DE2166900B2 - Endless conveyor belt for spiral conveyor tracks - Google Patents

Description

The invention relates to an endless conveyor belt for helical conveyor tracks, according to the preamble of the patent claim.

From US-PS 34 94 456 or DE-OS 14 81 006 is a conveyor belt with a plurality of cross bars known, which are articulated by attached hook-shaped Güeder at their ends are, wherein the hook-shaped members are formed so that they are relative without separation from each other are mutually collapsible and are brought into engagement with a drive device.

If such a conveyor belt is guided over a helical conveyor track, then there is Difficulty keeping both edges of the conveyor belt taut at all times. The cross bars are only loosely connected to each other by the hook-shaped members, so that there is a risk that in the absence of tensile stress, the driving forces are not transmitted properly and a one-sided Slack in the conveyor belt is to be feared ..

The invention is based on the object of designing the connection of the crossbars in this way. that this Conveyor belt remains essentially level during operation, while the links on his outer edge always under tension.

This object is achieved according to the invention in that the relative movement between the members that lie on the inside of the helical conveyor track is less than that of the links that are on the helical conveyor track are outside, and that the inside lying on the helical conveyor track Members are in engagement with the drive device.

The links along the inner edges of the conveyor belt are so collapsible that the inner edges can assume different curvatures when they are along the helical Move conveyor track.

With the invention the advantage is achieved that the links of the conveyor belt along its inner edge when moving through curves of the conveyor track are pulled apart and pressed against each other, so that the inner edge adapt to different curvatures without one-sided sagging of the links can.

The conveyor belt is continuously loaded with objects such. B. baked goods or loaves of bread that moved through a cooling zone, loaded on the lower portion of a helical conveyor track or loaded. The objects migrate upwards along the conveyor track, changing at the top of the Conveyor belt over to an inner spiral and are down along the inner conveyor track conveyed where they are taken.

An embodiment of the invention is in the following explained in more detail with reference to the drawings

ίο F i g. 1 is a schematic perspective view a helical endless conveyor belt according to the invention;

F i g. FIG. 2 is a partial top plan view taken along lines 2-2 of FIG. 1 showing a bottom portion of the conveyor belt and

Associated infeed and unloading conveyors are illustrated, which convey items to the conveyor belt supply and remove from this;

Fig. 3 is an enlarged partial plan view of a portion of the conveyor belt showing the inner edge

Μ shows it in an extended or uncompressed state;

F i g. 4 one of the F i g. 3 similar view, but in which the inner edge of the conveyor belt is in a compressed condition;

Fig. 5 is an enlarged end view of another Conveyor belt section taken along lines 9-9 of Figure 3;

6 is an enlarged end view of the inner Edge of the in F i g. 3 conveyor belt shown;

FIG. 7 is an enlarged end view of the inner edge of the FIG. 4 shown conveyor belt.

F i g. Figure 1 shows schematically a helical conveyor having an outer helical conveyor track 12 and an inner helical conveyor track 14 which is concentric with the outer conveyor track 12 is arranged. The inner and outer helical conveyor tracks 12 and 14 are by an endless movable conveyor belt formed. At the top and bottom of the conveyor are the helical ones

Conveyor tracks 12 and 14 through transfer sections 16 and 18 of the conveyor belt connected to one another. At the upper end of the conveyor belt or conveyor track 12, 14, the diameter of the transition section 16 consequently decreases as it extends curves helically inwards and downwards to enter the inner helical conveyor track 14 to pass over. At the bottom or bottom of the conveyor, the transition section 18 gradually increases in diameter as it moves outward

so bends to go into the outer in Fig. 2 to pass over the helical conveyor track 12 shown.

The lower portion or loop of the outer helical conveyor track 12 is in shape formed two sections 20 and 22, which in different levels or heights lie and through a vertical section 23 are interconnected, as shown in FIG. 1 is shown. The movement of the Conveyor belt through sections 20, 23 and 22 is spaced vertically through Rolls 25 out, over or under which the conveyor belt runs. When the conveyor belt moves clockwise in the direction of travel, as shown in Fig. 2 is indicated, it rises above a vertical Section 26 diametrically opposite the vertical Section 23, whereupon the conveyor belt along the outer helical conveyor track up through the successive loops or turns runs.

In the exemplary embodiment shown, the objects to be transported (not shown) are on introduced in any suitable manner, e.g. B. by a conveyor 27 onto the lower belt section 28, into which the vertical section 26 runs, as shown in FIG F i g. 2 is shown

After the articles have been transposed to the top of the conveyor and then down through the inner helical conveyor track 14 , they are removed from the lower portion 20 of the outer helical conveyor track 12 by means of a second endless conveyor 29 similar to conveyor 27.

The conveyor belt shown in FIGS. 3 to 7 contains a number of transverse rods 100 which are made of steel or some other material and extend transversely to the conveyor belt and are arranged at a distance from one another in the longitudinal direction of the conveyor. The crossbars 100 are connected to one another at their opposite ends by means of links 102 and 104 which form a part with the crossbars 100. The links 104 on the outer edge of the. Conveyor belt are U-shaped or hook-shaped in order to receive the ends 101 of the adjacent crossbars IuO at their bent sections 105 . It can be seen from FIG. 2s FIG. 5 that small spaces 106 are present between the ends of the outer links 104 and the adjacent bent sections 105 of the closest link 104 . As a result, the crossbars 100 can only collapse or expand to a very limited extent at their outer ends. In the FIG. 5 and 6, the outer links 104 are in their fully extended or tensioned position, which they always assume when the conveyor belt in the helical conveyor is actually in operation. Although this is not shown, the outer links 104 can however also be embodied in this way be that they do not push themselves together at all relative to one another. This is due to the fact that the outer links 104 are always under tension when they are actually in use, as will be explained below. In a special embodiment of a conveyor belt in which the width of the cross bars 100 (conveyor belt width) is approximately 580 mm, the spacing of each outer link 104 is approximately 25 mm.

The links 102, which form the inner edge of the conveyor belt, have a smaller longitudinal extent than the outer links 104 . Further, the inner members 102 are adapted to collapse from an expanded position shown in FIG. 6 to a retracted or fully contracted position shown in FIG. 7 is shown. In the particular conveyor belt embodiment described above, the inner links 102 are spaced approximately 12.5 mm apart when fully collapsed and approximately 19 mm apart when fully extended. The collapsibility of the inner links 102 allows the conveyor belt to accommodate the various diameters of the drive pulleys. As they move about the outer drive drum, the inner links 102 can assume an extended position which is just prior to the fully extended position shown in FIG. 3 position shown. When similarly moving about the inner drive drum, the inner members 102 may assume a collapsed position that may be close to the fully collapsed position.

In the illustrated conveyor belt embodiment, the collapsibility of the inner links 102 during fabrication is achieved by bending them laterally inward with respect to the conveyor belt or (against the outer links) relative to the crossbars 100, so that adjacent inner links 102 on top of one another and can slide relative to one another without a collision or blockage occurring between the link ends 110 and the adjacent bent sections 112 li. This is shown in FIG. 4 and '! 4 in which the inner members 102 are in a collapsed condition as opposed to theirs in FIG. 6 extended or stretched position.

In addition, the inward flexure of the inner members 102 also results in a variety of im substantial right-angled recesses 114 between successive inner links 102 leads which are used to drive elbows 66 and 67 on the drive drums to move the Take up the conveyor belt. From Figs. 3 and 4 goes from the fact that the corners of the angle drive pieces 66, 67 engage frictionally in the recesses 514 in such a way that that when the drive drums rotate, the drive elbows 66, 67 the inner edge of the Push the conveyor belt forward without slipping.

In addition, the drive angle pieces 66, 67 act on the inner ends of the crossbars 100 the recesses 114 exerted force that the crossbars 100 in the direction of movement of the conveyor belt about their inner ends at the bent sections 116 to pivot forward, which has the consequence. that the outer members 104 of the crossbars 100 move forward. The result of this is that the the outer edge of the conveyor belt is under tension, d. that is, its outer limbs 104 during the are fully extended or fully extended throughout the operation of the conveyor. This is to do the Keeping the conveyor belt in the correct flat, level or horizontal position, without slack, to facilitate an effective drive of the conveyor belt.

For this purpose 2 sheets of drawings

Claims (1)

Claim: Endless conveyor belt for helical conveyor tracks, consisting of a large number of cross bars attached by at their ends hook-shaped members are articulated together, the hook-shaped members in such a way are designed so that they can be pushed together relative to one another without separation from one another and can be brought into engagement with a drive device, characterized in that that the relative movement between the links (102) which are on the helical conveyor track (12, 14) are inside, is less than that of the links (104) on the helical conveyor track (12, 14) are on the outside, and that the links (102) lying on the inside of the helical conveyor track (12, 14) are in engagement with the drive device.