NL9300313A - Device for orienting objects, such as bottles, which are fed onto a conveyor belt in an upright position - Google Patents

Abstract

The invention relates to a device for orienting objects - such as bottles - which are fed onto a conveyor belt in an upright position and the cross-sectional dimensions of which differ in two axial directions which are perpendicular to one another. The device comprises an auxiliary drive member, which moves past one side of the conveyor belt along a path running substantially in the conveying direction, and an opposite guide wall, which extends along the other side of the conveyor and is flexible in the transverse direction. The auxiliary drive member can be moved at a higher speed in the conveying direction, and at the upstream end of its movement path is at a distance from the flexible guide wall, in such a manner that an object which is held at that end between the drive member and the guide wall and the largest cross- sectional axis of which forms an angle with the conveying direction, is gripped by both the drive member and the guide wall and, in the process, is subjected to an orienting moment by the auxiliary drive member which causes the bottle to rotate about its axis. <IMAGE>

Description

Short designation: Device for lifting objects, such as bottles, supplied in a standing position on a conveyor belt.

The invention relates to an apparatus for directing objects supplied in a standing position to a conveyor belt, such as bottles, whose cross-sectional dimensions are different in two mutually perpendicular axis directions.

When transporting a series of successive objects, such as bottles or other containers, in a standing position, these objects are generally objects with a round cross-sectional shape, danwal with a cross-sectional shape, the dimensions of which are equal in two mutually perpendicular directions. Advance on a conveyor, such as a bottle conveyor, usually takes place between two opposite fixed guide rails flanking the conveyor, which are arranged at a relatively large distance from each other. Such objects provided with a regular cross-sectional shape automatically assume the desired angular position on the conveyor, for example for carrying out a filling operation or for applying labels.

The invention, on the other hand, involves the transport of objects, such as bottles, whose cross-sectional dimensions are different in two mutually perpendicular axis directions. Such objects can occupy many angular positions on the conveyor, i.e. positions, in which they have their largest cross-sectional size c.e. -include an angle with the transpart device varying between 0 and 90 °.

The object of the invention is now to orient objects of such a cross-sectional shape, i.e. to rotate them about their axis during propulsion, so that they have with their largest cross-sectional dimension c.g. -axis will be oriented in the transport direction, without this being accompanied by a significant change in the pitch distance with which the objects are being docked.

The device described in the preamble is to that end characterized by an auxiliary drive member moving along one side of the conveyor belt along a path extending substantially in the conveying direction, and a transverse yielding direction extending opposite it, along the other side of the conveyor belt. wherein the auxiliary drive member is movable in the direction of transport at such a higher speed and has such a distance at the upstream end of its moving path from the yielding guide wall that an object traps at that end the drive member and the guide wall, the largest of which cross-sectional axis or cross-sectional dimension makes an angle with the conveying direction, is gripped by both the driving member and the guide wall and thereby subjected to a rotation by the auxiliary driving member, which causes the bottle to rotate its axis.

Due to the laterally yielding nature of the guide wall, the assembly of auxiliary drive member and yielding guide wall adapts to the width (measured transversely to the direction of transport), with which an object presents itself at the current end of the device. Thereby, the adjusting action of the auxiliary driving member will end as soon as the adjusted object has lost contact with the yielding guide wall. Generally, this moment will be reached when the object in question with its largest transverse cross-sectional dimension is in the conveying direction.

Further features and advantages of the device according to the invention are explained in more detail below with reference to the drawing with an exemplary embodiment.

The invention is explained in more detail below with reference to the drawing with an exemplary embodiment.

Fig. 1 is a schematic top view of the device according to the invention; Fig. 2 shows a schematic cross section on a larger scale according to plane II-II in Fig. 1 and Fig. 3 shows a schematic cross section on a larger scale according to plane III-HI in Fig. 1.

The exemplary embodiment shown in the drawing relates to a device for aligning so-called "shoulder bottles". Such a schuder bottle is indicated by 1 in the drawing. The body of this bottle, viewed in a given cross-sectional direction, has two opposite, substantially vertical bottle side walls 1a, which are upright from the bottle bottom. The external distance between the opposite bottle side walls 1a is indicated by x. In a cross-sectional direction perpendicular thereto, the bottle body has two opposite bottle side walls 1b. The distance y between the latter walls is greater than the distance x and moreover increases slightly, counting from the bottom of the bottle towards the neck of the bottle, so that the bottle has a slightly tapered profile with a slightly wider transition between bottle body and bottle neck. Between the ringed pairs of opposite bottle side walls 1a and 1b are the transition wall parts indicated with 1c.

The bottles 1 to be oriented are advanced in a upright position - with a pitch distance of, for example, one and a half to twice the bottle height - in the direction of arrow I (fig. 1) at a speed VI on a conveyor of a type known per se. The uppermost active part of this bottle conveyor, which is not shown in more detail in Fig. 1, is schematically indicated by 2 in Figs.

Viewed in the horizontal plane, the bottles 1 can be at different angular positions on the bottle conveyor 2, i.e. the short or long cross-sectional axes x and y can be at different angles to the transport direction I. It is now the intention that all bottles with their long cross-sectional axis Y are oriented in the direction of conveyance I. The device according to the invention arranged for this purpose in the path of the bottle conveyor consists of an endless drive belt 3 disposed on one side of this path, which is guided over belt pulleys 4a and 4b, the belt pulley 4a of which, via a belt transmission 4c, a drive motor (not shown in more detail) is driven, such that the active drive part 3a of the drive belt 3 moves in the transporting direction I at a speed V2 which is greater than VI. As shown in Figs. 2 and 3, the drive belt 3 is located approximately half way up the height of the bottle body. The active drive part 3a is supported in the transverse direction by a support guide element 5 extending between the two belt pulleys 4a, 4b. Opposite the drive belt 3 there is a transversely yielding guide wall 6, which extends along the opposite side of the conveyor. .

In the illustrated exemplary embodiment, the yielding guide wall 6 is formed by the part 6a lying facing the drive belt 3 of a belt of rubber or the like material guided by two stationary pins 7a and 7b. The guiding pin 7a is situated a little distance upstream from the axis of the pulley 4a, while the guiding pin 7b is located a little downstream from the axis of the pulley 4b.

On each side of the path of the bottle conveyor there is furthermore a guide rail 8 and 9 respectively. The guide rails 8 and 9 occupy a position converging with respect to each other in the conveying direction I. In addition, the distance between these guide rails at the current downward end (right in fig. 1) is slightly greater than the largest cross-sectional dimension (y) of the bottle to be aimed, while the distance at the downstream end (left in fig. 1) is slightly larger than the smallest cross-sectional dimension (x) of the bottle to be targeted.

The active string sections 3a and 6a, on the other hand, run substantially parallel to each other or, viewed in the direction of transport I, assume a slightly divergent position relative to each other, the distance between the active string sections 3a and 4a at the upstream end of the device is slightly greater than the smallest cross-sectional dimension (x) of the bottle body.

The operation of the above-described straightening device is as follows.

In the right-hand side of Fig. 1, a bottle 1 is shown at a moment when it is "caught" between the downstream end of the active part 3a of the drive belt 3 and the bottle with the largest cross-sectional dimension (y) transverse to the traiporting direction I. active part 6a of the belt 6. The distance between the active belt parts 3a and 6a is actually too small to allow the bottle to pass in this position (with the long cross-sectional axis transverse to the direction of travel I). Therefore, the supplied bottle has pushed the active string part 6a out a little. The bottle is thereby slowed down in its movement by the stationary string part 6b. On the other hand, the bottle on the other side of the string part 3a moving at the higher speed V2 receives an impulse in the direction of travel I, whereby the bottle is exerted for a moment, which causes the bottle to rotate about its axis, so that it has its long cross-sectional axis y is directed in the transport direction I. The impulse received from the string 3 can be so strong that the bottle rotates through its oriented position and must then be directed again. Such a phenomenon can be promoted by low friction between bottle bottom and conveyor and by losing contact with the stationary string section; 6a when the latter is pushed out by a subsequent bottle. This phenomenon is limited by the two mutually converging guide rails 8, 9 in that they take over the guiding function of the strings and the bottle in the correct position and in the correct position relative to the last part of the path through the straightening device. deliver the previous and next bottle to the downstream end of the device (see left fig. 1 and 3). On the latter section of the track, rails 8, 9 keep the bottle out of contact with string parts 3a and 6a.

Claims (7)

Apparatus for aiming articles - such as bottles - supplied in a standing position on a conveyor belt, the cross-section dimensions of which differ in two mutually perpendicular axis directions, characterized by a track running along one side of the conveyor belt in a direction substantially in the conveying direction moving auxiliary drive means, and a guide wall extending transversely along the other side of the conveyor, with the transverse direction yielding, the auxiliary driving element being movable in the direction of conveyance at such a higher speed and such a movement at the upstream end of its path of movement has a distance from the yielding guide wall that an object caught at that end between the drive member and the guide wall, the largest cross-sectional axis of which is at an angle to the conveying direction, is gripped by both the drive member and the guide wall and thereby by the auxiliary drive member to a Direction moment is subjected to cause the bottle to rotate its axis. 2. Device as claimed in claim 1, characterized in that the auxiliary driving element consists of an endless driven belt. Device according to claim 2, characterized in that the active part of the endless drive belt is supported laterally outwards. Device according to claims 1-3, characterized in that the yielding wall consists of an elastic string stretched between two fixed points. 5. Device as claimed in claim 4, characterized in that the elastic string is formed by the part of an endless belt guided around the two auxiliary guide pins facing the auxiliary drive member. 6. Device as claimed in claims 4-5, characterized in that the current upstream fixed point or the downstream guide pin is located some distance upstream of the current upstream end of the attachment path of the auxiliary drive member. A device according to claims 1-6, characterized in that a fixed guide rail is arranged on either side of the conveyor, below the auxiliary drive member or under the yielding guide wall, which guide rails converge in the direction of transport and are positioned such that they prevent contact between the object to be aimed and the auxiliary drive member or the compliant guide wall over the last part of the path through the device.