The present invention relates to unloading conveyor systems for agricultural grain storage bins, and, more particularly, to conveyors mounted in a channel in the floor of a bin or under a raised floor of a bin being fed by a series of radially spaced openings or wells formed in the floor, through which grain is delivered to the conveyor by gravity, in collaboration with a sweep conveyor that rotates about a central pivot point of the bin to direct residual grain into one or more of the wells in the floor.
Seed and grain are commonly stored in grain bins and related storage structures. Grain storage structures-such as grain bins-commonly utilize a concrete foundation providing a foundation on which a series of formed steel rings (i.e. corrugated cylindrical sections) are joined and extend upward to form a cylindrical tank. Many such grain bins have perforated steel floors supported on the concrete foundation and spaced above the floor of the foundation, for purposes of passing air upwardly through the stored grain for aeration of the grain to control the drying and moisture content of the grain, preserve the grain, and reduce loss.
Horizontal unloading augers have been principally used in the past to remove the grain from the bin. These augers are placed between the concrete foundation and the perforated steel floor or in a trough formed in the foundation. The augers extend from the center of the bin through the side wall to several feet outside the bin for discharge into another mass flow auger or conveyor for subsequent transport to market or other use. The unloading auger carries grain away from an enclosed metal frame—a well—at the center of the grain bin. The grain flows via gravity through the center well into the auger. The center well typically has a moveable slide gate which can be operated from outside the grain bin to control grain flow through the well.
Eventually the bin empties to the point where no additional grain can flow under gravity into the center well, leaving residual grain on the outer edges of the floor of the grain bin extending from the center well and sloping upwards to the outer wall of the bin. The remaining grain, referred to as the residual grain, is considerable, rising from a few inches near the center to as much as ten or twelve feet at the outer wall, for larger diameter bins. The valuable residual grain is commonly removed from the bin via a powered horizontal sweep auger. This powered horizontal sweep auger rests on the perforated floor and may be placed over the unloading auger prior to filling the grain bin. Commonly, additional secondary wells are placed over the unloading auger to remove grain from around the powered horizontal sweep auger so it is free of the residual grain pile prior to commencing its rotary “sweep” operation. Power to the sweep is either transferred from the unload conveyor—as described in U.S. Pat. No. 7,544,031—or the sweep is powered with a dedicated electric motor, or equivalent power source. The sweep conveyor transfers power from the power source, through the auger or chain to turn an idler roller. The idler roller is coupled to a distal drive wheel such that power is transferred from the conveyor to the drive wheel. The driven wheel is mounted perpendicular to the length of the sweep conveyor and drives the sweep about the pivot point, like the hand of a clock.
Recent improvements have been made to grain bin unloading systems for purposes of reducing damage to grain. This damage is related to the clearance fit and steel flighting used in conventional unloading auger systems. Belt conveyors fitted under the perforated grain bin floor in place of auger unloading systems are now being employed to minimize damage to high value seed, as well as to improve energy efficiency and reduce unload time.
The belt conveyor is positioned under the perforated metal grain bin floor and may employ additional intermediate wells for removal of residual grain to clear the region about the power sweep before it is actuated. The drive roller typically employs a bonded rubber coating to provide sufficient traction to transmit power to the conveyor belt.
We recognized that removable cover plates would allow maintenance access to the belt without removing the belt from the conveyor system. These removable cover plates span across the trough or gap in a raised floor system. The removable cover plates must be reinforced to support the weight of the grain and the sweep conveyor. The removable cover plates are vertically supported by a plurality of ribs that extend along an axis perpendicular to the longitudinal axis of the horizontal bin unload conveyor. The ribs incorporate a tab that is received into the midpan to maintain proper spacing of the ribs sufficient to support the removable cover plates.
We also recognized that providing an overlap flange on the removable cover plates prevents grain from entering the midpan. The overlap flange covers the raised bin floor and extends over the external ledge to cover a portion of the raised bin floor to provide a seal. The overlap flange also provides a convenient place for securing the cover to the return trough.
We also recognized that ribs incorporating a rib end having a first rib support flange and a second rib support flange would prevent the ribs from falling over during the installation or maintenance. The rib ends have a first rib support flange and a second rib support flange that extend parallel to the longitudinal axis of the horizontal bin unload conveyor when the ribs are installed. This provides support to maintain the ribs in a vertical orientation when the tab is received into the tab slot.
We also recognized that a removable midpan can support the conveyor during transfer of the material from the bin. The removable midpan is suspended within the return trough and provides a separation between the outgoing, full portion of the conveyor belt from the returning, empty portion of the conveyor belt. The ribs span across the midpan to allow the outgoing and full portion of the conveyor belt to pass underneath the ribs. The rib tabs are inserted into respective tab slots appropriately spaced apart longitudinally along the horizontal bin unload conveyor.
In order to operate the well gates or the clutch for the sweep conveyor drive mechanism, a control rod extends longitudinally through the horizontal bin unload conveyor. In order to accommodate the control rod, the ribs incorporate a notch in the exterior side of a rib end. The notch allows the control rod to move along the peripheral interior portion of the midpan. The midpan is configured with various ledges to support the ribs and the control rod.
One limitation of current systems is the roller, ball bearing mounts, and clutch system are located internal of the bin at or near the center well of the grain bin. This makes maintenance on the rollers, ball bearing mounts, and clutch system exceedingly difficult. Existing systems require the raised floor be removed in order to access the bearings and to remove the roller. We recognized that the roller, ball bearing mounts, and clutch system could be more easily maintained by providing a side access portion to the center well. Additionally, a second bearing mount is mounted to the interior of the center well. In this way, the service parts are accessible within the center well and can be maintained without removing the raised floor. This access also allows the user to maintain the belt, such as splicing the belt, without removing the belt from the horizontal bin unload conveyor and without removing the raised floor.
We also recognized that longitudinal risers could be attached to the floor of the return trough to prevent the return portion of the conveyor belt from freezing or otherwise binding up on the bottom of the return trough. It is common for grain bins to be unloaded in the winter, and any residual moisture may descend to the bottom of the return trough. This moisture may freeze, causing the belt to bind up. This can damage the belt. By attaching risers that run along the longitudinal axis of the return trough, the belt is supported and does not make sufficient contact with the return trough to bind up. The return portion of the belt moves along the top of the risers.
We also recognized that a generally U-shaped backstop mounted adjacent to the roller at the end of the transition assembly can prevent grain from backflowing into the center well and the return trough. Belt conveyors are more susceptible to material interposed between the belt and the roller causing interference with the proper operation of the belt conveyor. The backstop has a lower profile that matches the shape of the bottom of the transition piece. The backstop has a central slot that allows the belt to pass through. The edges of the backstop rise up, generally perpendicular to the edges of the belt. In this way, the openings around the belt—other than directly above the belt surface—are minimized.
These and other features, aspects, and advantages of the present disclosure will become better understood with regard to the following description, appended claims, and accompanying drawings where:
In order to facilitate rapid access to the bin unload conveyor 10, a cover 20 is removably mounted to cover the bin unload conveyor. The cover 20 provides a top surface of the bin unload conveyor over which the sweep conveyor can travel over. The cover 20 is illustrated as pitched, having a central peak 24. The cover 20 prevents grain from entering at points along the bin unload conveyor 10 other than through the gated pit areas.
Also shown in
The midpan 30 is received into a return trough 40, as shown in
In order to support the cover 20 along the longitudinal length of the bin unload conveyor 10, the ribs 50 are longitudinally spaced apart at a predetermined interval, as shown in
Any residual grain, dust, or debris that accumulates around the belt and settle into the midpan 30 can be removed to the return trough 40 through the cleanout aperture 31, as shown in
One advantage of the current disclosure is that maintenance can be performed while the conveyor belt 5 remains installed in the grain bin.
In order to access and replace the first bearing 234, the central pit cover 221 located above the roller 228 is removed. The bolts holding the first bearing 234 to the access support wall 224 are removed. The access support wall 224 separates the belt return portion 223 of the central pit 220 from the service access portion 222. Within the service access portion 222, the sprocket connecting the sweep drive assembly 240 is disconnected. The lock collar 235 is loosened. The roller is then freed to slide horizontally. The roller can then be pivoted to the side, providing sufficient clearance to remove the roller from the second bearing 236. In order to remove the roller, the roller slot cover 232 is removed. The roller slot 230 is a vertical slot in the access support wall 224, which is illustrated in
Other maintenance that can be required with belt conveyors is tracking of the belt 5. The user can access the belt tracking mechanism 238 within the service access portion 222 of the central pit 220. The tracking mechanism is best shown in
Additional maintenance that can be required with belt conveyors include belt splicing to repair a section of the belt 5. By removing the cover 20, the user can access the belt to perform belt splicing and other belt repairs. Additionally, the use can access the belt in the return trough by removing the midpan.
Shown in the
Also shown in
As shown in
It is also contemplated that the pitch of the cover 20 may be flat. In a flat cover, the cover 20 would not have a central peak 24. The truss portion of the plurality of ribs would be formed with a flat top to accommodate the flat cover 20.
This application is a continuation of U.S. application Ser. No. 16/949,009, entitled “Grain Bin Unloading Conveyor System”, and filed 9 Oct. 2020, which is a divisional of U.S. application Ser. No. 16/552,674, entitled “Grain Bin Unloading Conveyor System”, and filed 27 Aug. 2019, which claims benefit of U.S. Provisional Application No. 62/724,125, entitled “Grain Bin Unloading Conveyor System”, and filed on 29 Aug. 2018.
Number | Date | Country | |
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62724125 | Aug 2018 | US |
Number | Date | Country | |
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Parent | 16552674 | Aug 2019 | US |
Child | 16949009 | US |
Number | Date | Country | |
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Parent | 16949009 | Oct 2020 | US |
Child | 18465326 | US |