In a walking floor reciprocating slat conveyor having a plurality of floor beams to support a load, and being longitudinally reciprocal to move the load longitudinally to an unloaded condition, and being supported by a transverse subfloor, having guides to control movement of the floor beams, and bearing/seal devices mounted to the subfloor and in bearing and sealing contact with the floor beams to prevent material that is part of the load supported by the floor beams from migrating below the floor beams.
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1. A walking reciprocating floor system for use in moving a load, which includes bulk particulate materials or the like, disposed in a designated area; , comprising:
a plurality of floor beams, said floor beams being adapted for supporting particulate materials thereon, and moving said load to an unloaded position, each said floor beam terminating in opposed vertically disposed side walls, said floor beams being disposed in side by side relation, and each being reciprocal along a longitudinal axis; a subfloor, said subfloor comprising a series of support members for supporting said floor beams for reciprocal movement relative thereto; guide means for guiding the movement of each said floor beams beam along a predetermined path, each said guide means being secured to one said support members member, each said floor beam further having a pair of depending opposed L shaped L-shaped members, said L shaped L-shaped members being disposed about one of said guide means for controlled directional movement there along when the floor beams reciprocate; and means defining a bearing/seal, said bearing/seal being mounted to said subfloor, and contacting the vertically disposed sidewalls side walls of said floor beams to provide bearing support therefor, and to thereby serve as a seal against the inadvertent passage of the particulate material disposed on the walking floor beams from its a position on the floor beams to a place there beneath therebeneath.
18. A reciprocating slat conveyor for conveying a load that includes particulate material, said conveyor comprising:
a plurality of side-by-side conveyor slats that are movable longitudinally in a first direction, for conveying the load, and are retracted longitudinally in the opposite direction; each said conveyor slat having a load engaging upper region including a pair of substantially horizontal, upper side portions, each with a lower surface and a longitudinal edge-forming portion, depending below said lower surface and including a lower edge; a base structure including a plurality of longitudinal guide members, one for each said conveyor slat, and a plurality of longitudinal slat support members, one for each pair of adjacent upper side portions of said conveyor slats; each said slat support member being positioned below an adjacent pair of said slat upper side portions and including an upwardly directed, hard plastic bearing/seal surface; and each said lower edge contacting and sliding along a said upwardly directed bearing/seal surface that is below said lower edge, wherein by this contacting, each lower edge and the bearing/seal surface below it seals against passage of said particulate material from a region above the conveyor slats to a region below the conveyor slats, and weight of the conveyor slats and the load on the conveyor slats is transmitted downwardly from the conveyor slats onto the slat support members.
11. A walking reciprocating floor system for use in a moving bulk particulate materials or the like, disposed in a designated area; , comprising:
a plurality of floor beams, each of said floor beams having a flat, essentially horizontally disposed upper surface, said floor beams being adapted for supporting and moving particulate material placed thereon, each said floor beam terminating in opposed vertically disposed side walls, said floor beams being disposed in side by side relation, and each being reciprocal along a longitudinal axis; a subfloor, said subfloor comprising a series of support members, said support members being disposed transverse to the longitudinal axes of said floor beams, and positioned for supporting said floor beams for reciprocal movement relative thereto; guide means for guiding the movement of each said floor beams beam along a predetermined path, each said guide means being secured to one said support members member, each said floor beam further having a pair of depending opposed L shaped L-shaped members, said L shaped L-shaped members being disposed about an associated one of said guide means for controlled directional movement there along when the floor beams reciprocate; and means defining a bearing/seal, said bearing/seal being mounted to said subfloor on opposite sides of an associated guide means, and contacting the vertically disposed side walls of said floor beams to provide bearing support therefor, and to thereby serve as a seal against the inadvertent passage of particulate material disposed on the walking reciprocating floor conveyor from its position on the floor conveyor to a place there beneath therebeneath.
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The present invention relates, in a general sense, to walking floorwalking floor reciprocating slat conveyor system 10 is installed in the van V. The floor system 10 is disposed longitudinally within the van in order to unload the van from the forward end 12, toward the rear end 14. The load within the confines of the van is protected from inadvertent discharge by doors 16, illustrated in the open position. The van is supported by rear wheels 18, and is towable by a fifth wheel system (not illustrated) or by any other well known arrangement.
The floor system 10 is perhaps best illustrated in FIGS. 2 through 5, and referring to FIG. 2 in particular, there is shown a plurality of reciprocatable floor members, or beams, 21, disposed in parallel relation. Each such floor beam comprises a horizontally disposed plank, or slat, portion 23, having a flat surface defining a load receiving face 25. The face portions of adjacent ones of said beams are coplanar, thereby presenting, in unison, a relatively flat, level surface upon which a particulate, or other load, may be firmly supported.
In order to provide support for the floor beams 21, the invention contemplates the use of a slotted subfloor, comprising a series of spaced support members 27. The support members 27 are supported within the van V by its own frame structure, such that the support members run transverse to the longitudinal axis of the van and are secured to the framework of the van V in spaced relation relative to one another. The support members, in addition to providing necessary and uniform support for the floor beams 21, provide rigidity and support for the van V.
The spacing of the support members 27 is a matter of intelligent choice, dictated to a substantial extent, by the weight to be supported by the support members, including the walking floor 10 and the maximum loads which are contemplated for the van's capacity.
As is the case with competitive walking floors reciprocating slat conveyors, the floor slats or beams are moved fore and aft along the longitudinal axis of the van V. They may be moved in one direction or the other, either in unison or in some alternative pattern, as may be desirable, but in any event, in an well known manner. Since such beams are long in their direction of movement, it is necessary to provide guidance for such movement to avoid misalignment, the inevitable consequence of which is the breakdown of the sealing arrangement and increased friction with coincident increases in wear, just to name a few.
Accordingly, guidance is provided for the floor beams 21 by guide members 30. Each guide member 30 is secured to the support members 27 by means of fasteners 31, which may be of any well known construction or type not inconsistent with the task of holding the guide members 30 securely in alignment.
Each guide member 30 is configured so as to be partially encircled by a floor beam 21. More specifically, and referring in particular to FIG. 4, each guide member 30, comprises an elongated strip, or more accurately, a series of strips joined together at their ends to form a rail upon which the floor beam 21 may reciprocate.
In order to optimize the performance of the guide members 30, they are shaped, in profile, in a substantially rectangular configuration with an upper body portion 32, having arcuate, or rounded, upper corners 34, the upper body portion 32 being supported on a lower body portion or stem 36. The lower body portion is, as seen in FIG. 4, secured to the lower support members 27, by fasteners 31.
Again referring to FIG. 4, and additionally to FIG. 3, each floor beam is formed with a pair of opposed depending "L" shaped legs 41. The "L" shaped legs 41 combine to define a channel beneath the plank portion 23, which channel is dimensioned to embrace the upper body portion 32 of the guide members 30, with inwardly turned flange portions 43, of legs 41 cupped beneath the lower surface 45 to secure the floor beam 21 from raising up from its position on the guide member 30.
In order to provide a minimum lateral or torsional movement, or torquing, of the floor beams during operation, they must fit as closely as possible about the guide members 30. Naturally, the more secure the fit the greater likelihood of frictional resistance to movement. In order to minimize frictional resistance to reciprocation of the floor beams, it is contemplated that the guide members be formed, or constructed of a high molecular weight resinous material, sometimes referred to in the trade as UHMW material. Such materials, which are available from several manufacturers, are strong, easily formed to a predetermined configuration, and have exceptionally low surface abrasion, which translates into an excellent bearing relationship between adjacent parts, even if the load on a particular floor beam is such that the beam is forced into contact with the guide member, or is unbalanced, creating upward forces on the lower surface 45 of the upper portion of the guide member.
An important feature of the present invention is the use of a novel bearing/seal system, which is perhaps best illustrated in FIG. 5. The essence of this seal arrangement is to prevent, insofar as may be realistically possible, the incursion of particulate materials, including "fines" of 100 mesh or better, into the pocket areas beneath the floor area, as may be observed in FIGS. 2 and 4.
In accordance with this aspect of the invention, intermediate spaced longitudinal guide members, and equidistant therebetween, the present invention provides a bearing/seal member 50. Each such bearing/seal member 50 parallels its adjacent guide members 30, and comprises a base member 52, which is secured to the subfloor support members 27, by means of a fastener 54, of well know construction. The base member supports a seal plate, or cap, 56 on its upper surface 58, which is secured by fasteners 60, which, as illustrated, comprise rivets of a compatible material such as UHMW.
In order to minimize friction and wear, even in the presence of heavy loads, the seal plate is preferably constructed of a material such as UHMW materials as previously described.
It will be observed in FIGS. 2 through 5 that the longitudinally extending side walls 63 of the plank portion 23 of the floor beams terminate in a downwardly extending ear 65, having an end, or termini, 67, which is formed with a small radius so as not to present a sharp edge to the seal plate. As seen in FIG. 5, the end 67 of the ear 65 engages the surface of the seal plate 56. As shown by FIGS. 2-5, the conveyor slats or beams 21 have upper side portions that project horizontally outwardly from the lower side portions or legs 41. The upper side portions include lower surfaces and ears 65. The ears 65 are depending, longitudinal edge forming portions. They depend below the lower surfaces and include lower edges 67 that contact the seal plate 56 and space the lower surfaces above the bearing/seal surfaces on top of members 56.
When the floor beam is under load, the end of the ear 67 and the seal plate 56 form an effective and very simple seal against the incursion or migration of particulate material to the subfloor area. Indeed, with time, the end 67 of the ear will form, by continuous reciprocal movement, a groove 70 in the face of the seal plate, which will, with wear, conform closely to the configuration of the end 67. Thus, as the seal plate wears in, the amount of surface area contact between the ear and the seal plate increases with the result that, with such greater surface contact, the seal becomes further enhanced as the ear 65 rides in that groove.
Because the wear is light, relatively speaking, the service period for a seal plate is quite long, much longer than industry expectations, and the maintenance associated with the novel floor of the present invention is coincidently, exceptionally good.
Thus, the pockets, or voids, defined by the bearing/seal members 50, and the guide members 30 remain exceptionally free of particulate material. Moreover, because the seal plate is of a low friction, high density material, it doubles as a bearing member, both supporting the floor beam, and providing the desired seal. Hence, the name bearing/seal.
The present invention further provides a novel system that has the added feature of being essentially self cleaning. Extreme "fines" are sometimes capable of passing the most effective seal, and when the floor is not under load, the seal formed by the present invention is somewhat less effective. In anticipation of at least some passage of particulate, the present invention simplifies the cleaning process, in avoiding the adverse consequences of build up in the pockets beneath the floor by spacing the support members 27. In this manner, any build up will pass beneath the subfloor, avoiding build up of material and consequent back pressure on the floor beams.
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