The present disclosure relates generally to automated feeding devices, and in particular to automated devices for feeding and conveying items with optimized control.
A “prefeeder” is a device that handles blank sheets of, for example, corrugated material. The prefeeder receives a stack of blank sheets, divides the stack into blocks, and feeds the blocks into a finishing machine in an intermittent shingled stream. Particularly, a block pusher prefeeder may receive the stack of blank sheets, lift the stack up, divide the stack into measured blocks, and then feed the sheets off the bottom of the block under a vertical stop in a continuous shingled stream for delivery into the finishing machine hopper.
With conventional pusher technology, a stack of flat sheet stock enters the block pusher prefeeder. The lead edge of the stack is registered against a vertical stop, such as a backstop. The block pusher plate resides behind and to the top of the stack. When there is a call for another block of sheets, the stack rises, such that the stack is between the backstop and the block pusher plate. The block pusher plate then moves forward to push off a block of sheets from the top of the stack. In the standard configuration, the bottom of the block pusher plate is aligned with the top of the backstop, so as to produce a horizontal plane. This horizontal plane defines the separation point in the stack, wherein the sheet above the plane is the bottom sheet of the block and the sheet below the plane is the top sheet of the stack.
When there is down warp, the leading edge of the stack is lower than the trailing edge of the stack. As a result, when the block pusher plate moves forward to deliver a block of sheets, the block pusher plate stalls due to the sheets that are captured/jammed between the block pusher plate and the backstop. When there is up warp, the leading edge of the stack is higher than the trail edge of the stack. When the block pusher plate moves forward to deliver a block of sheets, trailing sheets (i.e., sheets that are not aligned with the block or the stack) result.
Current block pusher prefeeders allow the operator to select a warp mode which lifts the block pusher plate. Elevating the bottom of the block pusher plate relative to the backstop allows the block pusher plate to convey forward and push a down warped block of sheets successfully off the stack.
Warp mode cannot be enabled permanently due to the potential for a trailing sheet condition when running flat, or non-warped, sheets. When the bottom of the block pusher plate and the top of the backstop are not correctly aligned in elevation (i.e., the bottom of the block pusher plate is above the top of the backstop), a scenario arises when running flat sheets where the bottom sheet(s) of the block, or the top sheet(s) of the stack, begin to move, but then stall and are no longer aligned with the block or the stack. This may cause issues with the manufacturing line efficiency.
With the selector switch for warp mode at the operator station, the operator is required to make the decision regarding when to use the warp mode and when to disable warp mode. Upon visual inspection of a stack, the operator can select a mode to allow the prefeeder to handle warp or select a mode where the prefeeder handles no warp. Use of a selector switch results in an increased risk for human error. For example, the operator may enable warp mode at times when warp mode is undesirable, thereby causing trailing sheets to occur. Similarly, the operator may disable warp mode at times when warp mode is desirable. Thus, the block pusher plate may stall against the back of the stack due to down warp. As an additional example, the operator may enable warp mode where warp mode is desirable (i.e., the stack contains warped sheets). However, the sheets at the bottom of the stack may be pressed flat due to the weight of the stack. That is, the amount of warp may diminish from the top of the stack to the bottom of the stack, and therefore, with warp mode enabled, trailing sheets may be present in the last few block pushes of the stack. Thus, to have an efficient operation, the operator must always be cognizant of whether warp is present in the stack and select the appropriate mode.
Another problem with conventional feeders arises when items moved by the conveyor belts are dropped into the finishing hopper, which stacks the items as they are dropped off of the conveyor belt. Many conventional feeders do not include means for effectively controlling the drop distance of the items, which extends from the top of the conveyor belts to the top of the stack of items formed in the hopper. When the drop distance of the items is too large, the items may be damaged as they are deposited in the hopper. On the other hand, the hopper may overflow when the stack of items is too high. Each of these events may result in damage to the items, and/or jamming of the stacking device.
To control the drop distance of the items, many conventional feeders alternate between starting and stopping the conveyor belt of the stacking device and/or the finishing conveyor belt of the finishing machine. For example, these feeders may start the conveyor belt of the stacking device while stopping the finishing conveyor belt to increase the height of the stack in the hopper and decrease the drop distance between the belt and the top of the stack. Alternatively, conventional feeders may stop the conveyor belt of the stacking device while running the finishing conveyor belt to decrease the height of the stack and increase the drop distance. However, these solutions are not effective in maintaining the stack at a constant level within the hopper, and further result in jamming of the stacking device due to the accumulation of items during the stopping and starting of the belts. Accordingly, there is a continuing need in the art for automated feeding devices with optimized control that overcome one or more of the limitations of conventional approaches.
The present disclosure includes an apparatus and method for conveying, stacking, and un-stacking items, and has particular application for stacking sheets of corrugated board, paperboard, fiberboard, or other sheet material from an entry or line conveyor or other delivery means.
In one embodiment, a stacking device can be coupled between a conveyor and a receiving hopper. The stacking device can be configured to adjust a drop distance from the conveyor onto the top of a stack of stackable items already in the receiving hopper (for example, a level of the top of the stack can be determined by one or more sensors). This can have the effect that items are not damaged by an excessive drop distance, and do not have overflow-related problems from an insufficient drop distance. The drop distance can be adjusted by one or more techniques that can have the effect of maintaining the drop distance within a desirable range, such as between a relative minimum and a relative maximum. Maintaining the drop distance more than the relative minimum can help prevent overflow-related problems. Maintaining the drop distance less than the relative maximum can help prevent drop damage.
For a first example, the drop distance can be adjusted by altering a position of the conveyor, such as a height of the delivery end of the conveyor above the receiving hopper (either the height of the entire conveyor, or just the height of its delivery end, could be adjusted). This can have the effect that the stackable items are dropped from a location either closer to, or farther from, the top of the stack already in the receiving hopper. For a second example, the drop distance can be adjusted by altering a speed at which stackable items enter the receiving hopper. This can have the effect that the stackable items enter and exit the receiving hopper at a speed that maintains the top of the stack already in the receiving hopper relatively closer to, or farther from, the conveyor (such as with respect to a minimum fill level or a maximum fill level).
In one embodiment, apparatus including the stacking device can perform one or more methods that maintain the drop distance within a desirable range, such as between a relative minimum and a relative maximum. The conveyor can be responsive to the sensor in the stacking device, and can perform method steps that maintain the drop distance within the desirable range. For a first example, the delivery end of the conveyor can be raised or lowered with respect to the stacking device (either the height of the entire conveyor, or just the height of its delivery end, could be adjusted). For a second example, the conveyor can increase or decrease its speed, with the effect of maintaining a desirable fill level range. Each of these method steps can maintain a desirable drop distance and help prevent stacking problems.
As described herein, in one embodiment, a stacking device including a conveyor belt may be configured to move one or more items towards a receiving storage hopper configured to receive the one or more items from the conveyor belt. The one or more items may form a stack of items in the receiving storage hopper. The stacking device may further include a sensing device configured to determine a level of the stack of items in the receiving storage hopper. The stacking device may be configured to adjust a height of the stacking conveyor belt relative to the storage hopper based on the level of the stack of items in the receiving storage hopper. For example, the height of the stacking conveyor belt relative to the storage hopper can be adjusted by altering an angle of the stacking conveyor, with the effect that a delivery end of the stacking conveyor is different or higher, relative to the storage hopper.
As described herein, in another embodiment, the stacking device may be configured to raise the height of the stacking conveyor belt relative to the storage hopper if the level of the stack of items in the receiving storage hopper is above a target fill level. In a further embodiment, the stacking device may be configured to lower the height of the conveyor belt relative to the storage hopper if the level of the stack of items in the receiving storage hopper is below a minimum fill level. In another embodiment, the stacking device may be further configured to adjust a speed of the conveyor belt based on the level of the stack of items in the receiving storage hopper.
In some embodiments, the sensing device may include a laser sensor that emits a predetermined wavelength of light in the form of a beam. In other embodiments, the laser sensor may be positioned within the stacking conveyor belt. In additional embodiments, the sensing device may include one or more photoelectric sensors that are positioned within the hopper.
As described herein, in another embodiment, a conveyor belt can be configured to move one or more items towards a receiving storage hopper configured to receive the one or more items from the conveyor belt. The one or more items may form a stack of items in the receiving storage hopper. The stacking device may further include a sensing device configured to determine a level of the stack of items in the receiving storage hopper. The stacking device may be configured to adjust a speed of the conveyor belt based on the level of the stack of items in the receiving storage hopper.
As described herein, in a further embodiment, the stacking device may be configured to decrease the speed of the conveyor belt when the level of the stack of items is higher than a target fill level. In another embodiment, the stacking device may be configured to increase the speed of the conveyor belt when the level of the stack of items is lower than a minimum fill level. In additional embodiments, the stacking device may further include a finishing machine including a finishing conveyor belt, and the stacking device may be configured to adjust the speed of the conveyor belt based on the level of the stack of items in the receiving storage hopper.
As described herein, another embodiment relates to a method for stacking items. The method may include moving one or more items along a conveyor belt at a predetermined speed, dropping the one or more items into a hopper to form a stack of items in the hopper, measuring a level of the stack of items in the hopper, and altering the speed of the conveyor belt based on the level of the stack of items in the hopper.
As described herein, in another embodiment of the method, the altering step may include decreasing the speed of the conveyor belt if the level of the stack of items in the hopper is above a target fill level. In a further embodiment, the altering step may include increasing the speed of the conveyor belt if the level of the stack of items in the hopper is below a target fill level.
As described herein, another embodiment relates to a method for stacking items, including moving one or more items along a conveyor belt, dropping the one or more items into a hopper to form a stack of items in the hopper, measuring a level of the stack of items in the hopper, and altering a height of the conveyor belt relative to the hopper based on the level of the stack of items in the hopper.
As described herein, in a further embodiment, the altering step may include lowering the conveyor belt if the stack of items in the hopper is lower than a target fill level and the conveyor belt is running at a maximum speed. In another embodiment, the altering step includes raising the conveyor belt if the stack of items in the hopper is higher than a target fill level. In another embodiment, the altering step includes lowering the conveyor belt if the stack of items in the hopper is lower than a minimum fill level.
While multiple embodiments are disclosed, still other embodiments of the present disclosure will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments of the invention. As will be realized, the various embodiments of the present disclosure are capable of modifications in various obvious aspects, all without departing from the spirit and scope of the present disclosure. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not restrictive.
While the specification concludes with claims particularly pointing out and distinctly claiming the subject matter that is regarded as forming the various embodiments of the present disclosure, it is believed that the invention will be better understood from the following description taken in conjunction with the accompanying Figures, in which:
The use of the same reference numerals in different drawings indicates similar or identical items.
The various embodiments of the apparatus and method for conveying and stacking items in accordance with the present disclosure may be used with an automated stacking device for maintaining an ideal relative position between a feeder assembly and a finishing machine thereof.
The device 100 may include a carrier or conveyor 105 for receiving incoming items to be stacked. The conveyor 105 may include an endless band or belt 110 that extends longitudinally along the conveyor 105. Depending upon the embodiment ultimately implemented, the belt 110 may be made of a variety of materials and configurations. For example, in some embodiments, the belt 110 may be made from a single rubber layer. In other embodiments, the belt 110 may be made of multiple layers that include an underlying layer, which provides linear strength, and a cover layer over the underlying layer. In these embodiments, the underlying layer may be cotton and/or metallic composites and the cover layer may be plastic, rubber, or combinations thereof. Additionally, in some embodiments, the belt 110 may include one or more grooves to increase gripping strength of items being conveyed along the belt 110. Furthermore, in still other embodiments, the belt 110 may be a woven structure with openings or gaps throughout. In some embodiments, the belt 110 may be made of plastic, plastic with rubber inserts, and/or plastic chain. Further, some embodiments may implement the belt 110 as a single wide belt, multiple thinner belts, and/or a belt with skate wheels.
In some embodiments, the device 100 may be configured to move the conveyor 105. For example, the conveyor 105 may be moved in vertical, horizontal, angular, or other directions. This may be accomplished using a robotic arm (not shown) that is coupled to the conveyor 105. Such robotic arms may be found in assembly lines, and may extend from above or below the conveyor 105 to support the weight of the conveyor 105. Other embodiments may utilize other types of devices or structures for moving the conveyor 105, as appropriate.
As shown in
An opposed or through-beam arrangement consists of a receiver located within the line-of-sight of a transmitter that may be located beneath the belt 110. For example, the receiver may be above the belt 110 (not specifically shown in
In the embodiments where the sensor 115 is a photoeye, the sensor may have different operational modes to determine the presence of items on the belt 110, such as “light operate” mode or “dark operate” mode. In light operate mode, photoeyes may generate a signal when the receiver “receives” the transmitter signal, whereas in dark operate mode, photoeyes may generate a signal when the receiver “does not receive” the transmitter signal. Examples of commercial products that may be used to implement the photoeye 115 include an Efector O1D100 photoelectric sensor from IFM of Exton, Pa. Of course, other embodiments are possible where the sensor 115 is implemented using different technology, such as laser, capacitive, background suppression diffuse, ultrasonic, pressure, and/or weight-sensing technologies.
Referring still to
As shown in
As shown in
The stack 124 of items 132 in the hopper 125 may have a height 135, defined as the distance between the top and bottom of the stack 124 within the hopper 125. As shown in
As previously discussed, the sensor 117 positioned at the end of the conveyor belt 110 may be configured to detect the height 135 of the stack 124 using the laser beam 120. In some embodiments, the sensor 117 may be filtered, such that items 132 falling off of the conveyor 105 and occluding or blocking the beam 120 may be disregarded by the sensor 117 in determining the height 135 of the stack 124. This may be accomplished through the use of a timer that is triggered when the beam 120 is blocked, and turned off once the beam 120 is unblocked. If the beam 120 is not blocked for over a minimum threshold time, the device 100 may restart the timer for the next item 132 detected by the sensor 117. However, if the beam 120 is blocked for over a minimum threshold time, device 100 may determine that the stack 124 is occluding the beam 120, and that the target fill level 140 has been reached. Other embodiments may utilize other methods for preventing inaccurate sensor 117 readings as to the height 135 of the stack 124. For example, in other embodiments, a signal from the sensor 117 can be low-pass filtered, with the effect of removing effects on the signal from possible temporary occlusion of the beam 120 by falling items 132.
Referring still to
In some embodiments, the device may simultaneously increase the speed at which the conveyor belt 110 is rotated and lower the conveyor belt 110, to simultaneously increase the height 135 of the stack 124 and decrease the drop distance 131 of items 132 into the hopper 125. However, in other embodiments, the device may only increase the rotational speed of the conveyor belt 110 or lower the conveyor belt 110. In further embodiments, the device may alternate between adjusting the speed of the conveyor belt 110 and the height of the conveyor belt 110 during operation.
When the height 135 of the stack 124 is higher than the target fill level 140, the device 100 may also raise the conveyor belt 110 (represented by arrow 128), if possible, to increase the drop distance 131 of the items 132 deposited into the hopper 125. This serves to maintain a desirable drop distance 131 between the conveyor belt 110 and the top of the stack 124, and prevent items 132 from being damaged or disordered as they are deposited into the hopper 125. For example, if the conveyor belt 110 was in the lowest position, such as for priming the hopper, then belt 110 could be raised until the target hopper level plus the ideal drop height is reached.
In some embodiments, the device may simultaneously decrease the speed at which the conveyor belt 110 is rotated and lower the conveyor belt 110, to simultaneously decrease the height 135 of the stack 124 and increase the drop distance 131 of items 132 into the hopper 125. However, in other embodiments, the device may only decrease the rotational speed of the conveyor belt 110 or raise the conveyor belt 110. In further embodiments, the device may alternate between adjusting the speed of the conveyor belt 110 and the height of the conveyor belt 110. In other embodiments, the speed of finishing conveyor 137 may be increased.
As discussed above, some embodiments of the stacking device 100 may attempt to maintain the stack 124 in the hopper 125 at the target fill level 140. There are many advantages to maintaining the hopper 125 at a constant target level 140, including maintaining a relatively constant drop distance of items 132 onto the stack 124, which prevents damage to the items 132 as they are dropped onto the stack 124. Another reason for maintaining the stack 124 at a constant level is to maintain a relatively constant weight on the hopper 125, which prevents jamming of the device 100. For example, conventional finishing devices often use vacuum to convey the first item from the bottom of the stack 124, and in the event that the stack 124 is too tall, then the weight of the stack 124, may be too great for the vacuum to work properly. As the fill level required in the hopper 125 is further reduced, which reduces the risk that the hopper 125 is emptied, and when the hopper 125 is emptied, it may cause production to stop altogether and/or necessitate human intervention to re-prime the hopper 125. Further, increasing and decreasing the rotational speed of the conveyor belt 110, rather than starting and stopping the conveyor belt 110, which is common in existing devices, serves to prevent clumping or grouping of the items 132 in the hopper 125, and allows for more even distribution of the items 132 being dropped into the hopper 125.
Next, in step 406, the height 135 of the stack 124 is compared to the target fill level 140. If, in step 406, the device determines that the height 135 is greater than the target fill level 140, then, in step 408, the device may raise the belt 110, which increases the drop distance of the items 132 from the belt 110. The method 400 may then proceed back to step 403. If, however, in step 406, the device determines that the height 135 is lower than the target fill level 140, then, in step 410, the device 100 may either move the belt 110 down or maintain the position of the belt 110, as further discussed with reference to
If, in step 506, the device 100 determines that the height 135 is above the low threshold level, then, in step 510, the device 100 may determine whether the height 135 is under the target fill level 140. If, in step 510, the device 100 determines that the height 135 is under the target fill level 140, then in step 512, the device 100 will increase the speed of the conveyor belt 110. The method 500 may then proceed back to step 504, in which the device 100 may again determine the height 135 of the stack 124. Accordingly, the device 100 will continue increasing the speed of the belt 110 until the device 100 determines that the height 135 extends at or above the target fill level 140.
If, in step 510, the device 100 determines that the height 135 is not under the target fill level 140, then, in step 514, the device 100 may determine whether the height 135 is at the target fill level 140. If, in step 514, the device 100 determines that the height 135 is at the target fill level 140, then in step 516, the device 100 may keep the rotational speed of the conveyor belt 110 constant. The method 500 may then proceed back to step 504, in which the device 100 may again determine the height 135 of the stack 124.
If, in step 514, the device 100 determines that the height 135 is not at the target fill level 140, then, in step 518, the device 100 may determine whether the height 135 is above the target fill level 140. If, in step 518, the device 100 determines that the height 135 is above the target fill level 140, then in step 520, the device 100 may decrease the speed of the conveyor belt 110. The method 500 may then proceed back to step 504, in which the device 100 may again determine the height 135 of the stack 124.
If, in step 518, the stacking device 100 determines that the height 135 is not above the target fill level 140, then, in step 522, the device 100 may determine that the height 135 is at or above the overfill line (i.e., a maximum threshold level either set by the manufacturer of the device 100 or the user). The overfill line may be, for example, the level at which the items 132 in the stack 124 are in danger of overflowing from the hopper 125. The device 100 may then halt the conveyor belt 110 in step 524. The method 500 may then proceed back to step 504, in which the device 100 may again determine the height 135 of the stack 124.
In some embodiments, the method 500 illustrated in
Once an item 132 is sensed by the photoeye 803, the device 800 may start a timer. The device 800 may stop the timer once the item is no longer sensed by the photoeye 803. If the photoeye 803 senses the presence of an item 132 for longer than a threshold period of time, the device may determine that the stack height 135 has grown above the target fill level 140. In such cases, the device 800 may slow down the conveyor belt 110 to minimize the growth of the stack 124. On the other hand, if the photoeye 803 does not sense the presence of an item 132 for longer than a threshold period of time, the device 800 may determine that the stack height 135 is below the target fill level 140. In such cases, the device 800 may increase the speed of the conveyor belt 110 to increase the height 135 of the stack 124.
Other embodiments may utilize two or more photoeyes 803(a), 803(b) that are positioned within the hopper 125. In one embodiment of the stacking device 900, shown in
In a further embodiment of the stacking device 1000, illustrated in
Other embodiments may utilize other types of photoeyes 803(a)-803(f) in connection with the device 1000. For example, in one embodiment, the photoeyes 803(a)-803(f) may include sets of infrared photodiodes and phototransistors mounted at different hopper levels on a single circuit board strip that extends along the height of the hopper 125. Each photodiode/phototransistor set may be configured to sense a different frequency of infrared light. A microprocessor controller, or other processing component for operating the photoeyes 803(a)-803(f), may also be mounted on the circuit board strip. In some embodiments, a lens with a coating to filter non-infrared frequencies may also be used to filter out ambient light. As an example, the lens may be formed from plastic, and may have a 12-inch focal length. The microprocessor controller may pulse each photodiode at a different frequency, allowing the device 1000 to distinguish between the different photodiode/phototransistor sets, which are each responsive to a different frequency. In one embodiment, the controller may further allow for transmitting the status of each photodiode/phototransistor set to a processing device, which may determine the height 135 of the stack 124 within the hopper 124 based on the received status information.
Although the various embodiments of the present disclosure have been described, persons of skill in the art will appreciate that changes may be made in form and detail without departing from the spirit and scope of the present disclosure.
Number | Name | Date | Kind |
---|---|---|---|
3030107 | Stidwill | Apr 1962 | A |
3143344 | Miller et al. | Aug 1964 | A |
3671753 | Lucas | Jun 1972 | A |
4313600 | Mosburger | Feb 1982 | A |
5152515 | Acquaviva | Oct 1992 | A |
5326088 | Newsome | Jul 1994 | A |
5439209 | Runzi | Aug 1995 | A |
5697753 | Aurora et al. | Dec 1997 | A |
5904465 | Villacieros Fernandez | May 1999 | A |
5997238 | Garrard et al. | Dec 1999 | A |
6003861 | Iizumi et al. | Dec 1999 | A |
6318954 | Voss et al. | Nov 2001 | B1 |
6427999 | Christofferson | Aug 2002 | B1 |
7066462 | Rilitz et al. | Jun 2006 | B2 |
7585146 | Widmer et al. | Sep 2009 | B2 |
20030015835 | Post et al. | Jan 2003 | A1 |
20030108416 | Schererz et al. | Jun 2003 | A1 |
20080128983 | Prim et al. | Jun 2008 | A1 |
Number | Date | Country |
---|---|---|
0 033 799 | Aug 1981 | EP |
0 844 201 | May 1998 | EP |
Entry |
---|
EPO Extended Search Report dated Sep. 25, 2013 for EP Appln. No. 13160183.3. |
Number | Date | Country | |
---|---|---|---|
20130259631 A1 | Oct 2013 | US |
Number | Date | Country | |
---|---|---|---|
61619125 | Apr 2012 | US |