DE102020132869A1 - Arrangement comprising a traction means and a guide - Google Patents

Abstract

Arrangement (1) comprising a traction means (2) and a guide (3), the guide (3) having at least one guide element (4), the guide element (4) having a magnetic principle of action.

Description

The invention relates to an arrangement comprising a traction mechanism and a guide, the guide having at least one guide element.

Traction drives are widely used in mechanical engineering and are used to transmit movement and/or power between two or more gear links that are spaced apart from one another. Frequently used traction devices are chains or ropes. The traction means can be deflected circumferentially, for example via gears or pulleys. In the case of very large arrangements in particular, there is the problem that the traction means have a high intrinsic weight on the one hand and that, on the other hand, larger distances usually have to be bridged. This in turn gives rise to the problem that the traction means can hang down between the two gear members to be connected. The problem here is that hanging traction means have an increased space requirement.

There is also the risk that the traction mechanism will vibrate when it starts and when it stops, which is associated with large mechanical loads. In order to prevent this, it is known from the prior art to provide a guide which prevents the traction means from hanging down. In this case, however, the guide is in contact with the traction means and the guide is designed as a wearing part and must be replaced regularly.

The object of the invention is to provide an arrangement with a traction mechanism and a guide that requires less maintenance.

This object is solved with the features of claim 1. The dependent claims refer to advantageous configurations.

The arrangement according to the invention comprises a traction mechanism and a guide, the guide having at least one guide element, the guide element having a magnetic principle of action. The traction means can be designed to transmit a torque and the traction means can be used for transport purposes. Due to the fact that the guide element has a magnetic principle of action, a force can be exerted on the traction means without contact, so that the traction means can be guided without contact. This eliminates the need for guide elements that rub against the traction means and therefore form wearing parts. Contactless guidance results from the contactless guidance due to the magnetic interaction between the guide element and the traction mechanism.

However, a further guide element can also be provided, on which the traction means is guided in abutting manner. In this case, the guide element can be equipped in particular with a receptacle which at least partially accommodates the traction mechanism. The receptacle can be in the form of a groove, for example. This configuration results in a particularly precise guidance of the traction mechanism. In this case, the further guide elements can be assigned guide elements with a magnetic principle of action. For this purpose, the magnetic guide elements can be arranged on the further guide elements or integrated into the further guide elements.

According to a first embodiment, the magnetic guide elements are designed in such a way that the traction mechanism is drawn towards the further guide element. This configuration results in a particularly precise and safe guidance of the traction mechanism. According to a second embodiment, the magnetic guide means are designed in such a way that the traction means is repelled at the further guide element. For this purpose, the traction means can be equipped with magnetic elements which, together with the magnetic guide elements, bring about the magnetic repulsion. In this embodiment, the traction means only bears against the further guide element with little pressure or is slightly spaced apart from the further guide element. With this configuration, mechanical wear of the guide element can be avoided.

This refinement is advantageous in particular in connection with traction means which are used in the mechanical engineering of large systems. Traction means of large systems often bridge distances of several meters and have a high dead weight. As a result, the traction means exert a high mechanical load on deflection rollers and the like. In order to reduce the load, it is known from the prior art to support the traction means with rollers or chain guides. However, the problem here is that this requires additional elements which are in contact with the traction means and which are subject to wear.

A further problem arises with traction means, to which elements are attached and which are transported by the traction means. The elements can be, for example, transport containers, tools or the like. The elements are firmly attached to the traction mechanism and rotate with the traction mechanism. The problem arises that the elements can come into contact with the supporting rollers or the chain guide when the traction mechanism is rotating, which in turn can be associated with insufficient support. Due to the design according to the invention, a very heavy traction means bridging a long distance can also be supported, in that the traction means interacts with the magnetic guide element. The guide element can be arranged between the two circulating chain strands and in particular pull the lower chain strand. As a result, a traction device can also be supported, to which elements with transport containers or tools are fastened on the outside.

The guide element is preferably designed as a magnet. According to a first embodiment, the guide element can be designed as a permanent magnet. Permanent magnets do not require any auxiliary energy, so that the arrangement is particularly simple. Permanent magnets based on neodymium are particularly preferred.

Alternatively, it is conceivable to design the guide element as an electromagnet. In the case of electromagnets, it is advantageous that the magnetic interaction can be adjusted, so that the magnetic attraction force required for guiding the traction mechanism can be adjusted over a wide range as required.

The guide element can be designed as an eddy current generator. Eddy current generators are particularly advantageous for traction means that are electrically conductive but not magnetic. The eddy current generator induces an inhomogeneous magnetic field, which acts on the traction mechanism. The effect of the changing magnetic field in turn induces a current in the traction mechanism, which in turn is accompanied by the induction of a further magnetic field. This makes it possible for the guide element to generate a magnetic interaction with the traction mechanism, which is electrically conductive but not magnetic.

The traction means can be guided over deflection rollers, with guide elements being arranged between two deflection rollers. The guide elements act on the traction mechanism via the magnetic principle of action and prevent the traction mechanism from sagging too much, for example.

It is also conceivable to equip the deflection rollers with magnetic guide elements. In this embodiment, the traction mechanism is captively guided on the deflection rollers.

According to a first embodiment, the traction means is designed as a chain. The chain can be designed as a link chain or as a roller chain. In an alternative embodiment, the traction means is designed as a cable.

In connection with the design of the traction means as a rope, it is conceivable that the arrangement is part of a means of transport, for example a passenger elevator, a freight elevator, a cable car or the like. With the arrangement according to the invention, undesired cable vibrations can be avoided.

If the traction mechanism is designed as a roller chain, it can be advantageous to provide additional guide elements on or in which the rollers of the chain can roll. For example, the further guide elements can have a groove running in the longitudinal direction, the groove partially accommodating the chain. The rollers of the chain can rest against the bottom of the groove and roll off there. Depending on the assembly situation, it can happen that the chain is mounted tilted so that the axis of rotation of the rollers is aligned vertically. In the case of large chains, the weight of the chain is very high and large distances of several meters often have to be bridged. This can lead to a very high mechanical load on the chain. If the tension of the chain is not sufficient, the chain can also tilt and twist. The chain can be held in a desired position by the magnetic guide element according to the invention. Depending on the configuration of the chain and the assembly situation, it is conceivable that the chain is integrated into the further guide element and pulls the chain into or onto the further guide element. However, it is also conceivable for the chain to be arranged between the guide element and the further guide element, with the guide element pressing the chain against the further guide element. This configuration is advantageous for chains whose roller axis is aligned vertically and also for chains with a horizontally aligned roller axis.

The traction means is preferably made of magnetizable material. In this case, the traction means is either pulled out or pushed off by the guide elements with the magnetic principle of action, depending on the orientation. As a result, the traction means can be brought into a predetermined position without contact.

• 1 eine Anordnung;
• 2 eine Anordnung mit weiterem Führungselement und Zugmittel in Form einer Kette;
• 3 eine Anordnung mit weiterem Führungselement und Zugmittel in Form eines Seiles;
• 4 eine Anordnung mit einem Zugmittel in Form einer Rollenkette;
• 5 eine Anordnung mit einem Zugmittel in Form einer Rollenkette und einem weiterem Führungselement;
• 6 Anordnungen mit einem Zugmittel in Form einer Rollenkette für den Transport von an der Rollenkette befestigten Elementen;
• 7 eine Anordnung mit rollenförmigem weiteren Führungselement.

Some configurations of the arrangement according to the invention are explained in more detail below with reference to the figures. These show, each schematically:

• 1 an arrangement;
• 2 an arrangement with a further guide element and traction means in the form of a chain;
• 3 an arrangement with a further guide element and traction means in the form of a rope;
• 4 an arrangement with a traction means in the form of a roller chain;
• 5 an arrangement with a traction means in the form of a roller chain and a further guide element;
• 6 Arrangements with a traction means in the form of a roller chain for the transport of elements attached to the roller chain;
• 7 an arrangement with a roller-shaped further guide element.

The figures show an arrangement 1 with a traction device 2 and a guide 3. The traction device 2 can be a rope or a chain. The arrangement 1 is part of a device, in which case a torque can be transmitted by the traction mechanism 2 . Alternatively or additionally, the traction means 2 can also transport machine elements or products. For this purpose, the traction means 2 can be moved either in a circular fashion or back and forth. The guide 3 has at least one guide element 4 .

1 shows an arrangement 1 in which the traction means 2 is guided over two deflection rollers 5 . The traction means 2 is made of metallic and magnetizable material. In the present embodiment, three guide elements 4 are arranged between the two deflection rollers 5 .

The guide elements 4 have a magnetic principle of action. For this purpose, the guide elements 4 are designed as magnets in the form of permanent magnets based on neodymium. The magnets are designed and arranged in such a way that the traction mechanism 2 is drawn towards the guide elements 4 . Here, however, the traction means 2 does not come to rest on the guide elements 4 . The traction mechanism 2 is guided without contact.

According to an alternative embodiment, the traction means 2 is made of plastic. In this configuration, the guide element 4 is designed to bring about an electrostatic charge on the surface of the traction mechanism 2 , so that the traction mechanism 2 enters into a magnetic interaction with the guide element 4 .

According to a further alternative embodiment, the traction means 2 is made of a metallic and non-magnetizable material. In this configuration, the guide element 4 is designed as an eddy current generator, so that the guide element 4 induces a current within the traction mechanism 2, which in turn creates a magnetic field that interacts with the magnetic field induced by the eddy current generator.

2 shows an arrangement 1 in which the traction means 2 is designed as a chain. The guide 3 comprises a further guide element 6 with a recess 7 running in the longitudinal direction. The recess 7 partially accommodates the traction mechanism 2 . Guide elements 4 with a magnetic operating principle are integrated into the further guide element 6 .

In the present embodiment, the guide elements 4 are designed as electromagnets. The guide elements 4 are designed and arranged in such a way that the guide elements 4 arranged above the recess 7 pull the traction means 2 into the recess 7 . In contrast, the guide elements 4 arranged to the side of the recess repel the traction means 2 . As a result, the traction mechanism is guided securely in the recess 7 . However, it only comes into contact with the wall of the recess 7 with very little pretension.

3 shows the configuration according to 2 , wherein the traction means 2 is designed as a cable in the present embodiment.

4 shows an arrangement 1 in which the traction means 2 is designed as a roller chain. Guide elements 4 with a magnetic principle of action are integrated into the guide 3 . In the present embodiment, the guide elements 4 are designed as permanent magnets based on neodymium. The guide elements 4 are designed and arranged in such a way that the guide elements 4 arranged above the traction means 2 in the guide 3 pull the traction means 2 in the direction of the guide 3 . In this case, however, the traction mechanism 2 does not come into contact with the guide 3, so that the traction mechanism 2 is guided without contact.

5 shows an arrangement 1 in which the traction means 2 is designed as a roller chain. Guide elements 4 with a magnetic principle of action are integrated into the guide 3 . In the present embodiment, the guide elements 4 are designed as permanent magnets based on neodymium. The guide elements 4 are designed and arranged in such a way that the guide elements 4 arranged above the traction means 2 in the guide 3 pull the traction means 2 in the direction of the guide 3 . A groove is made in the guide 3, into which the traction means 2 is partially drawn due to the magnetic interaction. A further guide element 6 in the form of a chain roller support is arranged on the side of the traction mechanism 2 facing away from the guide 3 . The other guide element 6 is used for additional support of the traction mechanism 2.

6 shows a traction device 2 in the form of a roller chain in the upper area. The roller chain comprises chain links which are movably connected to one another by means of a roller. Receiving areas in the form of straps are formed from the chain links, to which elements can be fastened. According to an advantageous embodiment, tools that are transported by means of the roller chain are fastened to the receiving areas.

The illustration in the middle area shows an arrangement 1 in which the guide 3 has magnetic guide elements 4 in the form of permanent magnets and a further guide element 6 . The rollers of the traction means 2 are pressed against the further guide element 6 by means of the magnetic guide elements 4, so that the rollers bear against the further guide element 6 and roll there. In this configuration, it is alternatively or additionally conceivable for guide elements 4 to be arranged underneath the traction means 2, ie on the side of the traction means 2 facing away from the further guide element 6. The axis of the rollers runs in the horizontal direction.

The representation in the lower area shows an arrangement 1, which essentially corresponds to the arrangement 1 in the middle representation. In this configuration, the axis of the rollers runs in the vertical direction. The guide 3 includes magnetic guide elements 4, which are arranged to the side of the traction device 2 (above and below the traction device 2 in the illustration). These guide elements 4 are designed in such a way that they pull the tabs of the traction means 2 . A magnetic guide element 4 is integrated into the further guide element 6 and pulls the traction mechanism 2 towards the further guide element 6 . According to an advantageous embodiment, the guide elements 4 integrated into the further guide element 6 are omitted, so that only the guide elements 4 associated with the tabs act on the traction mechanism 2 . Furthermore, it is alternatively or additionally conceivable that guide elements 4 are arranged on the side of the traction mechanism 2 facing away from the further guide element 6 .

The guide elements 4 are each embedded in the guide 3 and do not come into direct contact with the traction means 2. A wear layer and/or a damping layer is preferably arranged between the guide element 4 and the traction means 2. The wearing layer absorbs mechanical and thermal loads and prevents the guide elements 4 from being damaged by the traction mechanism 2 . The damping layer prevents vibrations or impacts from being transmitted directly from the traction mechanism 2 to the guide element 4 . The wearing layer and the damping layer can be made of a metallic material or a rubber material. In addition, it is conceivable that the guide elements 4 are embedded in a vibration-damping layer. For example, the guide elements 4 can be embedded in an elastomer body.

7 shows an arrangement 1 in which the guide 3 comprises a further guide element 6 in the form of a roller. The further guide element 6 comprises a recess 7 running over the circumference, the recess 7 partially accommodating the traction means 2 . Guide elements 4 with a magnetic operating principle are integrated into the further guide element 6 . The guide elements 4 are designed as permanent magnets based on neodymium. The guide elements 4 are designed and arranged in such a way that they pull the traction means 2 into the recess 7 in sections. The further guide element 6 rotates in accordance with the movement of the traction mechanism 2.

Claims (12)

Arrangement (1) comprising a traction means (2) and a guide (3), the guide (3) having at least one guide element (4), characterized in that the guide element (4) has a magnetic principle of action. arrangement according to claim 1 , characterized in that the traction means (2) is guided by the guide elements (4) without contact. arrangement according to claim 1 or 2 , characterized in that the guide element (4) is designed as a magnet. Arrangement according to one of Claims 1 until 3 , characterized in that at least one further guide element (6) is provided. arrangement according to claim 3 or 4 , characterized in that the guide element (4) is designed as a permanent magnet. arrangement according to claim 3 or 4 , characterized in that the guide element (4) is designed as an electromagnet. Arrangement according to one of Claims 1 until 3 , characterized in that the guide element (4) is designed as an eddy current generator. Arrangement according to one of Claims 1 until 7 , characterized in that the traction means (2) is guided over deflection rollers (5), guide elements (4) being arranged between two deflection rollers (5). Arrangement according to one of Claims 1 until 8th , characterized in that the traction means (2) is made of magnetizable material. Arrangement according to one of Claims 1 until 8th , characterized in that the traction means (2) is designed as a chain or as a cable. Arrangement according to one of Claims 1 until 8th , characterized in that the traction means (2) is designed as a roller chain. arrangement according to claim 11 , characterized in that elements are fastened to the members of the traction means (2).

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