Grip for a grasping device

BACKGROUIND OF THE INVENTION
1. Field Of The Invention
The present invention relates to grasping devices and, more particularly, but not by way of limitation, to a grip for a grasping device.
2. Description Of The Related Art
An automatic ice bagger supplies bagged particulate ice and includes an ice maker and an ice bagging unit. The ice maker produces particulate ice that is received by the ice bagging unit. The ice bagging unit transfers the ice into individual bags, seals those bags, and then delivers the bags for consumption.
The ice bagging unit includes a hopper, auger mechanism, chute, bag supply, bag carrier, scale, and bag sealer. The bag carrier grasps a bag from the bag supply and carries the grasped bag under the chute. The auger mechanism transfers particulate ice from the hopper into the bag through the chute. The bag resides on the scale which registers the amount of ice deposited into the bag. After the scale registers the desired amount of ice, the auger mechanism is deactivated. The bag sealer seals the full bag of ice which is then dumped from the scale into a merchandiser.
To grasp and open the bag, the bag carrier includes a motor, a carrier arm, and a gripper arm. The gripper arm mounts to the carrier arm which is driven by the motor in an arc toward the bag supply. The gripper arm supports a gripper that includes a mounting plate and two spring loaded hooks. Each hook includes a rotatable base, an arm, a grip spring, a shock-absorbing spring, a first pin, a second pin, and a grip. The rotatable base is formed integrally with the arm and connects to the mounting plate. The arm is formed integrally with and substantially bisects the first pin. The grip is connected to the arm by the second pin and is constructed from metal. The grip includes a body having a toothed edge or toothed sections having spacers therebetween. A grip spring for moving the grip toward the bag connects the first pin to the mounting plate.
After triggering the spring loaded hooks, the springs contract driving the grips' toothed edges across a front portion of the bag, thereby snagging it. After snagging the bag's front portion, the grips' insert and secure the front portion into slots in the mounting plate, thereby opening the bag. Shock-absorbing springs are positioned between the grips and arms to absorb the impact when the grips contact the mounting plate.
Although grippers in general perform satisfactorily, the grips suffer from several disadvantages. Poor operation occurs if the bag carrier is not properly aligned with the bag supply. Minor deviations in alignment arising during manufacture, or subsequently during maintenance and repair, result in poor operability of the ice bagging unit. These minor deviations result in the metal grips either snagging both the front and back portions of the bag or missing the bag entirely. In addition, the toothed edges of the metal grips must not be too dull or too sharp. Dull teeth fail to grasp the front portion of the bag while sharp teeth pick up multiple bags. Furthermore, the bags are coated with a release agent that accumulates on the metal grips after repeated use. Grips that have accumulated release agent on their teeth often fail to grasp a bag. Moreover, metal grips tend to bend after repeated use. Bent grips miss the slots in the mounting plate, thereby damaging the spring loaded hooks and/or the mounting plate.
Accordingly, grips that improve operability by permitting greater alignment deviations, provide an additional surface other than metal teeth for engaging bags, prevent the accumulation of release agent, and have greater pliancy will improve over conventional grips.
SUMMARY OF THE INVENTION
In accordance with the present invention, a grip for grasping bags includes a member constructed from a suitably pliable material, such as silicon rubber or neoprene. The member has a durometer hardness range of from 30 to 50. The grip further includes first and second supports positioned adjacent to the member. The first and second supports have teeth to assist in grasping.
It is, therefore, an object of the present invention to provide a grip that improves operability by permitting greater alignment deviations of the ice bagging components.
It is a further object of the present invention to provide a grip constructed from silicon rubber that prevents the accumulation of the bags' release agent and provides greater pliancy.
It is an additional object of the present invention to provide a grip that has a member constructed from a suitably pliable material, such as silicon rubber or neoprene, to engage a bag.
Still other objects, features, and advantages of the present invention will become evident to those skilled in the art in light of the following.

BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view depicting the housing of the ice bagger of the present invention.
FIG. 2 is a front elevation view in partial cross-section depicting the hoppers and augers of the present invention.
FIG. 3 is a side elevation view depicting the bag carrier, bag sealer, and scale of the present invention.
FIG. 4 is a front elevation view depicting the bag carrier, bag sealer, and scale of the present invention.
FIG. 5 is a cut-out side elevation view depicting the bag carrier and bag supply of the present invention.
FIG. 6 is a perspective view depicting the bag supply of the present invention.
FIG. 7A-C are cut-out elevation views depicting the positioning of the scale during the filling of the bag with particulate ice.
FIG. 8 is a cut-out top elevation view depicting the scale mounted within the scale housing of the present invention.
FIGS. 9A and B are cut-out side elevation views depicting the scale mounted within the scale housing of the present invention.
FIG. 10 is a cut-out side elevation view depicting the bag sealer of the present invention.
FIG. 11 is a cut-out front elevation view depicting the delivery of the bag of ice into the merchandiser by the scale of the present invention.
FIG. 12 is a cut-out perspective view depicting a first embodiment of the sanitizing system of the present invention.
FIG. 13 is a schematic diagram depicting the first embodiment of the sanitizing system of the present invention.
FIG. 14 is a schematic diagram depicting a second embodiment of the sanitizing system of the present invention.
FIG. 15 is a schematic diagram depicting a third embodiment of the sanitizing system of the present invention.
FIG. 16 is a schematic diagram depicting the control system for the present invention.
FIG. 17 is a front, elevational view illustrating a gripper of the present invention.
FIG. 18 is a bottom, plan view illustrating the gripper of the present invention.
FIG. 19 is an exploded, perspective view illustrating a grip of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
As shown in FIG. 1, ice bagger 10 includes ice makers 11 and 12 which receive water from a water source such as a public water line and produce ice in particulate form (e.g., cube or crescent shape pieces having average dimensions from 1/2 to 21/2 inches. Illustratively, ice makers 11 and 12 may be implemented utilizing a HOSHIZAKI KM 1200 manufactured by Hoshizaki America, Inc. and described in U.S. Pat. No. 4,368,608. Alternatively, ice making machines which produce chunk or crushed ice may be used to implement ice makers 11 and 12. Ice bagger 10 further includes ice bagging unit 13 which receives the ice from ice makers 11 and 12, transfers the ice into individual bags, seals those bags, and then delivers the ice bags into merchandiser 14 where consumers may retrieve them.
As shown in FIG. 2, ice bagging unit 13 includes hopper 15 which communicates with the outlet for ice from ice maker 11 to provide a storage bin for the ice dispensed from ice maker 11. Similarly, hopper 16 communicates with the outlet for ice from ice maker 12 to provide a storage bin for the ice dispensed from ice maker 12. In the preferred embodiment, hoppers 15 and 16 are constructed of a plasticized material to prevent the ice from freezing to their inner walls. Hoppers 15 and 16 mount to frame 17 of ice bagging unit 13 using any suitable means such as screws.
Auger 18 resides within auger housing 20 and functions to deliver ice from hopper 16 to chute 19. Auger 18 connects at one end to motor 23 (see FIG. 12) and at its opposite end to frame 17 using universal joint 22. Auger housing 20 furnishes an enclosed path for the ice delivered from hopper 16 to chute 19 by auger 18. Auger housing 20 connects to hopper 16 over outlet 21 from hopper 16 and mounts to frame 17 using any suitable means such as welding.
To facilitate the delivery of ice from hopper 16 to chute 19, motor 23 drives auger 18 so that it pulls ice from hopper 16. As auger 18 continues to rotate, it forces the ice through auger housing 20 and out outlet 23 of auger housing 20 into chute 19. Chute 19 receives the ice and guides it into a open bag positioned below it. When the bag is full, motor 23 stops and then reverses auger 18 slightly to pull the ice within auger housing 20 back from auger housing outlet 23. Motor 23 reverses auger 18 to prevent ice from exiting auger housing 20 when no bag resides below chute 19. Without the reversal of auger 18, ice would fall from auger housing 20 into merchandiser 14 resulting in a mess which must be cleaned by store personnel.
Even though the auger mechanism connected to hopper 15 has not been described, it comprises the same components and functions identically to the auger mechanism connected to hopper 16. However, the auger of hopper 15 activates separately from auger 18 to deliver ice into chute 19 and fill a bag positioned below chute 19. That is, only one of hoppers 15 and 16 is utilized to deliver ice into a bag positioned below chute 19. Illustratively, auger motor 23 activates repeatedly to fill bags with ice until the ice within hopper 16 has been depleted. The auger motor of hopper 15 then activates repeatedly to fill bags with ice until hopper 15 has also been depleted. While the auger of hopper 15 delivers ice into the bags sequentially positioned below chute 19, ice maker 12 refills hopper 16 with ice. Similarly, ice maker 11 refills hopper 16 with ice, while auger 18 again delivers ice into the bags sequentially positioned below chute 19. Although the preferred embodiment discloses two ice makers and two hoppers, only one ice maker and hopper are actually required. However, any number of ice makers and hoppers may be employed to implement ice bagger 10.
As shown in FIGS. 3, 5, 6 and 10, ice bagging unit 13 includes bag supply 24. Referring to FIG. 6, bag supply 24 comprises cassette tray 25 which houses cassette 26. Cassette 26 includes pins 27 and 28 and arms 29 and 30 both of which secure the bags within cassette 26. The bags include a pair of eyelets at one end which fit over pins 27 and 28 to allow the suspension of the bags within cassette 26. Pins 27 and 28 include slots 180 and 181, respectively, which receive the guide arms (described herein) so that the eyelets of each bag easily transfer from pins 27 and 28 to the guide arms during each bag's removal. Additionally, arms 29 and 30 engage the edges of the bags to hold the bags suspended from pins 27 and 28.
Cassette 26 further includes pad 170 which mounts to cassette 26 using any suitable means such as glue to provide a surface which allows the bag carrier (described herein) to more easily grasp the individual bags. Handle 31 furnishes a grasping point to allow the easy installation and removal of cassette 26 from cassette tray 25. Additionally, cassette 26 includes hook 173 (see FIGS. 3 and 10) which fits within slot 172 of cassette tray 25 and engages cassette tray 25 to arrest the movement of cassette 26 within cassette tray 25.
Cassette tray 25 pivotally mounts to frame 17 of ice bagging unit 13 using pins 32 and 33 which fit within brackets mounted to frame 17 (see FIG. 10). To facilitate the easy loading of bag supply 24 with bags, pins 32 and 33 and their brackets connected to frame 17 permit cassette tray 25 to pivot from the vertical position shown in FIG. 10 to an open position transverse to its closed vertical position. Additionally, cassette tray 25 includes handle 171 (see FIGS. 3 and 10) which supplies a grasping point used in the raising and lowering of cassette tray 25. Cassette 26 slides easily from cassette tray 25 so that it may easily be stocked with bags. Cassette 26 is then slid back within cassette tray 25 where hook 173 prevents cassette 26 from dislodging from cassette tray 25. Cassette tray 25 is then pivoted back to the position shown in FIG. 10 where latch 34 (see FIG. 4) latches cassette tray 25 into place.
As shown in FIG. 4, latch 34 connects to frame 17 using pin 36 and brackets 37 and 38 which connect to frame 17 using any suitable means such as welding. Latch 34 not only functions to latch cassette tray 25 when cassette 26 is installed, but it also latches cassette tray 25 with cassette 26 removed. Cassette tray 25 is latched during the stocking of cassette 26 to prevent store customers from colliding with cassette tray 25, possibly causing injury.
Referring to FIGS. 3, 4, 5, and 10, ice bagging unit 13 includes bag carrier 39 that grasps a bag from bag supply 24 and carries the grasped bag under chute 19. Bag carrier 39 includes motor 40 which drives carrier arm 41 in an arc. Carrier arm 41 supports gripper reset arm 43 and gripper arm 42 that includes gripper 447. Gripper reset arm 43 connects to carrier arm 41 using pins 44 and 45 and freely pivots within carrier arm 41. Gripper arm 42 also connects to carrier arm 41 at pins 44 and 45, however, flat spring 46 connects to both carrier arm 41 and gripper arm 42 to provide a substantially rigid support of gripper arm 42 within carrier arm 41. Additionally, gripper reset arm 43 includes flange 51 that resides in front of pins 453 and 454 of spring loaded hooks 449 and 450 to allow the resetting of spring loaded hooks 449 and 450 during the sealing of the bag (described herein).
Referring to FIGS. 17-19, gripper 447 includes a mounting plate 448 and spring loaded hooks 449 and 450. Hooks 449 and 450 are substantially identical, therefore only hook 449 will be described in detail herein. Hook 449 includes a rotatable base 455, arm 457, grip spring 459, shock-absorbing spring 461, pin 453, grip 463, and pin 465. Rotatable base 455 is formed integrally with arm 457 and connects to mounting plate 448 using any suitable means such as bolts. Arm 457 is formed integrally with and substantially bisects pin 453. Grip spring 459 connects pin 453 to mounting plate 448. Grip 463 is connected to arm 457 by pin 465. Shock-absorbing spring 461 is positioned between grip 463 and arm 457 to absorb the impact when grip 463 contacts a bag mounted in cassette 26.
Grip 463 includes a first support 471 having first and second apertures 491 and 492, second support 473 having first and second apertures 493 and 494, member 475 having first and second apertures 495 and 496, and rivet 477. First support 471 and second support 473 are positioned on either side of member 475. Rivet 477 inserts respectively through apertures 492, 494, and 496 to connect first support 471, second support 473, and member 475 thereby forming grip 463. Second apertures 491, 493, and 495 form a common opening for receiving pin 465 to connect grip 463 to arm 457. Additionally, supports 471 and 473 include respective protrusions 481 and 483 to form a common post for receiving shock-absorbing spring 461.
First support 471 and second support 473 are preferably constructed from any suitable material such as metal and member 475 is preferably constructed from silicon rubber having a durometer hardness range of from 30 to 50 with a durometer hardness range of 40 being most preferable. The proper hardness of member 475 is important. If member 475 is too hard, it slips across the bag failing to grab it. If member 475 is too soft, metal supports 471 and 473 grab the bag instead of member 475. Silicon rubber is preferred because the release agent on the bags flakes off member 475 instead of accumulating. Furthermore, the operability of member 475 is unaffected by the presence of water on it or the bag. In addition, silicon rubber improves operability of grips 463 and 464 because it significantly reduces the tolerance requirements permitting a wider range of alignments of carrier arm 41 when compared to metal grips.
In operation, spring loaded hooks 449 and 450 move substantially simultaneously together. Although FIGS. 17 and 18 illustrate alternative engagement of hooks 449 and 450, the FIGS. 17 and 18 are not representative of gripper 447 operation and are only for depicting the structure of hooks 449 and 450 and plate 448. Member 475 of grip 463 moves across the top bag. A tip 476 of member 475 grasps the bag. Metal supports 471 and 473 have respective teeth 485 and 487 for assisting to grab the bag after member 475 initiates contact. Respective outer edges 497 and 499 of supports 491 and 493 are contoured to prevent the edges 497 and 499 from snagging the bag after member 475 deforms. After grips 463 and 464 grasp the bag, they move into slots 501 and 502 of mounting plate 448. Slots 501 and 502 are preferably tapered to compress grips 463 and 464. This compression assists in holding the bag against mounting plate 448.
To position and activate the gripper 447, motor 40 drives carrier arm 41 in an arc towards bag supply 24 to place mounting plate 448 against the top bag. As carrier arm 41 continues to travel forward, spring loaded hooks 449 and 450 substantially simultaneously trip to pinch the front of the bag against mounting plate 448. Flat spring 46 provides sufficient tension against gripper arm 42 to permit the tripping of spring loaded hooks 449 and 450, however, after spring loaded hooks 449 and 450 trip, flat spring 46 allows a slight rearward motion of gripper arm 42 as carrier arm 41 continues in its forward arc. The rearward pivoting of gripper arm 42 trips sensor 52 which causes motor 40 to reverse resulting in carrier arm 41 reversing its direction of travel. That reversal in direction of carrier arm 41 allows gripper 447 to pull the front of the bag open.
As carrier arm 41 continues to arc away from bag supply 24, it pulls the rear of the bag off pins 27 and 28 of bag supply 24 onto guide arms 54 and 55. Guide arm 55 comprises bracket 56 which pivotally connects to frame 17, pin 58 mounted to bracket 56, and spring 60 which connects between bracket 56 and bracket 62 of frame 17. Similarly, guide arm 54 comprises bracket 57 which pivotally connects to frame 17, pin 55 mounted to bracket 56, and spring 61 which connects between bracket 57 and bracket 63 of frame 17. Guide arms 54 and 55 receive the two eyelets formed at the top rear of the bag to assist bag carrier 39 in supporting the bag under chute 19.
In addition to guide arms 54 and 55, bag opener 175 connects to frame 17 between guide arms 54 and 55 to assist in opening the bag. During the rearward movement of carrier arm 41, the rear of the bag contacts bag opener 175 which ensures the rear of the bag separates from the front of the bag to open underneath chute 19. After carrier arm 41 has pulled the bag past bag opener 175 and onto guide arms 54 and 55, it will continue rearward until it pivots to the position shown in FIG. 10. Once carrier arm 41 reaches that position, it trips sensor 64 which results in motor 40 being disengaged. With motor 40 disengaged, the grasped bag resides below chute 19 in a totally open position because its rear portion has been suspended from guide arms 54 and 55 and its front portion is grasped by gripper 447 (see FIGS. 7A-C).
As shown in FIGS. 3, 4, 7A-C, 8, 9A and B, and 10, ice bagging unit 13 includes scale 65 which comprises a balance beam scale utilized to register when the desired amount of ice has been delivered into the bag. Scale 65 further furnishes the platform on which the bag rests during its filling with ice (see FIGS. 7A-C). Scale 65 includes scale housing 66 which is rectangular in shape (see FIG. 8) and supported at each one of its corners in a position under chute 19 within merchandiser 14 by motor driven arms. Specifically, arms 67 and 68 support one end of scale housing 66 while arms 79 and 80 support the same side of scale housing 66 as arms 67 and 68 but on the opposite end (see FIG. 10). Similarly, arms 69 and 70 support the end of scale housing 66 across from arms 67 and 68 while a fourth set of arms (not shown) support the same side of scale housing 66 as arms 69 and 70 but on the opposite end.
Scale 65 further includes motor 71 which drives arms 67, 68, 79, and 80 and motor 72 which drives arms 69 and 70 and their corresponding arms (not shown) connected at the corner on the same side of scale housing 66 as arm 69 and 70. Motor 71 mounts onto frame 17 and connects to drive shaft 81 to raise and lower arms 67, 68, 79, and 80. Drive shaft 81 functions to transfer the driving force of motor 71 to arms 68 and 80. Arms 68 and 80 include sleeves 73 and 74, respectively, which slide over drive shaft 81 and rigidly connect to drive shaft 81 using any suitable means such as a screw or allen nut (see FIG. 10). The opposite end of arm 68 pivotally connects to one end of arm 67 utilizing pin 75 and clip 76. Additionally, the opposite end of arm 67 connects to scale housing 66 using pin 77 and clip 78. Arm 79 connects to arm 80 which, in turn, connects to scale housing 66 using similar pins and clips. Although the connection among motor 72, the drive shaft for motor 72, arms 69 and 70, and the fourth set of arms which support scale housing 66 are not described, their connections are identical to that described for motor 71, drive shaft 81, and arms 67, 68, 79, and 80.
As shown in FIGS. 8, 9A, and 9B, scale housing 66 includes base 82 and pressure plate 83 which operates as part of scale 65. Base 82 comprises members 84-87 which connect together using any suitable means such as welding to define opening 88. Scale 65 comprises counterweight beam 89 which pivotally mounts within opening 88 through its connection to member 85 using bracket 90 and pin 91. Scale 65 further comprises roller 92 and sensor 93. Sensor 93 comprises a photo-optic sensor that trips in response to the pivoting of counterweight beam 89 within base 82. Pressure plate 83 pivotally mounts over counterweight beam 89 of scale 65 through its connection between members 86 and 87 using pin 94. Pressure plate 83 includes lip 95 which transfers the pivotal motion of pressure plate 83 to counterweight beam 89 and flange 96 which stops the pivotal motion of counterweight beam 89 within base 82. Bucket 97 mounts onto pressure plate 83 using any suitable means such as welding to maintain the bag positioned on scale housing 66 during its filling with ice.
Referring to FIGS. 7A-C, the filling of a bag with particulate ice and the operation of scale 65 will be described. During periods when ice bagger 10 remains idle, motors 71 and 72 manipulate arms 67, 68, 79, 80, 69, 70, and the fourth pair to raise scale housing 66 to its fully raised position (see FIGS. 3, 4 and 10). However, when ice bagger 10 activates, motors 71 and 72 lower scale housing 66 to its fully lowered position so that ice bagging operations may begin. After bag carrier 39 grasps one side of a bag and pulls the bag from bag supply 24 onto guide arms 54 and .55, one of the auger motors activates to drive its auger so that ice from one of hoppers 15 and 16 will be delivered into the bag via chute 19. The auger operates until a sufficient amount of ice resides within the bag to trip a sensor positioned adjacent to each of guide arms 54 and 55. That is, as the ice enters the bag, it weights the bag which results in guide arms 54 and 55 rotating slightly downward to trip the sensors. After the sensors trip, the auger motor deactivates so that the auger only delivers a small amount of particulate ice (e.g. 5-10 particles) into the bottom of the bag (see FIG. 7A). The auger dumps a small amount of ice into the bottom of the bag to ensure the bag contains no wrinkles or folds and is thus fully open.
Motors 71 and 72 then actuate for a predetermined period (20 seconds in the preferred embodiment) to manipulate arms 67, 68, 79, 80, 69, 70, and the fourth pair to raise scale housing 66 to an intermediate position which supports the bag (see FIG. 7B). The same auger motor again activates to it auger so that ice from one of hoppers 15 and 16 will be delivered into the bag via chute 19. The auger operates for a second predetermined time period (25 seconds in the preferred embodiment) to partially fill the bag with particulate ice (see FIG. 7B).
After the auger motor deactivates, motors 71 and 72 reactivate to manipulate arms 67, 68, 79, 80, 69, 70, and the fourth pair to raise scale housing 66 until those arms reach their fully raised position as shown in FIGS. 3, 4, and 10. Once scale housing 66 reaches its fully raised position, motors 71 and 72 deactivate and the same auger motor reactivates to continue the delivery of ice into the bag. The auger delivers ice from it respective hopper 15 or 16 into the bag via chute 19 until scale 65 registers the desired weight of the ice within the bag whereupon the auger motor disengages to discontinue the flow of ice into the bag (see FIG. 7C). The auger motor then reverses to drive the auger in reverse, resulting in the auger pulling the ice away from the auger housing outlet. The auger pulls the ice away from the auger housing outlet to ensure that no ice falls into merchandiser 14 after the bag has been sealed and delivered into merchandiser 14.
As shown in FIG. 9B, when no weight resides on pressure plate 83 counterweight beam 89 resides approximately parallel to the bottom of base 82. However, after motors 71 and 72 of scale 65 raise scale housing 66 such that the bag resides within bucket 97, scale 65 begins to register the weight of the ice within the bag. Illustratively, as the particulate ice collects within the bag (see FIG. 7C), the weight of the ice pivots pressure plate 83 about pin 94 to bring lip 95 on top of roller 92. As the ice continues to fill the bag, pressure plate 83 pivots further onto roller 92 resulting in the end of counterweight beam 89 containing roller 92 pivoting towards the bottom of base 82 while the opposite end of counterweight beam 89 pivots towards flange 96 of pressure plate 83. When the amount of ice within the bag corresponds to the desired bag weight as measured by scale 65, pressure plate 83 will have transferred the weight of the ice fully onto roller 92 causing counterweight beam 89 to pivot fully against flange 96 as shown in FIG. 9A. In its fully pivoted position, counterweight beam 89 trips sensor 93 which develops a signal representing a full bag of ice. In response to that signal, the activated auger motor turns off to stop the delivery of ice from its respective hopper 15 or 16 into the bag of ice. Scale 65 typically is adjusted to measure common weights for ice bags (e.g., 8 or 20 lb. bags), however, the substitution of a counterweight beam having a different overall weight for counterweight beam 89 will allow virtually any weight ice bag to be filled.
As shown in FIGS. 3, 4, and 9, bag sealer 98 includes heating element 99 which connects to frame 17 using any suitable means such as brace welded to frame 17. Additionally, heating element 99 connects to the brace using any suitable means such as brackets. Heating element 99 comprises a resistive heater that transfers heat to the front and back of the bag resulting in the front and back melting together to form a seal. Bag sealer 98 further includes motor 101 which drives press 100 via arms 102-104 connected to one side of press 100 and arms 105-107 connected to the opposite side of press 100. Motor 101 drives arms 102-107 through its connection to drive shaft 108 which mounts to frame 17 using any suitable means such as bearings. Drive shaft 108 functions to transfer the rotational force of motor 101 to arms 102-107.
Arm 102 includes sleeve 109 which fits over drive shaft 108 and rigidly connects to drive shaft 108 via screw 110. Pin 116 connects arms 102 and 103 together while pin 111 connects arms 103 and 104 together. Finally, pin 112 connects arm 104 to frame 17 to provide complete support for one side of press 100. Spring 113 connects between pins 110 and 111 to provide a restoring force against the movement of press 100 by arms 102-107. Although arms 105-107 have not been described, there connections to drive shaft 108 and frame 17 and among themselves are identical to that described for arms 102-104. Bag sealer 98 also includes sensors 114 and 115 which determine the maximum arc that press 100 swings during the sealing of the bag.
During the filling of the bag with particulate ice, press 100 resides in the position shown in FIG. 3. However, once the bag fills with ice, motor 101 activates to drive arms 102-107 pivotally so that they pull press 100 against heating element 99 as shown in FIG. 10. Essentially, arms 102-107 swing press 100 in an arc until it abuts heating element 99. As press 100 traverses its arc, its lower plate swings down and contacts the ends of guide arms 54 and 55 to force guide arms 54 and 55 downward to the position shown in FIG. 10, resulting in the bag sliding from guide arms 54 and 55.
Furthermore, the rotation of press 100 results in the disengaging of the bag from gripper 447. That is, during the swing of press 100, it exerts pressure against gripper reset arm 43 to pivot gripper reset arm 43 toward the rear of carrier arm 41. As gripper reset arm 43 pivots toward the rear of carrier arm 41, flange 51 of gripper reset arm 43 forces pins 453 and 454 rearward with sufficient force to overcome the restoring force of the springs of spring loaded hooks 449 and 450. Consequently, spring loaded hooks 449 and 450 reset to their open position so that the next bag to be filled may be grasped.
As press 100 arcs towards heating element 99, it pushes the front and rear sides of the bag against heating element 99. When press 100 abuts heating element 99 as shown in FIG. 10, sensor 115 trips to deactivate motor 101 thereby stopping the swing of press 100. At this point, the front and rear sides of the bag are pressed against one another between press 100 and heating element 99. Heating element 99 then activates for a predetermined time period (0.86 seconds in the preferred embodiment) resulting in the front and rear sides of the bag being heat sealed together to prevent the particulate ice from escaping the bag. The length of time heating element 99 applies heat to the bag is a user set variable and is described herein with reference to FIG. 16.
After heating element 99 deactivates, motor 101 reverses to swing press 100 back to the position shown in FIG. 3. Motor 101 manipulates arms 102-107 to swing press 100 rearward until sensor 114 trips to indicate that press 100 has returned to its up position. Motor 101 then disengages to stop the motion of press 100. Additionally, as press 100 releases the pressure it applies against guide arms 54 and 55, the restoring force of springs 61 and 60 return guide arms 54 and 55 back to their horizontal position. That is, guide arms 54 and 55 pivot back until they reside within slots 180 and 181 of pins 27 and 28 of cassette 26. With press 100 fully withdrawn and the bag sealed, ice bagging unit 13 then delivers the bag of ice into merchandiser 14.
Referring to FIG. 11, the dumping of filled bags of ice alternately between the left and right side of merchandiser 14 to prevent the undesirable stacking of ice bags directly underneath scale housing 66 will be described. To accurately measure the amount of ice within each bag, scale housing 66 must reside in its fully raised position as previously described with reference to FIGS. 7A-C. To raise scale housing 66 during the filling of a bag with ice, motors 71 and 72 operate in tandem, however, to deliver a filled bag of ice into merchandiser 14, one of motors 71 and 72 energizes separately to drop one side of scale housing 66 so that the bag of ice will fall either into the left or right side of merchandiser 14.
Illustratively, motor 72 could be energized to drive arm 70 and its corresponding arm connected on the same side of scale housing 66 to the position shown in full in FIG. 11. As a result, arm 69 and its counterpart arm connected to the same side of scale housing 66 tilt scale housing 66 to the left resulting in the bag falling from bucket 97 into merchandiser 14. Alternatively, motor 71 could energize while motor 72 remains off to drive arms 68 and 80 to the position shown in outline in FIG. 10, resulting in arms 67 and 79 lowering the right side of scale housing 66 to dump the bag into the right side of merchandiser 14. During automatic operation, motors 71 and 72 alternately energize and de-energize to regulate the dumping of the ice into merchandiser 14 such that the ice bags are delivered alternately between the left and right side of the merchandiser 14.
After the ice bag has been dumped into merchandiser 14, scale housing 66 must be repositioned horizontally underneath chute 19. If ice bagging operations are to continue, the motor initially energized to perform the dumping remains de-energized, while the motor not energized activates to lower the end of scale housing 66 which remained in its fully raised position. Scale housing 66 must be lowered so that bag carrier 39 can retrieve another bag from bag supply 24 for filling. However, if bagging operations are to cease, scale housing 66 must be fully raised within ice bagging unit 13 so that it no longer extends into merchandiser 14. In that instance, the motor initially energized to perform the dumping is re-energized while the motor not originally energized remains u-activated resulting in scale housing 66 rising to the position shown in FIGS. 3, 4, and 10.
As shown in FIGS. 12 and 13, the first embodiment of sanitizing system 120 includes line 121. Line 121 connects at its inlet to a water source such as a public water line and at its outlet with hopper 16. The outlet from line 121 communicates with the interior of hopper 16 through an opening in hopper 16 and secures to hopper 16 using any suitable means such as a bracket. Further, nozzle 122 connects to the outlet from line 121 to provide a water spray within hopper 16 while solenoid valve 123 resides within line 121 to control the flow of water from the water source to hopper 16.
Sanitizing system 120 further includes pan 124 which receives water from hopper 16 via outlet 125 and overflow 126 both of which communicate with the interior of hopper 16. Pan 124 includes baffle 127 which partitions pan 124 into reservoir 128 and drain channel 129. Reservoir 128 receives water from hopper 16 via outlet 125 and overflow 126 and pools that water for use in sanitizing hopper 16. Baffle 127 includes hole 130 which facilitates the flow of water from reservoir 128 to drain channel 129. Drain channel 129 includes outlet 131 which connects to a drain (not shown) via line 132 to provide an exit for the water entering drain channel 129 from reservoir 128 to prevent reservoir 128 from overflowing. Additionally, the top of baffle 127 terminates short of the top of pan 124 to form spillway 143. Spillway 143 ensures pan 124 does not overflow by providing a runoff which permits excess water within reservoir 128 to quickly reach the drain via drain channel 129.
Pump 135 delivers a sanitizing agent such as bleach from sanitizing agent source 133 into the water contained within reservoir 128 via lines 134 and 136 to form the sanitizing solution utilized to clean hopper 16. Once the sanitizing solution is formed, pump 138 pumps the solution into hopper 16 via lines 137 and 139. The outlets from line 139 communicate with the interior of hopper 16 through openings in hopper 16 and secures to hopper 16 using any suitable means such as a brackets. Further, nozzle 140-142 connect to the outlets from line 139 to spray the inside of the hopper with sanitizing solution, thereby sanitizing the hopper's inner surface.
Sanitizing system 120 removes ice stored in hopper 16 during periods when ice bagger 10 remains idle for longer than a set time period (30 minutes in this first embodiment) to prevent old ice from being dispensed to customers. Additionally, if ice sits within hopper for an extended time period, it will freeze together to form large chunks unsuitable for bagging. Thus, after the expiration of the set time period, solenoid valve 123 opens for a predetermined time period (15 minutes in this first embodiment) to allow the delivery of water into hopper 16 via line 121. The water entering hopper 16 melts the ice within and forces the melted ice into reservoir 128 via outlet 125 and overflow 126 of hopper 16.
Furthermore, sanitizing system 120 periodically sprays sanitizing solution within hopper 16 to kill any residue bacteria.
Illustratively, at the expiration of a second set time period (30 days in this first embodiment), solenoid valve 123 activates for a predetermined time period (15 minutes in this first embodiment) to permit water delivery into hopper 16. The water entering hopper 16 melts the ice and forces the resulting water into reservoir 128 as previously described. Solenoid valve 123 then deactivates and pump 135 activates for a predetermined time period (10 seconds in this first embodiment) to pump sanitizing agent from sanitizing agent source 133 into reservoir 128 to form a sanitizing solution.
After pump 135 deactivates, pump 138 activates for a first predetermined time period (30 minutes in this first embodiment) to deliver the sanitizing solution into hopper 16 where it cleans hopper 16 and returns to reservoir 128 for recirculation. Additionally, during the 30 minute sanitation cycle, pump 135 periodically reactivates a predetermined number of times (3 in this first embodiment) to refresh the sanitizing solution by pumping additional sanitizing agent into reservoir 128. At the expiration of the 30 minute sanitation cycle, pump 138 deactivates so that the sanitizing solution returns to reservoir 128 where it enters drain channel 129 via hole 130 and spillway 143 for delivery to the drain.
Once the sanitizing solution drains from reservoir 128, solenoid valve 123 re-actuates to refill reservoir 128 with water. After reservoir 128 fills with water, pump 138 reactivates for a second predetermined time period (15 minutes in this first embodiment) to deliver the water into hopper 16 where it rinses hopper 16 and returns to reservoir 128 for recirculation. Pump 138 circulates the water contained in reservoir 128 for its second predetermined time period (15 minutes in this first embodiment) to permit the rinsing of any residual sanitizing solution from hopper 16.
At the completion of the rinse cycle, ice maker 12 activates to make and deliver a first harvest of ice into hopper 16. During the filling of hopper 16 with ice, the water within reservoir 128 drains via drain channel 129. When hopper 16 fills with ice, solenoid valve 123 opens for a predetermined time period (15 minutes in this first embodiment) to again allow the delivery of water into hopper 16 via line 121. The water entering hopper 16 melts the first harvest of ice and forces the melted ice into reservoir 128 via outlet 125 and overflow 126 of hopper 16. Sanitizing system 120 removes the first harvest of ice within hopper 16 at the completion of a sanitation cycle to ensure no residual sanitizing solution is bagged with the ice. After solenoid valve 123 closes at the end of the predetermined time period, ice bagging unit 13 resumes normal ice bagging operations.
Referring to FIG. 14, the second embodiment of sanitizing system 120 will be described. In the second embodiment of sanitizing system 120, line 121 connects at a T connection with line 139 to feed water into hopper 16 through nozzles 140-142 of line 139. To ensure water delivered from the water source does not flow into pump 138, line 139 includes check valve 145 which prevents water flow to pump 138 from the water source. Furthermore, baffle 127 has been eliminated so that pan 124 forms a single reservoir. With the elimination of baffle 127, outlet 131 and line 132 have been removed and line 137 connected to both pump 138 and the drain via valve 144 which comprises a solenoid operated three-way valve.
During normal operation of ice bagging unit 13 and the flushing of old ice from hopper 16 as previously described, valve 144 remains open to connect pan to the drain thereby preventing it from overflowing. However, to sanitize hopper 16, solenoid valve 123 opens for a predetermined time period (15 minutes in this second embodiment) to permit water delivery into hopper 16 via line 139 and nozzles 140-142. That water melts the ice within hopper 16 and flushes the resulting ice water into pan 124 via outlet 125 and overflow 126. Near the end of the flush cycle, valve 144 closes as shown in FIG. 14 to prevent water flow from pan 124.
Once solenoid valve 123 de-actuates, pump 135 activates for a predetermined time period (10 seconds in this second embodiment) to pump sanitizing agent from sanitizing agent source 133 to the water contained in pan 124. When pump 135 deactivates, valve 144 opens to allow the sanitizing solution to flow from pan 124 to pump 138. Next, pump 138 activates for a first predetermined period (30 minutes in this second embodiment) to pump the sanitizing solution into hopper 16 via line 139 and nozzles 140-142. At the expiration of the 30 minute sanitation cycle, pump 138 deactivates, whereupon valve 144 moves to its initial position connecting pan 124 to the drain so that the sanitizing solution drains from pan 124.
After the sanitizing solution drains from pan 124, valve 144 moves back to its position connecting pan 124 to pump 138, and solenoid valve 123 again opens to fill pan 124. Once pan 124 fills, solenoid valve 123 de-actuates and pump 138 activates for a second predetermined time period (15 minutes in this second embodiment) to provide a water rinse which removes residual sanitizing solution from the inside of hopper 16. At the expiration of the rinse period, pump 138 deactivates and valve 144 again moves to its initial position connecting pan 124 with the drain.
Additionally, ice maker 12 activates to make and deliver a first harvest of ice into hopper 16. When hopper 16 fills with ice, solenoid valve 123 opens for a predetermined time period (15 minutes in this second embodiment) to again allow the delivery of water into hopper 16 via line 121. The water entering hopper 16 melts the first harvest of ice and forces the melted ice into pan 124 via outlet 125 and overflow 126 of hopper 16. Sanitizing system 120 removes the first harvest of ice within hopper 16 at the completion of a sanitation cycle to ensure no residual sanitizing solution is bagged with the ice. After solenoid valve 123 closes at the end of the predetermined time period, ice bagging unit 13 resumes normal ice bagging operations.
Referring to FIG. 15, the third embodiment of sanitizing system 120 will be described. In the third embodiment of sanitizing system 120, line 121 connects at a T connection with line 139 to feed water into hopper 16 through nozzles 140-142 of line 139. To ensure water delivered from the water source does not flow into pump 138, line 139 includes check valve 145 which prevents water flow to pump 138 from the water source. Furthermore, baffle 127 has been eliminated so that pan 124 forms a single reservoir. With the elimination of baffle 127, line 132 includes valve 147 to control the flow of water and sanitizing solution from outlet 131 of pan 124. Additionally, line 137 includes valve 148 to control the flow of sanitizing solution from pan 124 to pump 138. Both valves 147 and 148 comprise a solenoid operated two-way valve.
During normal operation of ice bagging unit 13 and the flushing of old ice from hopper 16 as previously described, valve 148 closes to block pump 138 from pan 124, while valve 147 opens to connect pan 124 to the drain thereby preventing it from overflowing. However, to sanitize hopper 16, solenoid valve 123 opens for a predetermined time period (15 minutes in this third embodiment) to permit water delivery into hopper 16 via line 139 and nozzles 140-142. That water melts the ice within hopper 16 and flushes the resulting ice water into pan 124 via outlet 125 and overflow 126. Near the end of the flush cycle, valve 147 closes as shown in FIG. 15 to prevent water flow from pan 124.
When solenoid valve 123 de-actuates, pump 135 activates for a predetermined time period (10 seconds in this third embodiment) to pump sanitizing agent from sanitizing agent source 133 to the water contained in pan 124. Once pump 135 deactivates, valve 148 opens to allow the sanitizing solution to flow from pan 124 to pump 138. Next, pump 138 activates for a first predetermined time period (30 minutes in this third embodiment) to pump the sanitizing solution into hopper 16 via line 139 and nozzles 140-142. At the expiration of the 30 minute sanitation cycle, pump 138 deactivates, whereupon valve 148 closes and valve 147 opens to connect pan 124 to the drain which removes the sanitizing solution from pan 124.
After the sanitizing solution drains from pan 124, valve 147 closes while valve 148 opens. Solenoid valve 123 then opens to fill pan 124 with water. Once pan 124 fills, solenoid valve 123 de-actuates and pump 138 activates for a second predetermined time period (15 minutes in this third embodiment) to provide a water rinse which removes residual sanitizing solution from the inside of hopper 16. At the expiration of the rinse period, pump 138 deactivates while valve 148 closes and valve 147 opens to connect pan 124 to the drain.
Furthermore, ice maker 12 activates to make and deliver a first harvest of ice into hopper 16. When hopper 16 fills with ice, solenoid valve 123 opens for a predetermined time period (15 minutes in this third embodiment) to again allow the delivery of water into hopper 16 via line 121. The water entering hopper 16 melts the first harvest of ice and forces the melted ice into pan 124 via outlet 125 and overflow 126 of hopper 16. Sanitizing system 120 removes the first harvest of ice within hopper 16 at the completion of a sanitation cycle to ensure no residual sanitizing solution is bagged with the ice. After solenoid valve 123 closes at the end of the predetermined time period, ice bagging unit 13 resumes normal ice bagging operations.
Although the sanitizing of hopper 15 has not been described, the components and operation of its sanitizing system are identical to sanitizing system 120 in each of the three embodiments.
Referring to FIG. 16, control system 200 of ice bagging unit 10 will be described. Control system 200 comprises processor unit 201, operator control 203, interconnect board 204, power supply 205, and driver board 208. In the preferred embodiment, an 8031 processor and associated RAM and ROM implement processor unit 201. Power supply 205 provides the 5V DC bias necessary to operate processor unit 201 and operator control 203. Additionally, interconnect board 204 provides connection points which permit the electrical coupling of processor unit 201, operator control 203, power supply 205, driver board 208, and the various sensors necessary to the operation of control system 200 as depicted in FIG. 16. The sensors utilized in ice bagger 10 comprise photo-optic sensors that develop a digital signal readable by the 8031 processor of processor unit 201 when tripped.
Driver board 208 comprises a plurality of relays, the number of which corresponds to the number of actuators depicted in FIG. 16. Each relay connects to one of the actuators and to a 120VAC input such as a standard public power line. The relays further connect to interconnect board 204 to receive control signals from processing unit 201. The received control signals regulate the activation of the relays to control the delivery of the 120VAC input to each actuator. Additionally, circuit breaker 206 trips in response to power surges or power overloads to prevent damage to the actuators of ice bagger 10.
Operator control 203 comprises a key pad which allows the manipulation of ice bagger 10 and a numeric key pad which permits an operator to input system control values (see FIG. 1). Operator control 203 further comprises a liquid crystal display (LCD) which displays the operator input values during their entry and the number of bags filled with ice during bagging operations. The key pad allows a system operator to select one of a manual, standby, or automatic modes of operation for ice bagger 10. In the standby mode, ice bagger 10 shuts down, however in the manual mode a system operator can manually control bag carrier 39, sealer arm 100, scale housing 66, and the delivery of into a bag held open underneath chute 19. The numeric key pad permits the system operator to input the automatic mode activation times for heating element 99 and for auger motors 23 and 230. Thus, when the system operator selects the automatic mode, processor unit 201 controls the operation of ice bagger 10 to sequentially fill bags with ice and deliver them into merchandiser 14.
Hopper 15 includes sensor 217 mounted in its upper portion and sensor 219 mounted in its lower portion. Similarly, hopper 16 includes sensor 218 mounted in its upper portion and sensor 220 mounted in its lower portion. Sensors 219 and 220 reside in the lower portions of their respective hoppers 15 and 16 to inform processor unit 201 if sufficient ice resides within the hoppers for bagging operations to proceed. That is, sensors 219 and 220 trip in response to any ice deficiency to provide signals indicating that deficiency to processor unit 201.
Processor unit 201 receives those signals and generates control signals received by driver board 208. The relays controlling the operation of ice makers 11 and 12 receive the control signals and actuate to deliver the 120VAC input to ice makers 11 and 12. Ice makers 11 and 12 activate to make ice which they deliver into hoppers 15 and 16, respectively. Ice makers 11 and 12 deliver ice into their respective hoppers 15 and 16 until sensors 217 and 218 trip to inform processor unit 201 that hoppers 15 and 16 are full. In response, processor unit 201 deactivates the relays on driver board 208 which connect ice makers 11 and 12 with the 120VAC input.
Once sensors 219 and 220 produce signals indicating sufficient ice within hoppers 15 and 16, processor unit 201 supplies the relays controlling motors 71 and 72 with control signals which activate the relays to connect motors 71 and 72 with the 120VAC input. Motors 71 and 72 activate to lower scale housing 66 until sensors 211 and 213 trip to inform processor unit 201 scale housing 66 resides in its fully lowered position. In response, processor unit 201 discontinues the control signals to remove power from motor 71 and 72, thereby stopping the lowering of scale housing 66.
After scale housing 66 lowers, processor unit 201 generates a control signal which activates motor 40 to begin the arcing of bag carrier 39 towards bag supply 24. Once bag carrier 39 grasps a bag, sensor 52 trips to provide processor unit 201 with a signal indicating the grasping of the bag. Processor unit 201 then generates a different control signal which activates a different relay to reverse motor 40 and, thus, the direction of travel of bag carrier 39. Bag carrier 39 pulls the bag from bag supply 24 onto guide arms 54 and 55 until it returns to its rear position. When bag carrier 39 reaches its rear position, it trips sensor 64 which informs processor unit 201 to deactivate motor 40. At this point, the bag should be grasped by bag carrier 39 and suspended from bag guides 54 and 55 in a fully open position as shown in FIG. 7A.
In addition to deactivating motor 40 in response to the tripping of sensor 64 by bag carrier 39, processor unit 201 generates a control signal which activates one of auger motors 23 and 230 to begin the delivery of ice from one of hoppers 15 and 16 into the bag. If the bag is fully open, all the ice initially delivered from one of hoppers 15 and 16 will enter the bag thereby allowing processor unit 201 to proceed with the complete filling of the bag. However, if the bag has not been properly opened, the delivered ice will miss the bag and fall into merchandiser 14 because the bag resides incorrectly beneath chute 19. Accordingly, to prevent the equivalent of an entire bag of ice from being dumped into merchandiser 14, control system 200 includes sensors 222 and 224 which sense if the ice exiting chute 19 actually falls into the bag.
Sensors 222 and 224 are positioned on either side of guide arms 54 and 55 and trip in response to the downward movement of guide arms 54 and 55. Specifically, as the ice exits chute 19 and enters the opened bag, it weights the bag so that the bag applies a downward pressure on guide arms 54 and 55. As a result, both guide arms 54 and 55 rotate slightly downward to trip sensors 222 and 224. In response, sensors 222 and 224 each develop a signal which informs processor unit 201 that ice resides within the bag. After receiving a signal from each of sensors 222 and 224, processor unit 201 deactivates the initially activated auger motor 23 or 230 and executes the next step in the ice bagging operation (described herein). Thus, during the proper filling of the bag with ice, the activated auger initially operates only momentarily to deliver a small amount of ice (5-10 particles) from hopper 15 and 16 into the bag. Alternatively, if processor unit 201 fails to receive signals from both sensors 222 and 224 by the expiration of a predetermined time period measured from the initial activation of one of, auger motors 23 and 230 (20 seconds in the preferred embodiment), it will suspend ice bagging operations until an ice bagger operator can remove the bag and reset ice bagger 10 to its automatic mode.
In addition to deactivating the activated auger motor (23 or 230) in response to the tripping of sensors 222 and 224, processor unit 201 activates motors 71 and 72 for a predetermined time period (20 seconds in the preferred embodiment) to raise scale housing 66 to an intermediate position which supports the bag. At the expiration of that predetermined time period, processor unit 201 deactivates motors 71 and 72 and reactivates the originally activated auger motor (23 or 230) for a second time period (25 seconds in the preferred embodiment) to partially fill the bag with particulate ice. Once the second time period expires, processor unit 201 again deactivates the auger motor (23 or 230) and reactivates motor 71 and 72. Motors 71 and 72 raise scale housing 66 until sensors 210 and 212 trip to provide signals informing processor unit 201 scale housing 66 has reached its fully raised position. After processor unit 201 receives those signals from sensors 210 and 212, it deactivates motor 71 and 72 and reactivates the originally activated auger motor (23 or 230). The activated auger motor (23 or 230) drives its respective auger to deliver ice into the bag until sensor 93 of scale 65 trips to indicate the desired amount of ice resides within the bag. Processor unit 201 deactivates the activated auger motor (23 or 230) in response to that signal from sensor 93.
Furthermore, after the receipt of a signal from sensor 93, processor unit 201 generates a control signal which activates motor 101 to pivot sealer arm 100 towards heating element 99. As arm sealer arm 100 abuts heater element 99, it forces the upper edges of the sides of the bag against heater element 99 and resets gripper 447, causing the release of the bag. Processor unit 201 drives motor 101 until sealer arm 100 pivots to a position which trips sensor 115. When processor unit 201 receives a signal from sensor 115, it deactivates motor 101 and generates a control signal which activates heater element 99. Processor unit 201 activates heater element 99 for a set time period (0.86 seconds in the preferred embodiment) to allow the heat sealing of the upper edges of the bag. Upon the expiration of the set time period, processor unit 201 deactivates heater element 99 and reactivates motor 101 to raise sealer arm 100. Motor 101 raises sealer arm 100 until sealer arm 100 trips sensor 114 to inform processor unit 201 that sealer arm 100 has been fully raised. In response to that signal, processor unit 201 deactivates motor 101.
In addition to deactivating motor 101, processor unit 201 generates a control signal which activates one of motors 71 and 72 to drop the sealed ice bag into merchandiser 14. For example, if the bag is to be dropped into the right side of merchandiser 14, processor unit 201 activates motor 71 to lower the right end of scale housing 66. Motor 71 lowers the right side of scale housing 66 until sensor 213 trips, whereupon processor unit 201 deactivates motor 71. If ice bagging operations are to continue, processor unit 201 next activates motor 72 to lower the left side of scale housing 66. Processor unit 201 provides a control signal to motor 72 until sensor 211 trips to signal processor unit 201 to deactivate motor 72. Alternatively, if bagging operations are to cease, processor unit 201 reactivates motor 71 to raise scale housing 66. Motor 71 raises scale housing 66 until sensor 212 trips, resulting in processor unit 201 deactivating motor 71.
Sensor 214 provides processor unit 201 with a signal indicating cassette tray 25 has been opened, while sensor 216 provides processor unit 201 with a signal indicating the door of merchandiser 14 has been opened. If processor unit 201 receives signals from either of sensors 214 and 216, processor unit 201 suspends ice bagging operations until it no longer receives a signal from either sensor. That is, processor unit 201 suspends ice bagging operations until either cassette tray 25 or the door of merchandiser 14 have been closed. Additionally, sensor 221 provides processor unit 201 with a signal indicating merchandiser 14 has been filled with ice bags. Upon receipt of that signal, processor unit 201 ceases ice bagging operations until sensor 221 no longer indicates that merchandiser 14 is full.
Processor unit 201 includes a first timer which begins to run whenever ice bagging operations cease. If ice bagging operations have not resumed before the first timer has timed out (30 minutes in the preferred embodiment), processor unit 201 suspends ice bagging operations and generates control signal which activate solenoid valves 123 and 223 for a predetermined time period (15 minutes in the preferred embodiment). With solenoid valves 123 and 223 open, water enters hopper 16 and 15, respectively, to melt the ice and flush the melted ice from the hoppers, thereby preventing old ice from being bagged and sold to the public. At the expiration of the predetermined time period, processor unit 201 deactivates solenoid valves 123 and 223 to stop the flow of water into hoppers 15 and 16.
Processor unit 201 further includes a second timer which determines the frequency with which hoppers 15 and 16 are sanitized (every 30 days in the preferred embodiment). When the second timer times out, processor unit 201 activates solenoid valves 123 and 223 for a predetermined time period (15 minutes in the preferred embodiment) to flush any ice within the hoppers into the pans of the respective sanitizing systems. Once the predetermined period for flushing has expired, processor unit 201 closes solenoid valves 123 and 223 and activates pumps 135 and 235 for a predetermined time period (10 seconds in the preferred embodiment) to deliver the sanitizing agents into the pans of the sanitizing systems, thereby forming the sanitizing solution.
Processor unit 201 then deactivates pumps 135 and 235 and activates pumps 138 and 238 for a first predetermined period (30 minutes in the preferred embodiment). Pumps 138 and 238 deliver the sanitizing solution into hoppers 15 and 16, respectively to remove any bacteria from hoppers 15 and 16. Additionally, processor unit 201 periodically activates pumps 135 and 235 (3 times in the preferred embodiment) during the sanitizing solution circulation cycle to refresh the sanitizing solution with the sanitizing agent. At the expiration of the sanitizing solution circulation cycle, processor unit 201 deactivates pumps 138 and 238 and re-energizes solenoid valves 123 and 223 to refill the reservoirs of the pans with water. After the pans fill, processor unit 201 reactivates pumps 138 and 238 for a second predetermined time period (15 minutes in the preferred embodiment) to provide a water rinse for hoppers 15 and 16 which removes any residual sanitizing solution from hoppers 15 and 16. When hoppers 15 and 16 have been rinsed, processor unit 201 deactivates pumps 138 and 238.
Furthermore, processor unit 201 activates ice makers 11 and 12, which make and deliver a first harvest of ice into their respective hoppers 15 and 16. During the filling of hoppers 15 and 16 with ice, the rinse water contained within each pan drains. When hoppers 15 and 16 fill with ice, processor unit 201 deactivates ice makers 11 and 12 and actuates solenoid valves 123 and 223 for a predetermined time period (15 minutes in the preferred embodiment) to again allow the delivery of water into hoppers 15 and 16. The water entering hoppers 15 and 16 melts the first harvest of ice and forces the melted ice into the pans via the outlets and overflows of hoppers 15 and 16. The sanitizing systems remove the first harvest of ice within hoppers 15 and 16 at the completion of a sanitation cycle to ensure no residual sanitizing solution is bagged with the ice. After the expiration of the predetermined time period, processor unit 201 closes solenoid valves 123 and 223 and resumes normal ice bagging operations.
To implement the second and third embodiments of sanitizing system 200, processor unit 201 would generate control signals that open and close the three-way water valve or the two two-way water valves, respectively, at the appropriate times as previously described with reference to FIG. 14 and 15. Furthermore, processor unit 201 would not periodically activate pumps 135 and 235 to refresh the sanitizing solution.
From the foregoing description and illustration of this invention it is apparent that various modifications may be made by reconfigurations or combinations producing similar results. It is, therefore, the desire of the applicant not to be bound by the description of this invention as contained in this specification, but be bound only by the claims as appended hereto.

Number	Name	Date
3416619	McClusky	Dec 1968
3416620	McClusky	Dec 1968
3789570	Mullins, Jr.	Feb 1974
3795084	Richardson et al.	Mar 1974
4003188	Lau	Jan 1977
4284301	Geiger et al.	Aug 1981
4761197	Christine et al.	Aug 1988
4848064	Lems et al.	Jul 1989
4936817	Runge	Jun 1990
4964944	Christine et al.	Oct 1990
5052169	Gronlie et al.	Oct 1991
5142840	Cappi et al.	Sep 1992
5581982	Schroeder et al.	Dec 1996

Grip for a grasping device

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