FI75783C - OEVERFOERINGSANORDNING FOER VARUENHETER. - Google Patents

Description

75 78 3

The present invention relates to a transfer means for moving separate items of goods, and in particular for transferring items of goods in collection warehouses from a bus on a conveyor, according to the preamble of claim 1.

Conventional equipment in collection warehouses comprises a plurality of roller tracks which act as pathways for storing and feeding units to a collection conveyor, which then transfers the units from the warehouse for loading into e.g. vans, etc. The typical length of the bus collection is 5 to 20 m and is usually inclined. , such as in dairies, e.g. milk transport boxes, would roll from the point of entry towards the conveyor. At the end of the journey, the rolling is normally braked by automatic, e.g. photocell-controlled, brake rails so that the box plates roll as close as possible to the bus end of the conveyor and so that the deceleration of the box stacks during rolling is so even that the stacks do not fall over. The result is often that items of goods, such as boxes, stop before the end of the bus and do not continue their journey because the tilt is not enough to overcome the resistance caused by friction. The situation is thus contradictory, as a reliable achievement of the bus end would require an increase in inclination, which in turn would lead to such an acceleration of braking that the box stacks collapse. This problem has been solved by separate bus-specific conveyors which move the stacks of boxes to the conveyor-side bus end if they have stopped before this. Furthermore, the conventional equipment comprises a transfer carriage which is brought to the respective bus and which transfers the goods unit from the bus to the pick-up conveyor. The bus-specific conveyors as well as the conveyor included in the transfer carriage are usually belt or chain conveyors as well as the collection conveyor k i n.

2 75783 This conventional equipment is very complex, as it comprises a roller conveyor, an automatic braking device and a conveyor for the final transfer for each bus, as well as a separate conveyor in the transfer carriage. Such complex equipment is expensive to acquire and operate and is prone to malfunctions. When handling food, maintaining the necessary hygiene is also complicated and expensive.

Efforts have been made to solve these problems by replacing the roller with a horizontal or almost horizontal rail on which the units rest. Goods units, such as boxes, are then made to move forward on the fairway by using rods or chains to which pivoting teeth are attached which, e.g. unobstructed access. In this case, the units of goods thus slide along the said rails when they are pulled by means of the teeth. It is clear that this method can only be used when the items are boxes that can withstand the point load caused by the teeth. In addition, when the draw is started, when the rest friction changes to 111 k e k 1t, a jerk is created, which can overturn the stack. In addition, this structure is also quite expensive, because each bus, which can have dozens, must have a complete machinery and the transfer carriage must have its own conveyor. Maintaining the hygiene of this bus-specific conveyor is no simpler than even a roller-based bus.

When exploring other conveyor alternatives that could be used on each bus, no usable alternatives are found. Belt conveyors are expensive and difficult to keep clean, and conventional beam conveyors, on the other hand, are not suitable because the structure determines the length of a single transfer step, so that the unit cannot be moved exactly to the end of the bus.

By means of the transfer means according to the invention, a substantial improvement in the above-mentioned drawbacks is achieved. To achieve this, the device according to the invention is characterized by what is set forth in the characterizing part of claim 1.

The most important advantages of the invention are that the freight units can be moved by the transfer means on the bus of the exact desired distance in each case without start or end turns, that the transfer of goods from the bus to the pick-up conveyor takes place by the same transfer means, that the transport means itself is the maintenance of the hygiene of the remaining other bus structures is very simple and that the structure of the transmission means is simple and inexpensive, which is further facilitated by the fact that the entire bus system can be operated by a single drive on the transfer carriage.

In the following, the invention will be explained in detail with reference to the accompanying drawings.

Fig. 1A shows a substantial structural part of the bus unit transfer means according to the invention in a side view, Fig. 1B shows a cross-section along the structure YY of Fig. 1A, Fig. 2 shows a typical bus system provided with the transfer means of Fig. 1, Fig. 3 shows the main part of Fig. 1 separately. and Figure 4 shows the shape of the trajectory of the transfer means in principle.

7 5 7 8 3 4

In Fig. 1, the transfer means according to the invention consists of a C-shaped beam 1, which is placed in such a position that the opening point 11 is downwards. This beam is movable and the outer surface of its web 12 supports the goods units 5 during transfer (Figure 2). A vertical branch 13 of the T-beam 4, for example, is inserted into the C-beam 1 via the opening point 11. This beam 4 is fixedly connected to the support structures of the bus system and its shape is otherwise irrelevant except that the branch 13 passes through the gap 11. Attached to the leg 13 of the beam 4 are periodically fixed pivot pins 3 perpendicular to the plane of the leg and thus substantially horizontal. Eccentric bodies 2 are pivotally mounted on these pins. When the transfer means is at rest the C-beam 1 is in the lower position E and the inner surface of its web 12 rests on the perimeter 2 against the end part 17. The cargo units then rest on the busbar support rails 6 (Fig. 2).

When the goods units have to be moved on the bus in the direction S2, the C-bar 1 is pulled in this direction. In this case, due to the friction between the inner surface of the web 12 of the C-beam and the circumferential surface 14 of the eccentric body, the eccentric body 2 begins to turn around the shaft pin 3. The circumferential surface 14 of the eccentric body 2 thus rolls. Along the inner surface of the web 12 of the C-beam 1, when the C-beam 1 is pulled in the direction S2, the eccentric body pivots. Figure 1 shows the rest position A of the eccentric body with a thin solid line, the slightly rotated position B with a broken line, the more rotated position C also with a broken line and the final position D with a thick solid line, i.e. the eccentric body rotates from position A through positions B and C to position D. where the center of curvature 15 of the circumferential surface 14 is below the axis line 16 of its shaft pin 3 when the eccentric body 2 is in the rest position A, the C-bar is raised by its eccentric body 2 to its upper position F while the beam is pulled and the eccentric body rotates. When the C-beam rises, it also lifts the goods units 5 on the outer surface of its web 12 off the support rails 6. Once the eccentric body 2 has reached its extreme position D, the pulling of the C-beam 1 in the direction S2 can be continued in the upper position F, while the beam web The inner surface 12 slides along the first end portion 18 of the circumferential surface 14 of the eccentric body. In this case, the straight sector side 20 of the eccentric body opposite this first main work 18 is against the branch 21 adjacent to the opening of the C-beam 11, which prevents the eccentric body from further rotating from position D. .

When the item 5 is in the desired position, the pull of the C-bar 1 is stopped calmly, as its movement was started. In this case, the items of goods, such as the stacks of boxes, are certainly left upright, since they are softly lifted off the support rails 6 and likewise lowered back. The goods units are lowered back onto the support rails 6 by moving the C-beam 1 a small distance backwards, i.e. in the opposite direction to S2, where the eccentric 2 starts immediately and regardless of the amount of traction in direction S2, pivots about its axis-loss part from position D, through positions C and B Correspondingly, the C-beam 1 descends from the upper position F to its lower position E. This return is completely reversed with the reversal in the second direction just described, and the goods units 5 then descend on the support rails 6. When the eccentric body is in the rest position A, the C-beam 1 can be pushed back against the direction S2 any further so that the inner surface of the beam web 12 slides along the other end portion 17 of the eccentric body 2, while the straight sector side 19 opposite this end portion 17 is the C-beam opening. 11 against the adjacent leg 21, which prevents the eccentric body from rotating further from position A.

The construction is thus such that the distance between the lower and upper positions of the C-beam 1 is determined by the design of the eccentric body 2 and typically by the distance H between its center of curvature 15 and the axis 16 of the shaft pin (Fig. 3). The travel of the C-beam in the direction S2 and in the opposite direction has no lower or upper limit per se, but its operating limits determine its upper limit. Longer transfers are then obtained simply by repeating the maximum possible travel a sufficient number of times. Short movements are obtained simply by moving the C-bar 1 only for that desired short distance, which is less than the maximum possible Business distance.

The beam construction is also very hygienic because it has no cracks open upwards or even to the side that would collect contaminants and would be difficult to clean. The only opening in the construction is the downward slot 11, because the ends of the C-beam 1 can also be closed. Hardly any impurities can accumulate through this gap 11.

A preferred eccentric body 2 according to the invention, shown in Figure 3, consisting of a cylindrical circumferential surface 14 with end portions 17 and 18, the circumferential surface radius R and a center of curvature 15, a hole 22 for the shaft pin 3 and two substantially perpendicular sector surfaces 19 and 20, wherein the center of curvature 15 and the axis line 16 of the shaft pin are on the same line parallel to the second sector side and have a mutual distance H on this line.

Fig. 4 shows graphically the trajectory of a point in the C-bar from the rest position A of the eccentric 2 through positions B and C to the upper position D, which corresponds to the position F of the C-bar and where the C-bar can be moved in the + S2 direction and back from the C position and B to a rest position A corresponding to the position E of the C-beam and in which the C-beam can be moved without restriction in the direction -S2, whereby the eccentricity dimension H of the eccentric body determines the distance between its positions A and D and the C-beam positions E and F, respectively .

7 75783

Figure 2 shows a typical bus system with passages 23a ... d, each of which has support rails 6 for supporting the goods units 5 at rest, C-beams 1 for moving the goods units 5, a collection conveyor 7 to which the goods units are transferred from the lanes 23 by a transfer carriage. 8. The goods units 5 are brought to the lanes 23 from the direction S1, they move on the lanes in the direction S2 and are conveyed by a conveyor 1a in a direction S3 which is substantially perpendicular to the direction S2. After this transport direction S3, the goods units can be further moved and handled as required. In order to simplify the whole process or chain shown in Fig. 2, i.e. to transfer the items on the lanes 23, to precisely align the items on the collection conveyor side bus ends 24a ... d and to transfer the items from the lanes to the collection conveyor 7, it is advantageous to use only one C-bar in the carriage 8. This drive device 9 is connected to the C-beam of the bus in question on the shaft 10, whereby in this bus the nearest goods unit is transferred to the collecting conveyor 10 by moving the C-beam and subsequent goods units to the bus end 24d. In this way, the part of the hardware left in the bus is extremely simple and cheap and thus the whole hardware. At the same time, there are no organs left in the fairway, the keeping and hygiene of which would cause problems.

The device according to the invention is not limited to the embodiment described above, but the beams may be shaped in other ways, the eccentric body may have a different shape, the friction surfaces of the rails and the eccentric body may be tapered or toothed, the eccentric body may be resiliently mounted and the bus can be any storage. be side by side or on top of each other. In particular, the circumferential surface of the eccentric body may have a shape other than a circular cylinder. In this case, it may not have an exact center of curvature, but an effective center of curvature.

8 75783

Type isestl beams and rails are made of metal and eccentric pieces are made of plastic, but the invention is not limited to these materials. The drive device 9 can be a hydraulic cylinder or an electric motor or other suitable power source in each case.

Claims (7)

9 75783 A conveying means for moving separate units of goods in a substantially horizontal direction, the conveying means comprising at least one longitudinal beam (1) for lifting the units off the base, moving the beam in its longitudinal direction and lowering it onto the same or another base and eccentrics (2) for said detachment and lowering; (2) consists of a circumferential surface (14) whose effective center of curvature (15) differs from the center line (16) of the pivot axis (3) of the eccentric body, that the pivot axis (3) is stationary, that the longitudinal beam (1) rests against the circumferential surface (14) the longitudinal beam is moved in its longitudinal direction to move the item, wherein the circumferential surface (14) rolls along the surface of the longitudinal beam (1) while raising the beam and wherein the longitudinal travel of the beam corresponds to the desired item travel. Transfer means according to claim 1, characterized in that the eccentric body consists of a cylindrical circumferential surface (14) with end portions (17, 18) and two substantially perpendicular surfaces (19, 20) delimiting the end portions and at least partially perpendicular to the circumferential surface (15) and the center line (16) of the axis of rotation are approximately in a plane parallel to the second straight surface at a distance from each other. Transfer device according to Claim 2, characterized in that the longitudinal beam (1) is in its upper position (F) when it rests with its weight substantially on the end portion (18) of the circumferential surface (14) of the eccentric. the direction of the plane formed by the center of gravity (15) and that the longitudinal beam (1) is in its lower position (E) when it rests with its weight substantially on the second end portion (17) of the circumferential surface (14) of the eccentric body. 75783 Transfer device according to one of the preceding claims, characterized in that the longitudinal beam (1) is a C-beam, the opening point (11) of which points downwards and in which the eccentric pieces (2) are arranged. Transfer means according to Claim 4, characterized in that the circumferential surface of the eccentric bodies (2) abuts the inner surface of the web (12) of the C-beam (1) and that the eccentric bodies (2) are supported via the opening axes (11). Transfer device according to one of the preceding claims, characterized in that part of the transfer of the longitudinal beam (1) to the conventional units takes place in a position of the eccentric body (2) which holds the longitudinal beam (1) in its upper position (F) and slides the circumferential surface (14) of the eccentric body or its first end portion (18) and that the corresponding non-moving return movement of the longitudinal beam (1) takes place partly in the eccentric body (2) position holding the longitudinal beam (1) in its lower position (E) and the longitudinal beam sliding along the eccentric (14) or another end part thereof (17). Transfer device according to one of the preceding claims, characterized in that it comprises a plurality of longitudinal beams (1) operated by a separate drive device (9) separate from them, which is connected to the respective longitudinal beam (1) by means of a coupling element (10). 5) to move just at this longitudinal beam. 11 75783 1. Restructuring of the supply of ski equipment in the eastern part of the country and in the interests of horizontal management pl decamma ellat annat underlag och eccentrick (2) för a Istad-komma det nämnda avskiljandet och nedleggetet, kännetecknad av att ecstecstykket (2) bestär av en ringyta (14), vars efektiv krökningsmittpunkt (15) avviker frän centrumlinje swing axle (3), the swing axle (3) and the swath axle (1) the swing axle (14) and the swing axle (14) the swing arm (14) ytan av längsbalken (1) och lyftar balken velvet-digt ocv varvid balkens rörelseavständ i 1ängdriktning mot-svarar det önskade överf1yttningsavständet av varuenheten. 2. a conversion according to claim 1, the pivoting means of an eccentric ring having a cylindrical ring (14) with a double ring (17, 18) as well as a longitudinal winch with a fixed color of the outer ring, including 20. 3. a transverse arrangement according to claim 2, the tongue-and-groove ring (1) is provided with a single ring (F) which is connected to the lower ring (18) of the eccentric ring (14), the weight of the planet is represented by the center (16) and the ringing point at the center of the plane (1), and in the case of a ring (E), which means that it is present at the center (17) of the eccentric ring (14) of the eccentric ring (14).