DE1586247A1 - Method and device for packing bricks - Google Patents

Description

Method and apparatus for packaging bricks The invention relates to a method and a device for applying steel strips single pile of bricks. to produce tightly tied packaging units, which are then combined into a larger stack consisting of a number ei; individual Consists of bundles of bricks that are held together by long edge protection strips, which lie under all ribbons and serve to keep adjacent bundles in place to keep with each other.

Known brick packs of the type mentioned have in view proved unsatisfactory for stability. Bs was often found that a brick pack, which when leaving the packing point a good cohesion showed it was lokker when it arrived at the deposit. The reasons for such unstable packaging are known. The main reason is in this, that there is loose sand from the kiln in the brick pack. This sand adheres to the stacked bricks, so that a tight fit of the neighboring Bricks in the pile is prevented. So when a pile is tied together a considerable amount of looser remains to form a brick pack unit Sand in the pack. Initially, the brick pack can still hold together well and the tape can be strong. As soon as this brick pack moves, however causes repeated inner pulls that cause relative movement between the adjacent bricks causes the sand to fall out, loosening the tape and the pack falls apart when unloaded by means of a fork truck.

Another reason for latent loosening of the packaging occurs especially with bricks that have raised spots in the form of irregular pyramidal shapes Have humps These humps allow crumbling under the initial tension of the tape resistance, but they break or crumble into powder as soon as the When moving, the pack is subjected to lateral forces and loosening occurs of the bound brick package.

A third reason for the loosening of the brick packing is Resistance of the steel band, slightly around the four edges the pack gu slide. During tensioning, most of the tension on the belt is applied to the first three edges consumed, so the furthest edge is not a sufficient one Tension is obtained to tighten the tape around all four sides of the pack.

The invention is based on the task of overcoming these obstacles, and for this purpose the individual brick packs are placed immediately before and during of tying together at high frequency, creating a finished brick pack arises that-its stability during moving the package ton the moment on, to aem it leaves the place of packaging at the kiln, until that Time at which it is deposited at the warehouse or construction site.

Zs: it is known that various objects, especially granular Materials can be packed more tightly together when shaken at high frequency so that they collapse under their force of gravity and become one for packaging form more compact cohesion. In the case of structural bricks, however, one rents high frequency vibration along with side compression of the stack and at the same time bind numerous unexpected advantages.

First, the jogging takes place while the pile is writhing the binding point approaches so that much of the sand is removed before the stack is tied together. The shaking continues during binding, making the stack centripetal Is subjected to forces to compress it from all directions, so that all sand particles that have not yet fallen out at this time into the porous Penetrate the surface of the bricks, where they occupy a position in which they are harmless are. This collapse of the particles takes place in four directions with respect to every brick instead.

Second, the high frequency jarring causes the stack to move during the bonding is subject to strong abrasion of the adjacent brick surfaces becomes, 80 that the various pyramidal humps on the surface of the brick continuously with the increase in tension in the applied straps laterally be removed.

After all, shaking the pile while it is tied together that the tape is relatively light around the four edges of the brick packs, so to speak "flows", so in all four lengths on the four sides of the stack the same Tension occurs.

The method described above for packing bricks forms the main feature of the invention. further details, advantages and features result from the following description. In the drawing, the invention is for example Illustrated, namely show: Fig. 1 partially in section, a perspective Partial view of a brick packaging device according to the invention, Fig. 2 in enlarged Scale shows a partial side view of a stack vibrator unit, FIG. 3 shows a perspective View of the outlet end of the device, FIG. 4 is a perspective view the vibrating device, FIG. 5 shows a section in the plane 5-5 of FIG. 4, and FIG. Figure 6 is a perspective view of a tethered package of bricks.

Referring to Fig. 1, a typical one comprised of individual bricks Brick pack 10 is a plurality of individual self-supporting packing units 12, one of which is shown in FIG. The pack 10 is similar to a known one Brick pack and consists of four pack units 12, the face to face adjoining are arranged one behind the other in the longitudinal direction. Each packing unit is by means of a steel band 14 tied together, and the various packing units are by edge protectors or strips 16 which have an L-shaped cross section and lie under the bands 14, held together against falling apart in the longitudinal direction. In certain areas of the pack 10, longitudinal rows of bricks are omitted, whereby openings 18 are formed which are intended to accommodate the forks of a lift truck to record.

The brick pack 10 differs in its external appearance not from a conventional brick packing and from a structural point of view only by that it has greater stability when moving and transporting it through the packaging method according to the invention is obtained.

The first process step for the production of a pack 10, at the stacking units 22 made of bricks at a loading point (not shown) and are conveyed on a running conveyor device 24 to a binding point 5, in order to produce packing units 12 is insignificant for the method according to the invention and known in the industry. For the purpose of explaining the invention, suffices Indication that the individual brick stacks 22 lie against one another at the binding point nd as shown in Fig. 1, and that the running roller conveyor 24 is switched in such a way that it conveys the stacks to the binding point onward in writing, where they are individually bound by a known binding machine 30.

As the stacks 22 advance, this becomes the edge strips 16 forming angular material continuously under tension on the four longitudinal edges of the stacked bricks applied as they advance towards the tie point.

At this point a steel belt loop 32 is placed around each stacking unit 22 with the aid of a known hand slide laid from or from the tape of the binding machine 30 is tightened to pull the loop 32 together on the stack. Thereupon the loop is stretched by the binding machine 30, and a fastener 3b (Fig. 1 and 6) is applied to the overlapping end sections of the loop, whereupon the free end of the tape is severed to wrap the packaging unit 12 disconnect from the tape source. The packaging units 12 tied together in this way, which are firmly connected to one another by the tension in the anthracite material 16 are incrementally advanced on the conveyor 24 and can be attached to a suitable separation point (not shown) divided into individual brick packs 10 will.

According to the invention means are provided by which each stack of bricks 22 is subjected to shaking vibration while being bound. To this Purpose, a pneumatic vibrating device 40 (Fig. 4) is connected to the conveyor 24, which is attached to the conveyor 24 and serves the rear edge areas all bricks 20 in the bottom row of bricks to be tied and also the front ones To carry the edge areas of all bricks in the bottom row of the next stack, who is the next to get to the binding site.

The conveyor 24 comprises a fixed frame 44 with one another opposite side rails 46 and the usual number of rollers 48.

The sequence of rollers 48 is interrupted at the binding point S, and the shaking device 4Ci 40 is arranged therebetween. A vibrating plate 42 has the shape of a long most with a beveled edge 50 for ease the sliding of the different bricks onto the plate. The whole plate extends across the conveyor 24, and iXre ends are held by flexible fasteners held resiliently, the upper and lower rubber parts 51 and 52 have between which a mounting plate 53 is arranged, which by means of bolts 54 on frame 44 is attached and one opening 55 for receiving a movable centering pin 56, which passes through the parts 46 and 48. A nut with a washer 58 holds the parts in place.

A pneumatic vibrating motor 60 is at 62 with the vibrating plate 42 screwed and is acted upon by a line 64 with compressed air. The motor 60 may be of any known commercially available construction suitable for the Plate 42 and the bricks 20 on it, the required vibrating effect to be granted, e.g. Model EP 40 "from Vibro-Plus Produots, Inc. Stanhope, N.J.

A part of the conveyor 24 forms a pre-compression point PCS. At this Means are provided for centering the stacking units 22 on the conveyor, which also compress the bricks contained therein transversely to a predetermined degree For this purpose, a stationary pressure plate 70 extends from the conveyor above, which is arranged opposite a movable pressure plate 72. The movable one Plate 72 is held on the outer ends of a plurality of pistons 74, which extend from pneumatic cylinders 76 attached to vertical supports 80 held brackets -78 are arranged. Flexible newspapers 82 connect the individual cylinder 76 with a compressed air source, and appropriate control valves (not shown) control the operation of the movable pressure plate 72.

Means are provided directly at the binding point S which refer to similar Mode a high degree of compression of the brick stacks 22 transversely inward during cause of binding, two pressure rollers 100 are spaced apart for this purpose from one another and rotatably arranged with their lower ends in a bracket 102. The upper ends of the rollers 100 are rotatable in a superstructure 104 of the conveyor attached. Opposite the rollers 100 there are two movable pressure bars 106, held in brackets 108; these are arranged on a piston 110, the protrudes from a cylinder 112 attached to a bracket 114. Flexible lines 116 drove BuCt to the cylinder ends.

To protect the bricks 20, the pressure strips 106 are provided with suitable ones rubber-like or other resilient contact strips resting on the bricks 107 provided.

When operating the device, the stacking units 22 are on the Loading point erected and gradually moved forward to binding point S during This forward movement, the edge strip material 16 is applied under tension. The conveyor 24 is controlled so that when approaching the first Stack 22 to the binding point S the lower front transverse edge, as in FIG. 2 shown, comes to rest centered on the vibrating plate 42. At that time is the previous one Stack has been pushed forward to a position in which its lower rear edge rests on the plate 42, the two stacks 22 essentially touching one another. At this point, the vibration motor 60 is switched on, with the piston 74 off the cylinders 76 step forward to the pressure plate 72 on the fixed pressure plate 70 to move, whereby the stacks 22 are aligned and also a moderate transverse inward pressure is exerted on the bricks at the same time the binding machine 30 is put into operation.

While shaking the two stacks near the binding point 5 the bricks 0 in the stacks do not change their position in relation to one another, obwohi a low rubbing effect between the individual facing brick surfaces takes place. The Bricks compressed in a direction across the stack, so that the major faces the bricks are subjected to a rubbing or abrasion effect. That's why this serves Vibrating the brick serves a dual purpose. First, it serves to keep the brick moving to move and thus any adhering sand particles to shake loose that have been carried along from the kiln. Effect on bricks with a strong structure the irregular formation of the surfaces that neighboring surfaces do not initially completely in close contact1 so that the loosened pieces of sand their heaviness easily makes their way down through the columns-the pile to the outside can find. Second, it occurs due to the relatively light pressure inside or across the stack as a whole through the two pressure plates 70 and 72 is granted, a certain amount of abrasion or self-sanding of the itself opposite major faces of the brick on, creating any bumps or humps are removed. The driving off of such humps creates additional t1Sand, which, due to its gravity, is also first led to an exit point will. If the two pressure plates continue to vibrate and continue to press, they will open I slowly move the stack of bricks into closer contact with one another. S-obald the binding of the initially preceding pile directly at the binding point S is finished, in order to produce a fully bound package unit 12, the Pressure on the stack is momentarily relaxed, and one step of the conveyor 24 is used to move this packaging unit further from the binding point and the next Pile that has now been partially freed of sand and compressed quite tightly, to be transported to the binding point, where it has its supported position on the vibrating plate 42 divides with a following stack, which is forwarded to the precompression point POS has been pushed.

The new and thus partially treated stack at the binding point will be jogged, squeezed and bound at the same time when the jogger motor 60 and the binding machine 30 switched on in the normal progress of the work cycle are. When these devices are turned on, the moveable ones move Pressure bars 106 in the direction of the stationary pressure rollers 100 and arrive the stack located between the bars and roles to the plant, with one Apply a relatively large amount of pressure on the stack in the transverse direction. The effect this combined jogging and cross printing process is the same as the one before Effect produced at the precompression point, only it is a little more intense. At the Pre-compression will most of the larger pieces of sand from the stack removed so that only the finer particles remain to be removed. Furthermore, the neighboring bricks, which are now tighter and under greater pressure lie against each other than when the stack arrives at the pre-compression point the himself resulting abrasion more carefully "scrubbed". In the end such fine particles that have not found time sit down through the pile settle through, in the surface pores of the bricks down, so that neighboring Bricks are completely next to each other.

Claims (7)

Claims: 1. Method ZUnL producing a substantially sand-free rectangular packing unit made of bricks produced in the kiln, which from superimposed rows of individual, surface to surface adjacent and bricks arranged in transverse rows and one encompassing the pack and itself around the four longitudinal edges of the pack and to hold together the adjacent Tensioned metal tape used for bricks, characterized by the following Process steps: Arranging the bricks (2D) in a pile in which they one of their take the corresponding position for the final position in the stack, apply a transverse pressure onto the stack to press the neighboring bricks together firmly, simultaneously Vibrating the stack as a whole to create a rubbing effect between the surfaces the neighboring bricks and for removing stuck kiln sand together with the abrasion products due to its gravity and tension of the belt (14) around the so treated stack for the production of the packaging unit (12). 2. The method according to claim 1, characterized in that the method step tensioning the tape (14) around the stack by pulling the tape over the circumference around four Long edges of the stack at the same time as performed by shaking the stack and compressing the stack in the transverse direction is to the sliding property of the metal band (14) over the edges through the through to improve the dynamic friction caused by the vibration. 3. Method of making successive compact rectangular ones Packing units of bricks produced in the kiln. Which are essentially free of kiln sand, with each packing unit made up of rows one on top of the other consists of individual bricks, the surface to surface arranged adjacent to one another in transverse rows are, and from a surrounding the packing unit and around its four longitudinal edges extending and tensioned to hold the adjoining bricks together Metal band, characterized by the following process steps: Collecting the bricks a packing unit (12) at a stacking point for producing a stack in ' to which the bricks (20) correspond to their final position in the packing unit assume a predetermined position, conduct the so. assembled stack in longitudinal row one after the other and in the forward direction one after the other and in the order mentioned to a pre-compression point (PCS), one binding point (S) and one Unloading point, the successive stacks at the pre-compression point (PCS) be squeezed together in the transverse direction to hold the adjacent bricks tightly together while at the same time shaking the stack as a whole to produce an abrasive effect between the surfaces of the neighboring bricks and removing the stuck kiln sand along with the abrasion product due to its severity and maintenance of the Cross printing and jogging the successive stacks at the binding point (S) with simultaneous tensioning of the straps (14) around the stack treated in this way Manufacture of a packing unit (12) .. 4. Device for packing bricks made in the kiln, characterized by a conveyor (24) for conveying a plurality of closely spaced ones Stack in a longitudinal row forwards in the longitudinal direction from a stacking point one after the other and in the order named via a precompression point (PCS) and a binding point (S) to an unloading point, by means for switching the conveyor to incremental Advancing each stack, the precompression point (PCS) and the The binding point (S) are so close together that there is a stack at the binding point is close to the next stack at the precompression point, by means (70.72), at the pre-compression point, those at the opposite Pages of at least the next stack can be placed in order to press the stack together to compress the opposite faces of the adjacent bricks (20) in the transverse direction, by means (100,106,107) at the binding point (S) also for compression of the stack in vuerrichtung at this point, by means (40) for shaking the next stack at high frequency at the precompression point to generate a rubbing action between the faces of the adjacent bricks due to compression of the stack in the transverse direction and removal of the adhering kiln sand together with the abrasion product by its gravity and by means (30) at the binding point (S) for applying metal strips (14) to the stack at this point. 5. Apparatus according to claim 4, characterized in that the means (40) for shaking the next stack at high frequency at the precompression point (PCS) comprises a vibrating plate (42) which is on the way of advancing the stack is arranged and can be applied to the lower surfaces of the stack. 6. Apparatus according to claim 4, characterized in that in addition Means (40) at the binding point (S) for vibrating a stack at a high frequency provided at this point during the application of the tape (14) to the stack are. 7. Apparatus according to claim 6, characterized in that the Means (40) at the Yorkompressierstelle (PCS) and the binding point (S) for shaking the respective stack at these points arranged in the path of the movement of the stack Has vibrating plate (42) attached to the lower surfaces of the stack at the binding point and the next stack can be placed at the pre-compression point.