US20030197324A1

US20030197324A1 - Feeding flexible products

Info

Publication number: US20030197324A1
Application number: US10/186,483
Authority: US
Inventors: Edward Cook
Original assignee: Individual
Current assignee: Longford Equipment International Ltd
Priority date: 2002-04-22
Filing date: 2002-07-01
Publication date: 2003-10-23
Also published as: CA2382951A1

Abstract

A stack of pouches (or other flexible products) is supported such that the stack declines from the horizontal. A pouch at the base of the stack can then be pulled upwardly from the base of the stack. This may be accomplished with an inclined conveyor on which the base of the stack rests. Because the basal pouch is pulled upwardly, gravity assists in ensuring that none of the other pouches in the stack follow the basal pouch. Thus, the approach assists in ensuring single pouch feeding.

Description

BACKGROUND OF THE INVENTION

This invention relates to feeding flexible products, such as pouches.

Pouches are used to package a wide variety of products such as spices and other dry powdered products, seeds, sterile medical supplies, sample sizes of shampoo, and individual servings of condiments. It may be desired to dispense pouches into an assembly line as, for example, when a pouch is to be inserted into a box or envelope. By virtue of their flexible nature and variable thickness, it is difficult to feed pouches one at a time in automated processes. U.S. Pat. No. 5,239,809 to Long issued Aug. 31, 1993 addresses this issue by feeding pouches incorporated into a web to a dispensing area where individual pouches are guillotined from the web. A drawback with this approach is that the guillotine may occasionally sever a pouch. When this occurs, the contents of the pouch may spill, fouling the equipment. Furthermore, this approach requires manufacturing the pouches in a web.

Therefore, a need remains for an approach to feeding pouches and other flexible products which avoids the identified drawbacks.

SUMMARY OF THE INVENTION

According to the present invention, there is provided a flexible product feeder, comprising: an inclined conveyor; a product stack support declining toward said inclined conveyor for supporting a product stack such that a product at a base of said stack rests on said inclined conveyor; a motor for moving said conveyor so as to urge any product resting thereon upwardly.

According to another aspect of the invention, there is provided a pouch feeder, comprising: an inclined conveyor; a pouch stack support declining toward said inclined conveyor for supporting a pouch stack such that a pouch at a base of said stack rests on said inclined conveyor; a motor for moving said conveyor so as to urge any pouch resting thereon upwardly.

According to a further aspect of the invention, there is provided a method for feeding flexible products, comprising: supporting a stack of products such that said stack declines from the horizontal; feeding a basal product from a base of said stack by pulling said basal product upwardly.

BRIEF DESCRIPTION OF THE DRAWINGS

In the figures which illustrate example embodiments of the invention, [0008]
FIG. 1 is a side view of a feeder made in accordance with this invention, [0009]
FIG. 2 is a top perspective view of the feeder of FIG. 1 shown from a dispensing end, [0010]
FIG. 3 is a top perspective view of an input end of the feeder of FIG. 1, [0011]
FIG. 4 is a schematic view of the feeder of FIG. 1 shown in a condition at start up, and [0012]
FIG. 5 is another schematic view, similar to that of FIG. 4 but shown in a condition ready for dispensing.[0013]

DETAILED DESCRIPTION

Turning to the figures, a [0014] feeder 10 feeds pouches 26 in a downstream direction 11 from a pouch stack support 12. The pouch stack support declines to an inclined conveyor 14 which, in the illustrated embodiment, is an endless friction belt. The pouch stack support 16 comprises sidewalls 18 a, 18 b each with an inwardly directed flange 20 a, 20 b, respectively, that form a gapped floor of the pouch stack support. The gap between the flanges accommodates an urging conveyor 22 which, in the example embodiment, is an endless friction belt. A stack 24 of pouches 26 is supported by the pouch stack support 12 such that a pouch 26 b at the base of the stack 24 rests on the inclined conveyor. However, an abutment 28 which, in the example embodiment, is a bar extending between the sidewalls 18 a, 18 b of the pouch stack support 12, is positioned proximate the inclined conveyor 14 and urging conveyor 22 to space the lower end of pouch 26 a from the inclined conveyor 14. A sensor 32 is positioned adjacent, but upstream of, the bar to sense the lower end of pouch 26 b. (In the schematic views, this sensor 32 is shown below urging conveyor 22. In reality, a hole will be provided through a sidewall of the pouch stack support 12 to allow the sensor a “view” adjacent the bar.)
A [0015] curved plate 36 has a flat upstream portion extending over the stack 24 of pouches and a curved downstream portion that forms a nip 38 at the upper end of the inclined conveyor 14.
An [0016] overhead conveyor 40 is positioned overhead of the inclined conveyor 14 and an underlying conveyor 42 underlies the overhead conveyor 40. In the example embodiment, both of these feeders are endless belts.
[0017] Conveyors 40, 42 feed to co-operating downstream conveyors 46, 48 which, in the illustrative embodiment, are endless bands. A pouch sensor 50 is positioned at the dispensing end 52 of the feeder 10.
The [0018] sensors 32 and 50 output to a processor 54. A motor 56 is provided for driving urging conveyor 22 and is operatively coupled to processor 54. A second motor 58 is provided for driving each of conveyors 14, 40, 42, 46, and 48. Motor 58 is also operatively coupled to processor 54. Appropriate gearing (not shown) is provided between the conveyors 14, 40, 42, 46, and 48 such that conveyors 40, 42, 46, and 48 operate at a speed greater than that of conveyor 14. Processor 54 receives pouch demand signals on line 60.
A [0019] base 62 of the feeder has an arm 64 that allows for the adjustment of the declination angle of the pouch stack support 12. Normally, the product stack support 12 will be adjusted to decline from the horizontal at an angle of between about twenty to forty degrees and will make an inside angle with the inclined conveyor 14 of between about eighty and one hundred degrees. At a typical declination of about thirty degrees from the horizontal, the product stack support 12 makes an inside angle with the inclined conveyor 14 of about ninety degrees.
Preparatory to operation, the pouch stack support [0020] 12 of feeder 10 may be loaded with a stack 24 of pouches. Whenever feeder 10 is activated, if sensor 32 is not blocked (i.e., it does not sense a lower end of a pouch 26 b), processor 54 causes motor 56 to operate at a slow speed to slowly move urging conveyor 22 in downstream direction 11. This urges the lower ends of the pouches 26 downwardly toward inclined conveyor 14. The sensor 32 is positioned such that it will become blocked (i.e., will sense a lower end of pouch 26 b) when the pouch 26 a at the base of the stack 24 abuts abutment 28. Whenever sensor 32 becomes blocked, urging conveyor 22 is stopped.
The [0021] processor 54 may then be prompted by a user to operate the feeder to achieve a dispensing ready position (illustrated in FIG. 5). This causes the processor to activate motor 58.
With [0022] motor 58 running, the inclined conveyor 14 urges basal pouch 26 b upwardly. With the inclined conveyor fabricated of a friction enhancing material and with the majority of the bottom face of the basal pouch 26 b lying against the inclined conveyor, the frictional engagement of the inclined conveyor will, for most pouch types, be sufficient to overcome the frictional engagement of the basal pouch with the remainder of the pouch stack 24. Thus, the inclined conveyor will cause the basal pouch 26 b to move upwardly. Further in this regard, it will be noted that the frictional engagement of the basal pouch 26 b with the rest of the stack is a function of the maximum height of the stack and of the angle of declination of the pouch stack support 12. However, the frictional engagement of the basal pouch 26 b with the inclined conveyor is also a function of these variables. Thus, a pouch may be pulled from the stack by the inclined conveyor relatively independently of these variables. The key, however, is that the pouch stack decline to the inclined conveyor so that the basal pouch 26 b may be pulled upwardly. In consequence of this, gravity will assist in ensuring that only the basal pouch is fed upwardly, thus helping to avoid improper feeding of more than one pouch at a time.
As soon as [0023] pouch 26 b clears abutment 28, the lower end of the pouch will fall onto conveyor 14. However, it will be noted that the lower end of the next adjacent pouch is kept spaced from the inclined conveyor so that, at this stage, no portion of this next adjacent pouch touches the inclined conveyor. With the basal pouch 26 b no longer upstream of abutment 28 sensor 32 may become unblocked. This results in re-activation of motor 56 to urge the bottom end of the next adjacent pouch against abutment 28.
As shown in FIG. 5, as a [0024] pouch 26 b moves upwardly, it enters the nip 38 between the inclined conveyor 14 and curved plate 36. The nip ensures a strong frictional engagement of the basal pouch with the inclined conveyor as the weight of the stack 24 ceases to provide this frictional engagement due to the basal pouch moving away from the stack. Additionally, the curved plate 36 will tend to block any pouch that might initially move with the basal pouch.
As [0025] pouch 26 b continues to move upwardly, its upper end will hit overlying conveyor 40. This will cause the (flexible) pouch to be re-directed, that is, it will bend in a downstream direction. As pouch continues to feed, it will leave nip 38 and drop onto underlying conveyor 42. The pouch will then continue along conveyors 46, 48. Once pouch 26 b leaves the base of the stack 24, the next adjacent pouch becomes the new basal pouch and, with motor 58 continuing to operate, the inclined conveyor will next urge that pouch to feed in a downstream direction. However, because the conveyors 40, 42, 46, and 48 operate at a higher speed than does inclined conveyor 14, once a pouch leaves nip 38, it will move ahead of the next pouch that begins feeding through the nip.
By virtue of this operation, a plurality of pouches will be fed, one at a time, toward the dispensing [0026] end 52 of the feeder 10. As soon as the first fed pouch interrupts sensor 50, the sensor signals processor 54 which stops motor 58. Consequently, (apart from possible continued operation of the urging conveyor), the feeder 10 stops in a quiescent, ready to feed, condition illustrated in FIG. 5.
Now when the [0027] processor 54 receives a signal on demand line 60, it re-activates motor 58 until sensor 50 is again interrupted. The result is that one pouch is dispensed (from dispensing end 52) and the next upstream pouch is moved to a ready position at the dispensing end of the feeder. Operation can then continue in this way with the feeder dispensing one pouch each time the processor receives a signal on demand line 60.
The nip [0028] 38 will squeeze a pouch which may cause its contents to be re-distributed in the pouch. To reduce this effect (and thus help ensure the pouch is not burst by the nip), the curved plate 36 that forms the nip may have a width which is less than the width of the pouch. Also, the pressure of the nip may be adjusted, as required.
The [0029] sidewalls 18 a, 18 b are supported in a frame 70 by rods 72 so that the sidewall spacing may be adjusted to accommodate pouches of different widths. Additionally, the height of the curved plate 36 above urging conveyor 22 may be adjusted so as to accommodate pouches of different lengths.
While the [0030] feeder 10 has been described in conjunction with the feeding of pouches, it may equally be used in the feeding of other flexible products, such as paper stock.
While the [0031] conveyors 40, 42, 46, and 48 has been described as being geared to inclined conveyor 14 so as to convey more quickly than the inclined conveyor, the same operation will result if the conveyors 40, 42, 46, and 48 are run off a separate motor.
While [0032] sensor 32 is illustrated as feeding back to processor 54, it could equally feed an operational signal directly to motor 56. In a similar fashion, sensor 50 could feed an operational signal directly to motor 58. In such case, demand line 60 could also feed an operational signal directly to motor 56.
The curved downstream portion of [0033] curved plate 36 could be replaced with a nip wheel which forms nip 38 with inclined conveyor 14, and, in many situations, the flat upstream portion of the curved plate could be omitted.
Other modifications will be apparent to those skilled in the art and, therefore, the invention is defined in the claims. [0034]

Claims

What is claimed is:

1. A flexible product feeder, comprising:

an inclined conveyor;

a product stack support declining toward said inclined conveyor for supporting a product stack such that a product at a base of said stack rests on said inclined conveyor;

a motor for moving said conveyor so as to urge any product resting thereon upwardly.

2. The feeder of claim 1 wherein said product stack support comprises an urging conveyor for urging a lower end of products in a product stack toward said inclined conveyor.

3. The feeder of claim 2 further comprising a sensor proximate said inclined conveyor for sensing a lower end of a product at a base of a stack of products supported by said product stack support, said urging conveyor for operating when said sensor fails to sense a lower end of a product at a base of a stack of products supported by said product stack support.

4. The feeder of claim 3 further comprising an abutment positioned for spacing a lower end of a product at a base of a product stack supported by said product stack support from said inclined conveyor.

5. The feeder of claim 4 further comprising a nip at an upper end of said inclined conveyor for nipping products fed upwardly on said inclined conveyor.

6. The feeder of claim 5 further comprising an overhead belt conveyor overhead of said inclined conveyor for re-directing products fed by said inclined conveyor.

7. The feeder of claim 5 further comprising an underlying conveyor underlying said overhead conveyor.

8. The feeder of claim 7 further comprising means for driving said overhead conveyor and underlying conveyor in a downstream direction at a speed greater than a speed of said inclined conveyor.

9. The feeder of claim 2 wherein said urging conveyor is accommodated in a gapped floor of said product stack support.

10. The feeder of claim 9 further comprising a base for said product stack support which allows adjustment of an angle of declination of said product stack support.

11. The feeder of claim 1 wherein said product stack support makes an inside angle with said inclined conveyor of about ninety degrees.

12. The feeder of claim 1 wherein said product stack support declines from the horizontal at an angle of between twenty to forty degrees and makes an inside angle with said inclined conveyor of between about eighty and one hundred degrees.

13. The feeder of claim 10 wherein said inclined conveyor comprises a friction belt.

14. The feeder of claim 13 wherein said urging conveyor comprises a friction belt.

15. The feeder of claim 4 further comprising a member for blocking from upward feeding all but a product lying against said inclined conveyor.

16. A pouch feeder, comprising:

an inclined conveyor;

a pouch stack support declining toward said inclined conveyor for supporting a pouch stack such that a pouch at a base of said stack rests on said inclined conveyor;

a motor for moving said conveyor so as to urge any pouch resting thereon upwardly.

17. A method for feeding flexible products, comprising:

supporting a stack of products such that said stack declines from the horizontal;

feeding a basal product from a base of said stack by pulling said basal product upwardly.

18. The method of claim 17 wherein said basal product is pulled upwardly at approximately a right angle to said stack.

19. The method of claim 18 wherein said feeding comprises operating an upwardly inclined conveyor against which said basal product rests.

20. The method of claim 19 further comprising re-directing flexible products pulled upwardly by said inclined conveyor with an overhead belt conveyor.