DE2850184C2 - Plate conveyor belt, in particular for the transport of people - Google Patents

Description

The invention relates to a plate conveyor belt, in particular for transporting people, one behind the other articulated, together driven, an endless conveyor belt forming plates, wherein the conveyor belt has a path that is at least one with another plane through a convex circular arc-shaped Curve connected inclined plane.

Most well-known, especially passenger transport from one horizontal to another horizontal plane serving plate conveyor belts only the connection of the inclined part of the useful length of the conveyor belt with the upper level through a curve. The transition from the lower to the inclined The plane is generally achieved by means of a solid comb plate that is at least partially identical Has inclination like that of the conveyor belt. Such an arrangement corresponds to the existing safety regulations with regard to conveyor belts that transport people who are equipped with means of transport Objects carry with them, as this z. B. in self-service shops is the case where customers use shopping carts.

In these conveyor belts, the plates having a load-bearing flat surface are often on one of them Ends carried by one of the axles which have two endless drive elements, such as e.g. B. chains, connects with each other and has rollers, by means of which the conveyor belt rotates on guide rails. There are plates in the Relatively high ratio to their drive elements

ίο are arranged, the fixed balustrades with the conventional handrails generally attached to the side of the conveyor belt, with a small horizontal play is provided between the base plate of each balustrade and the corresponding side of the conveyor belt.

Since the conveyor belt sides move in a straight line in most facilities, this arrangement should " of the balustrades on the side of the conveyor belt, at least in theory, the horizontal play between the same and the base plate of each balustrade remain in place. However, such an arrangement has certain disadvantages on. Small objects falling on the conveyor belt can easily get between the moving conveyor belt and slide one of the base plates of the balustrade; the visible space can then be used by the user entice you to retrieve such an object at the risk of pinching your fingers and yourself to hurt. In the case of lines with a large plate length, this risk is even greater, since the smallest inclination of the the plate at one of its ends supporting axis, caused by any manufacturing inaccuracies or uneven wear, causing significant lateral displacement of the plate at its other end. That between Horizontal play provided on the conveyor belt and the base plate of the balustrades may become abnormal enlarged, reduced or even eliminated. A solution to limit the aforementioned risks, consists in arranging the arrangement of the fixed balustrades above the conveyor belt, in this case that between the load-bearing surface of the slabs and the The base of the plinth of the balustrade is necessary clearance vertically.

Such a solution does have compared to the previous one in the case of an exclusively horizontal useful route the conveyor belt has considerable advantages. However, it is with conveyor belts, which an inclined and through a Curve with a horizontal plane connected useful route, difficult to apply, since parts of the curve the distance the vertical play varies depending on the curve radius and plate length. That for them The normal play provided for straight parts of the path can therefore be found in the convex curves in the center of the plate be considerably enlarged. As in the above-mentioned solution, there is always a certain risk here for the User.

The invention is based on the object of designing a plate conveyor belt which has an arrangement of the Balustrades above the same allows, while maintaining the permissible values, both for the straight Parts as well as for the curve parts of the route vertical

(, Ο games of the same size can be provided.

This object is achieved according to the invention in a conveyor belt of the generic type in that each plate has a geometrically convex load-bearing surface in cross-section in its running plane and symmetrically to its central axis, which follows an arc-shaped curve, the radius of which is greater than the radius of the Conveyor belt traversed curve.
Records are in particular two execution

Examples of the invention shown, which are explained in more detail below. Show it;

Fig. 1 is a schematic representation of a side view of the cross section in the longitudinal direction of one of the plates a conventional plate conveyor;

Fig. 2 is a schematic representation of a side view of the cross section in the longitudinal direction of one of the plates of the plate conveyor belt according to the invention according to a first embodiment, on a part of the curve of the route;

3 shows a schematic representation of a side view the cross-section in the longitudinal direction of the plate according to FIG. 2, on a straight part of the route;

4 shows a schematic representation of a side view of the cross section in the longitudinal direction of one of the plates of the plate conveyor according to the invention according to a second embodiment;

5 and 6 show a part of the plate conveyor according to the invention in longitudinal section, on a straight part or a curve part of the route.

In the schematic illustration of FIG. 1, 1 denotes one of the plates of the Platicniörderbandes which moves depending on the furnishing in a direction indicated at arrow in the drawing directions. The plate 1 has on its upper part a load-bearing surface 1.1 which is arranged at a distance d to a straight line which, in the case of a straight path of the conveyor belt, corresponds to the lower edge 2.1 of the base plate of a fixed balustrade. This lower edge 2.1 of the base plate is shown by the conveying jo ribbon traversed distance with a convex curve by a chain curved line in accordance with radius R in the case of. Since in practice the intentionally increased distance d in the drawing is slight in relation to the plate length and to the radius of the convex curve traversed by the conveyor belt, this radius becomes identical to the radius R both in relation to FIG. 1 and in the other figures the lower edge 2.1 of the base plate of the balustrade is considered.

Fig. 1 shows that in a path traversed on a part of the curve, the amount of the distance d in the area of the plate ends is reduced to d \ = dh , where /; is the arch height which is formed on the curve of the radius R by the chord α corresponding to the length of the plate I. Fig. 1 also shows that if the plate 1 is arranged in such a way that the distance d is maintained in the area of the plate ends in a path section traversed on the curve part, a greater distance d \ = d + h in the area of the plate center results , whereby this distance is present over the entire length Ocr plate 1 for straight paths. F i g. I finally shows that if the load-bearing surface

1.1 of the plateau 1 would be convex in the shape of a circular arc according to a radius corresponding to the radius R , the distance d would remain constant for a curved path, but a greater distance i / 2 would occur at the ends of the plate for a straight path.

In the schematic representations of FIGS. 2 and 3, the upper part of the plate 1 in its laul plane and symmetrical to its central axis a load-bearing surface ^

1.2, which is convex in the shape of a circular arc according to a radius R 1 which is greater than the radius R of the curve traversed by the conveyor belt. Starting from an appropriate radius R 1, it is possible in this way to significantly reduce the difference between the minimum value d 1 and the maximum value d1. 2 and 3 also show that the height distance between the ends and the center of the load-bearing surface 1.2 makes up half the height distance h if this surface is circularly convex according to a radius R, ie a radius which is that of the conveyor belt Curve corresponds. If the distance d is assumed to be the minimum distance, it is located in the area of the ends and a maximum distance D = d + - when traversing a part of the curve of the route

the center of the plate 1 (Fig. 2). When traversing a straight path, however, the minimum distance d is in the middle and the maximum distance D is in the region of the ends of the plate 1 (FIG. 3). In this way it is possible to obtain maximum and minimum vertical play of the same size between the plates and the lower edge 2.1 of the base plates, both for straight and curved paths.

From the application of the formula Ii = R - VR ^: -a ²

it can be seen that R =

4 / rr ih

The radius Al, which is larger than R and corresponds to half the arch height, can be determined as follows:

Λ1 = —Sr-4Λ

This is how the relationship results

R. R \

A If + er "Sh '

Atf + er

2If + tr

which shows that the closer If approaches zero, as is the case with most devices where the arch height h is relatively small, the closer the ratio approaches

R 1

of the two radii ----- =.
κι λ

It is within the scope of the invention to provide plates with a geometrically convex load-bearing surface which follows an arcuate curve, the radius of which is greater than that of the curve traversed by the conveyor belt, but is not necessarily an arcuate convex surface. 4, the load-bearing surface 1.3 of the plate 1 is a polygonal convex surface consisting of three levels, which is formed according to the curve radius Rl, which is greater than the radius R of the curve traversed by the conveyor belt. The edges 1.31 and 1.32 resulting from the polygonal arrangement can be rounded. The load-bearing surface can also have a flat central part and circular arc-shaped ends, or vice versa.

The fig. 5 and 6 show part of a in longitudinal section Plate conveyor belt with one behind the other arranged) Plates 3, which are transverse to the direction of travel at -hrem The end are connected to one of the links 4.1, 4.2 of a drive chain 4 by means not shown further. Each drive chain 4: t provided with rollers 5, by means of which it moves on a straight (Fig. 5) or a convex curved (Fig. 6) guide rail 6. With 7 the base plate of one of the 'üe usual handrails supporting fixed balustrades is referred to. the Lower edge of this base plate 7 is, with a certain Vertical play, above the load-bearing surface 3.1 of the plates 3 arranged. In its running plane, symmetrical to its central axis, this load-bearing surface 3.1 is inventive

ingenious.! In the shape of a circular arc, convex in a radius RP. which is larger than the radius Ä.V of the curve traversed by the orderbancl, this radius KS being considered to be identical to the radius of the con \ e \ en curve (Fig. 6) / u provided on the base of the base plate 7 of the balustrade. As in FIGS. 2 and 3, the radius RP is such that between the linden trees and the mill 3.11 of the last projecting pool 3.1 of the plate 3 would constitute the dump of the valley plan. if this surface were circular arc-shaped koiivcv according to a radius Ä.S '. The two figures are also characteristic of the fact that with a straight stretch of the conveyor belt, there is a minimal amount of play ι // wipe between the base hole 7 Liiul of the Mille 3.11 of the lase 3.11 of the l'lallen 3. where ilas mi \ ini.ilc game /'.in ilen l'lallenenden belliidet. Hei a gekurvlen Wegsirecke contrast helindet a ma \ imales game / 'equal value in the mine 3/11 of lasiiragenden I-Iäche 3.1 animal!' Babble 3 and the minimum clearance </ i to \ c \\ l'lallenenden. In addition to the above-mentioned normal lines, the slight appearance of the cover lines 3.1 of the plan 3 offers more security against possible straight stretches, especially on inclined planes. The same applies to Hirauldeni I orderh.iiul transported Finkaulskorh wagons. and / was independent of the nature of her Mremssvsiems In addition, thanks to the uewolblen l'latlen. Each of the curved stretches of road form a polvgon-like plane, the kinked angles / wipe two lallels are significantly reduced in size and thus the line of communication is increased

The present disclosure concerns itself flour exclusively l'latlenlorilerbandcr. whose l'kitl η with endless elements. like / ii trowels, vei-inmden sum. as well as those. which millels I .lul'roll iiinlaulen. Lessen> This is also the case with l'laitenlorderbandern avaliable. animals planning by other MiHeI. /. It. Toothed racks, driven η or unthreaded at F. nd With a friction drive, for example, are hetesiigl.

For this purpose 2 sheets of drawings

Claims (6)

Patent claims: 1. Slat conveyor belt, in particular (Qr passenger transport, with one behind the other articulated, driven together, forming an endless conveyor belt forming an endless conveyor belt with a lateral balustrade arranged over the edge of the plates, wherein the conveyor belt has a path that at least one with another plane through a has inclined plane connected to a convex circular arc-shaped curve, characterized in that each plate (1; 3) has a geometrically convex load-bearing surface (1.2; 13; 3.1) in cross-section in its running plane and arranged symmetrically to its central axis, which follows an arc-shaped curve, whose radius (Al; Rl; RP) is greater than the radius (R; RS) of the curve traversed by the conveyor belt. 2. Pteiwn conveyor belt according to claim 1, characterized in that that the supporting surface (1.2; 3.1) of the plate (1; 3) has a circular arc-shaped convex surface is. 3. Plate conveyor belt according to claim 1, characterized in that the load bearing surface (1.3) of the Plate (1) is at least partially polygonal convex. 4. Plate conveyor belt according to claim 3, characterized in that the through the polygonal arrangement resulting edges (1.31 and 1.32) are rounded. 5. Plate conveyor belt according to one of claims I to 4, dadi: = h characterized in that the radius (R 1; Rl; RP) of the lasttreeenden surface (1.2; 1.3; 3.1) of the plate (1; 3) followed curve to such an extent is that the height distance between the ends and the center of the load-bearing surface is half of the height distance that is reached with a curve radius on this surface which corresponds to the radius (R; RS) of the curve traversed by the conveyor belt. 6. Plate conveyor belt according to Claims 1 to 4, characterized in that the radius (Rl; Rl; RP) of the curve followed by the load-bearing surface (1.2; 1.3; 3.1) is twice as large as the radius (R; RS) of the curve traversed by the conveyor belt.