. Independently movable transfer pockets

142

a

accommodate the operational aspects of the various components of the food processing machine

100

a.

FIG. 2B

illustrates a food processing machine

100

b

in accordance with another embodiment of the invention. The embodiment of

FIG. 2B

is substantially similar to the embodiment of

FIG. 2A

but for the container-handling machine

452

b

and the method of depositing the food portions into the containers

170

b

. The food processing machine

100

b

enables multiple food portions to be deposited into multiple containers

170

b

simultaneously. A determined plurality of transfer pockets

142

a

are conveyed to and held in wait at the container-handling machine

160

b

during the filling operation.

A number of methods can be used to hold the awaiting transfer pockets

142

a

in proper alignment with the corresponding containers

170

b

held below include, but are not limited to, the following methods. In the embodiment shown in

FIG. 2B

, the physical dimensions of the transfer pockets

142

a

provide the proper spacing between food portions contained within the transfer pockets

142

a

when the transfer pockets

142

a

are in abutment with each other.

In another embodiment in accordance with the invention shown in

FIG. 2C

, a comb

172

with multiple teeth

173

is used to position and hold the transfer pockets

142

a

stationary and in proper alignment. The comb

172

is positioned out of the path of the transfer pockets

142

a

to let the transfer pockets

142

a

move freely. The comb

172

is positioned into the path of the transfer pockets

142

a

and the teeth

173

are used to separate and position the transfer pockets

142

a

subsequent to releasing the food portion into the awaiting corresponding containers

107

a

held below.

In another embodiment in accordance with the invention shown in

FIG. 2D

, a plurality of swing gates

174

a-d

are used to position and hold the transfer pockets

142

a

stationary and in proper alignment. The gates

174

a-d

are positioned out of the path of the transfer pockets

142

a

to let the transfer pockets

142

a

move freely. Each gate

174

a-d

is positioned in sequence into the path of the transfer pockets

142

a

such that one transfer pocket

142

a

is held by each of the gates

174

a-d

. In the embodiment shown in

FIG. 2D

, the farthest down-stream gate

174

a

would close first, followed in sequences by each adjacent gate

142

b-d

. Sufficient spacing between each incoming transfer pocket

142

a

is required to allow the gates

174

a-d

to close between the transfer pockets

142

a

. This can be done, for example, by incorporating an upstream gate that meters the oncoming transfer pockets

142

a

in time with the gates

174

a-d

. The gates

174

a-d

separate and position the transfer pockets

142

a

subsequent to releasing the food portions into the awaiting corresponding containers

170

a

held below.

Simultaneously with the filling of the containers

170

a

, other transfer pockets

142

a

are being filled with food portions by the portioning machine

120

. The container-handling machine

160

a

will not be hindered by the portioning machine

120

as each transfer pocket

142

a

can move independently from the others. This is especially beneficial when the portioning machine

120

operates by stopping each transfer pocket

142

a

while depositing a food portion therein.

FIG. 3A

illustrates a food processing machine

100

c

in accordance with another embodiment of the invention. The food portions are deposited into containers

170

c

, such as trays, which are in continuous movement upon a common conveyance

452

c

. The transfer pockets

142

a

continuously move in alignment with the containers

170

c

at the container-handling machine

160

c

during the filling operation while other transfer pockets

142

a

are being individually processed to receive food portions at the portioning machine

120

.

The embodiment of

FIG. 3A

shows a turret

57

that is able to convey transfer pockets

142

of various sizes to the container-handling machine

160

c

. The turret

57

comprises evenly spaced teeth

58

that define a containment space

59

. The transfer pockets

142

a

are conveyed into proximity of the turret

57

by one of the rotating belts

55

. The rotating belt

55

moves freely beneath transfer pockets

142

a

that are held waiting in queue for capture by the turret

57

. Each transfer pocket

142

a

is captured within each of the containment spaces

59

. The containment space

59

is shaped such that the turret

57

can convey and align transfer pockets

142

a

having a variety of shapes, for proper placement over the corresponding container.

170

c

. A second rotating belt

55

receives the emptied transfer pockets

142

a

for conveyance down-line.

FIG. 3B

illustrates a food processing machine

100

d

in accordance with another embodiment of the invention. This embodiment is much like the embodiment of

FIG. 3A

, but does not include the rotating belts

55

. The transfer pockets

142

a

are not coupled to each other, but are in close proximity or in touching relationship to each other. As the turret

57

rotates in the desired direction, the transfer pocket

142

a

is entrained by the teeth

53

imparting forward movement to the transfer pocket

142

a

. As the transfer pocket

142

a

is advanced and released by the turret

57

, the transfer pocket

142

a

abuts and pushes against the transfer pocket

142

a

before it, thereby advancing the transfer pockets

142

a

, in similar fashion as the embodiment of FIG.

1

A. The turret

52

can passively rotate in response to the passing transfer pockets

142

a

to guide the transfer pockets

142

a

. The turret

52

can actively rotate in synchronic relationship with the turret

57

to assist in moving the transfer pockets

142

a

. This present embodiment is particularly useful in food processing machines

100

c

wherein the path taken by the transfer pockets

142

a

is relatively short.

FIG. 4

illustrates a food processing machine

100

e

in accordance with another embodiment of the invention. The transfer pockets

142

a

are processed by a plurality of container-handling machines

160

d

wherein the transfer pockets

142

a

are individually processed to receive food portions at one portioning machine

120

. Neither the operation of the portioning machine

120

nor the container-handling machines

160

d

interfere with each other.

Additional embodiments are provided below. These are illustrative of specific embodiments and are not to be taken in a limiting sense, the scope of the invention being defined by the appended claims and their equivalents.

FIG. 5

illustrates a food processing machine

200

in accordance with an embodiment of the invention. The machine

200

is based on a filling machine as identified in U.S. Pat. No. 5,570,562, Anderson, incorporated herein by reference. The machine

200

comprises a portioning machine

120

, a transfer machine

140

, and a container-handling machine

160

. The machine

200

has a programmable operating control unit

180

to control the operation of the machine

200

. The portioning machine

120

prepares food product

190

into a food portion

192

of a desired size, shape, weight, and consistency. The transfer machine

140

transports the food portion

192

between the portioning machine

120

and the container-handling machine

160

. The container-handling machine

160

receives the food portion

192

from the transfer machine

140

for packaging the food portion

192

into a food container

170

d.

The portioning machine

120

has a product sizing machine

122

for processing a bulk quantity of food product

190

and subsequently sizing the food product

190

into food portions

192

. The sizing machine

122

has an expandable forming chamber

124

to receive a quantity of the food product

190

. The chamber

124

is expanded to receive the food product

190

from an infeed conveyor

126

and is collapsed to form the food product

190

into a food product column

193

. An upper plunger

128

and a lower plunger

129

in opposing relationship to each other act to compress the food product column

193

. The degree of compaction of the food product

190

is determined to produce a food product

190

of a desired consistency.

The food product column

193

is presented to a slicing machine

130

that slices the food portion

192

from the food product column

193

. The food portion

192

is subsequently presented to the transfer machine

140

. The portioning machine

120

cooperates with the transfer machine

140

to place the food portion

192

into an open-ended transfer pocket

142

b

. The transfer pocket

142

b

is a topless and bottomless container which can be of any shape suitable for the particular purpose, such as, but not limited to, a box, cylinder, and octagon. The transfer pocket

142

b

in the embodiment of

FIG. 5

is a topless and bottomless square cup that rides on a guide plate

144

. The guide plate

144

acts as a bottom of the transfer pocket

142

b

. The transfer pocket

142

b

is positioned between the food product column

193

and the lower plunger

129

. The guide plate

144

has a guide plate opening

145

to allow the lower plunger

129

to extend upwardly through the transfer pocket

142

b

to abut the food product column

193

.

During the process of filling the transfer pocket

142

b

, the lower plunger

129

retracts as the upper plunger

128

extends to force the food product column

193

into the transfer pocket

142

b

. The lower plunger

129

operating in conjunction with the upper plunger

128

determines the size of the food portion

192

to be received in the transfer pocket

142

b

. The lower plunger

129

is arranged to enter the transfer pocket

142

b

a determined distance to establish the height of the food portion