NL9201475A - Conveyor belt assembly. - Google Patents

Abstract

Conveyor belt unit having an endless conveyor belt which is guided over two supports and interacts with a drive device (2) situated upstream, and with an apparatus (20, 24), which is situated downstream, for exerting a braking moment on the incoming strand of the belt, so that a tensile stress occurs there between the braking apparatus and the drive device, and the belt length is such that the outgoing strand (2b) of the belt is unstressed, belt guide means (28) being arranged from the braking device onwards. <IMAGE>

Description

Short designation: Conveyor belt assembly

The invention relates to a conveyor belt assembly having an endless conveyor belt guided over a first and a second supports extending transversely of the conveying direction and cooperating with an upstream driving device.

Such conveyor belt assemblies are known per se in the most diverse varieties and embodiments, the supports usually being formed by a cylindrical drive roller and a cylindrical reversing roller cooperating with a belt tensioning device.

All known devices have the drawback that the conveyor belt only continues to run cleanly in the track when all the following requirements are met in combination: - Both the rollers and the conveyor belt are purely cylindrical and the rollers are purely parallel.

- The friction coefficient between belt and rolling surface is exactly the same everywhere.

- No transverse forces are exerted on the conveyor belt, and - No asymmetrical forces are exerted perpendicular to the conveyor belt.

It will be clear that in practice this combination of conditions is never met, so that in practice steering devices are always necessary to adjust the tire. These steering devices are a significant complication of the conveyor belt assembly.

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The object of the invention is to overcome this drawback and to provide a conveyor belt assembly in which the belt continues to run purely in the track with very simple belt guide means.

This object is achieved according to the invention by a downstream device for applying a braking torque to the first part of the tire, such that in this part between the brake device and the driving device a tensile stress occurs, and the tire length is selected such that the second part of the tire extends located between the drive device and the brake device is tension-free in combination with tape guide means arranged upstream of the device for applying the braking torque.

Surprisingly, it has been found that with these, very simple means, an exact tracking of the belt is realized.

In a preferred embodiment, the belt is guided over the outer circumference of a first downstream guide roller and the outer circumference of a second upstream guide roller, each of these guide rollers co-operating under pressure with a downstream first pressure roller and a second upstream pressure roller, respectively, and the belt is guided between the respective guide rollers and pressure rollers.

At the upstream end, the tape may be guided over a movable support with the upstream guide roller and the associated pressure roller co-located in the space between this support and the downstream guide roller.

Such an arrangement becomes possible because the tension-free part of the tire can be of considerable length allowing an "expanding movement" of the upstream support. This offers interesting possibilities for intermittently transferring objects on the belt to a second remote conveyor or a fixed support.

Embodiments of the device for applying the braking torque are described in claims 4 to 6, while an embodiment of the positioning means is described in claim 7.

Usually the first band part will be above the second, tension-free band part. However, the reverse situation is also possible, i.e. a situation in which the second tension-free belt part lies above the first belt part and is thereby supported, for example, by supporting rollers. This makes it possible to transport objects from a lower level to a higher level via this belt part or to transport objects through a treatment device.

The invention is elucidated on the basis of the drawing, which is:

Figure 1 shows a side view of a conveyor belt assembly according to the invention, by means of which the principle of the invention is explained.

Figure 2 is a top view of this embodiment.

Figure 3 shows an example of an embodiment for slipping braking of the non-driven guide roller.

Figures 4 and 5 show respectively a top view and a side view of a second embodiment of a device for slipping braking of the non-driven tape guide roller.

Figures 6a and 6b show embodiments in which the upstream support is movable in the belt moving direction 16.

Figure 7 shows an embodiment in which the tension-free second belt part lies above the first belt part and is supported by supporting rollers.

Figure 8 shows an embodiment in which the second, tension-free belt part is also above the first belt part and is used to transport objects through a treatment device.

In Figures 1 and 2, reference numeral 2 designates a conveyor belt with the tensioned upper belt section 2a and the slack lower belt section 2b; this belt is driven in the direction of the arrow 4. This drive is effected by means of the drive roller 6 with the shaft 8 on which is mounted a drive sprocket 10 which cooperates with a further drive (not shown) in combination with; a pressure roller 12 with shaft 14 is kept pressed against the driving roller 6 by means of springs 16. The whole is contained in a schematically drawn frame 18.

The figure shows an embodiment in which the roller 12 is driven from the driving roller 6 via the gear system 13; however, the roller 12 can also be designed to be free-rotating.

Downstream, there is a second, non-driven, guide roller 20 which is free to rotate about the shaft 22 and which interacts with the second pinch roller 24 which is held against the roller 20 by the springs 26. The belt 2 is guided between the rollers 6 and 12 on the one hand and the rollers 20 and 24 on the other.

Shortly before the second pressure roller 24, in the direction of movement of the belt, two guide wheels 28 are arranged on either side of the belt.

In order to ensure that the upper belt part 2a is always taut, i.e. under tension, the guide roller 20 has to be braked by slipping, which is realized by a braking device 30, coupled schematically in Figure 2, coupled to the shaft 22 of this roller.

Surprisingly, it has been found that with the above-described simple measures, in which it is essential that no tension occurs in the lower band part 2b, without additional measures a perfect guidance of the upper band part 2a is obtained. Very simple guiding devices for this lower band part 2b, such as those shown in Figures 1 and 2 indicated pins 28 which ensure that the belt part 2a arrives in the correct position at the second pressure roller 24 have proved to be sufficient.

Figure 3 on the one hand and Figures 4 and 5 on the other show simple mechanisms for skid-braking of the roller 20. According to Figure 3, the shaft 22 of the roller 20, which rotates in the direction of the arrow 32, is connected to a crank 34 which 36 is hingedly connected to the piston rod 38, the other end of which carries a piston 40 which is received in the cylinder 42 of an air damper hingedly mounted at 44, with an adjustable throttle opening 46 and 48, respectively, on its two cylinder ends. Its setting determines the braking effect. such braking device can be arranged at each end of the shaft 22, the respective cranks of which are arranged at 90 ° C relative to each other.

Figures 4 and 5 schematically show an embodiment in which the belt 2 'is guided on the one hand on a driven roller 6' and on the other side axis a geieiaeroj. zu; The pressure roller co-operating therewith are not shown in this figure. The driven roller 6 'with the diameter D1 (equal to the diameter D2 of the roller 20') is extended by a portion 6'1 with the diameter D1 'smaller than D1. An endless coupling belt 50 is guided over this part D1 'and the end of the roller 20', which - as shown in figure 5 - is kept under pretension by a tensioning device acting in the direction of the arrow 52, consisting of a pressure roller 54 carried by an the point 56 pivotable tilt lever 58, in combination with a compression spring 60 and an adjusting screw 62, incorporated in the schematically indicated frame 64. Since the diameter D1 'of the part 6' 'is smaller than the diameter D2 of the roller 20', this part has the tends to drive the roller 20 'at a slower speed than that which would correspond to the speed at which the belt 2' drives this roller so that a slip-inhibiting action occurs which results in tension of the upper part 2a 'of the belt 2'.

As will be clear from the foregoing, the lower, slack-hanging and non-tensioned part 2b or 2b 'of the conveyor belt can hang freely over a great distance. This offers interesting applications, the first of which will be described with reference to Figures 6a and 6b.

Figure 6a shows how the upper portion 70a of a conveyor belt indicated in its entirety by the reference numeral 70 is supported by a flat support plate 74 which is movable to and fro in the direction of the arrows 72 under the influence of a non-detailed drive mechanism 76 from the figure 6a. drawn position to the position drawn in figure 6b, and vice versa. The driving roller is indicated by 78, the co-acting pressure roller by 80; the braked guide roller is indicated by the reference numeral 82 and the pressure roller co-operating therewith by 84. The side guide of the belt is schematically shown and indicated by 86. The tension-free belt part is indicated by 70b.

Such an embodiment can be used when an object 83 present at the end of the conveyor 70 is to be placed at a distance corresponding to the expansion length of the drive mechanism 76 on another support, for example a conveyor belt 85 moving transversely to the conveyor belt 70.

Another interesting application possibility is shown in figure 7. Here, the non-tensioned part 90b is not located at the bottom of the assembly, but at the top and rests on a number of support rollers 92a..92f; the direction of movement of the belt is indicated by arrow 94. The belt driving roller is indicated by 96; this roller interacts with the pressure roller 98 and after passing this roller, the tension-free part 90b enters the ascending path via the guide roller 100, and passes the side guides 102 and the braked roller 104 with the co-operating pressure roller 106, the portion between the braked roller 104 and the driving roller 96 - that is to say the undervoltage standing part - is still guided over the guide roller 108.

Such an embodiment can be used to elevate supplied objects to a higher level, as long as, for example, the schematically indicated object 110 which is supplied on a conveyor belt 112 and which is conveyed to the conveyor belt 116 located on a higher level.

A final example of the versatile application possibilities of the assembly according to the invention is shown in figure 8. Here too, the tensioned part 110a of the conveyor belt 110 is located at the bottom of the assembly, while the tension-free part 110b is guided over the guide rollers 112. 114 and a number of smaller guide rollers 116a-116e and 118a-118e respectively hang down in a holder 120 containing a treatment liquid 122. Thus, objects 128 supplied in the direction of the arrow 124 via the conveyor belt 126 can be passed through this bath in order to have a certain treatment there to undergo. In this figure, the driven roller is indicated by 130 and the co-operating pressure roller by 132; the tension-free belt part moving in the direction of the arrow 134 is guided over the guide roller 136 and at the other end of the device passes the braked roller 140 with the co-acting pressure roller 142 via the guide roller 138. The subsequent tensioned belt part 110a is then guided over the guide rollers 144 and 146. Here, side guides 148 are schematically shown at a short distance in front of the braked roller 140.

The objects treated in the bath 120 are discharged onto the discharge hand 150 after passing the bath.

It will be clear from the foregoing that the, per se constructively simple measures according to the invention not only result in perfect guiding of the belt, but that the presence of the sagging, tension-free belt section offers interesting application possibilities.

Only a few exemplary embodiments of the skidding braking device have been described, but the skilled person will be able to devise suitable alternatives without problems within the scope of the invention.

Claims (10)

1. Conveyor belt assembly with an endless conveyor belt guided transversely to the conveying direction, extending over a first and a second supports extending transversely of the conveying direction, cooperating with an upstream driving device, characterized by a downstream device for applying a braking torque to the first part of the belt, such that in this part a tensile stress occurs between the braking device and the driving device, and the band length is selected such that the second part of the tire, which is located between the driving device and the braking device, is tension-free and tape guide means arranged upstream of the device for applying the braking torque. 2. Device according to claim 1, characterized in that the tape is guided over the outer circumference of a first downstream guide roller and the outer circumference of a second upstream guide roller, each of these guide rollers cooperating under pressure with a downstream first pressure roller and a second upstream pressure roller, respectively, and the belt is guided between the respective guide rollers and pressure rollers. Device according to claim 1 or 2, characterized in that the band at the upstream end is guided over a movable support and the upstream guide roller with the pressure roller co-acting therewith are located in the space between this support and the downstream guide roller. 4. Device as claimed in claims 1-3, characterized in that the device for applying a braking torque to the downstream conveyor belt section is formed by the combination of a first driving wheel coupled to the downstream guide roller or the pressure roller co-acting therewith and a first driving wheel with the upstream a guide roller or the second driving wheel coupled to it with a pressure roller, the diameter of which is smaller than that of the first driving wheel, and both driving wheels are coupled to each other by a pre-tensioned driving belt. Device according to claim 4, characterized in that the pre-tension of the drive belt is adjustable. 6. Device as claimed in claims 1-4, characterized in that the downstream guide roller or the co-acting pressure roller is coupled to two crank pins displaced by 90 ° C, each coupled to the piston rod of a pneumatic damping cylinder. Device as claimed in claims 1-6, characterized in that depositing means consist of guide members arranged in the movement direction belt upstream of the downstream guide roller on either side of the belt. 8. Device as claimed in claims 1-7, characterized in that the first band part lies above the second band part. Device as claimed in claims 1-7, characterized in that the second band part lies above the first band part. Device according to claim 9, characterized in that the second belt part is supported by supporting rolls.