DE102011114250A1 - Conveyor chain for profile system of conveyor chain system, has multiple contact surface areas which are subjected to rubbing wear, where one of contact surface areas is provided with structural elements - Google Patents

Abstract

The conveyor chain (3) has multiple contact surface areas which are subjected to rubbing wear, where one of the contact surface areas is provided with the structural elements reducing the rear contact surface of the contact surface areas. The structural elements are made from the same material as the respective contact surface areas. The structural elements have projections and rounded contours. The heights of the structural elements amount between 0.05 millimeter and 2 millimeter. An independent claim is included for a conveyor chain system with a contact surface areas with high material hardness of structural elements.

Description

The present invention relates to a conveyor chain having a plurality of contact surface areas which are subject to fretting, a profile system, in particular for a conveyor chain system, with a plurality of contact surface areas which are subject to fretting, and a conveyor chain system with a conveyor chain described above and / or a profile system described above.

Such conveyor chains are exposed to heavy loads, since the conveyor chain is guided in such a conveyor chain systems in the profile system slidably. By deflections and drive elements, the continuous circulation of the conveyor chain takes place. On the conveyor chain is conveyed, which comes to load the sliding contact between the conveyor chain and the profile system to load the friction contacts in the conveyor chain and load the friction between conveyor chain and deflections and to load the friction between the conveyor chain and the drive elements. The sliding contact between conveyor chain and profile system causes the highest resistance to movement and thus the largest share of the energy requirement of the conveyor system. The resistance to movement results in the mechanical load on the conveyor chain and ultimately in the service life of the system components. At all friction contacts in the system wear particles can arise, which interfere in particular in production plants with high demands on the purity. In addition, the wear causes a weakening of the components. As a result of the friction and wear, it comes in particular when using the friction mating plastic against plastic and plastic against metal to a short life of the system components and the emission of wear particles.

It is known to use lubricants such as soapsuds and oils to improve the friction and wear behavior of plastic-plastic friction pairings and of plastic-metal friction pairings. In addition, slip-modified plastics were developed. For this purpose, liquid and solid lubricants are mixed or chemically embedded in the polymer materials. Examples of such additives are silicone oils, polytetrafluoroethylene, graphite or molybdenum disulfide.

The disadvantage of using these slip-modified plastics is that the mechanical properties of the polymer materials are reduced by the additives. In addition, the slide-modified plastics are much more expensive than unmodified plastics.

It is therefore the object of the present invention to provide an improved conveyor chain, an improved profile system and also an improved conveyor chain system, which avoid the above-mentioned disadvantages.

For this purpose, it is provided according to the invention in relation to the conveyor chain that at least one of the contact surface areas is provided with structural elements reducing the real contact area of the contact area areas.

The friction and wear behavior of plastic-metal and plastic-plastic friction mating without lubrication is essentially determined by adhesion mechanisms and deformation mechanisms. The effect of adhesion is particularly important for materials with high surface energy, ie polar materials. The most used for components in mechanical engineering highly polar, semi-crystalline engineering thermoplastics, such as polyoxymethylene or polyamide, are such materials. The adhesion, and thus the resistance to movement and the wear, are all the greater, the larger the real contact surface, ie. H. the area in which contact actually takes place is. The structural elements on the contact surface areas reduce the real contact area. This also reduces the adhesion mechanisms. Friction and wear are reduced. On lubricants and a sliding modification of the plastics can be omitted, so that a cost advantage is achieved.

In a preferred embodiment it can be provided that the structural elements are made of the same material as the respective contact surface areas. The structural elements and the contact surface areas can therefore be made in one piece. This achieves good mechanical properties. In addition, a simple production is possible.

According to yet another embodiment, it can be provided that the structural elements have projections. The structural elements therefore protrude beyond the main plane of the respective contact surface areas. Under main level is to be understood as the level of the contact surface areas in which lie the bases of the structural elements. In this way, the desired reduction of the actual contact area between two components is easily achieved.

According to yet another advantageous embodiment it can be provided that the structural elements have rounded contours. The rounded contours also reduce the deformation mechanisms between two touching components, so that another Improvement of the friction and wear behavior of the conveyor chain is achieved.

It may further be provided that the height of the structural elements is between 0.05 mm and 2 mm. The height of the structural elements is defined as the distance between the main plane of the respective contact surface areas and the highest point of the structural elements. It has been shown that the desired ratios are achieved in the specified range.

It can also be provided that the radii of the rounded structural elements are in a range of 0.01 mm to 2 mm. As a result, the desired reduction of the deformation mechanisms is achieved.

Advantageously, it can be provided that the width of the structural elements is about 0 to 10 mm. The width of the structural elements is defined as the width of the protrusions in the area between the rounded contours. At a width of 0 mm, the structural elements are so completely rounded and have z. B. the shape of spherical or cylindrical cutouts. It has been shown that this achieves the desired effects. Preferably, the width of the structural elements may be in a range of 0.05 mm to 2 mm.

According to yet another embodiment, it can be provided that the structural elements are spaced apart from one another and the distance between the highest points of two adjacent structural elements is 0.04 mm to 10 mm. This also leads to a friction or wear reduction. It may also be sufficient if the distance is not more than 2 mm.

On the basis of the above information regarding the shape and the size of the structural elements, it can be seen that these structural elements are specifically applied structures. For example, these structures may have a regular pattern. Preferred patterns are parallel ridges, intersecting ridges, which preferably enclose a right angle with each other, and spherical ridges. The webs can be longitudinal, transverse or oblique to the direction of movement. But it is quite possible that the desired improvements can be achieved with other patterns. The dimensions of the structural elements are, as clearly evident from the values given above, greater than the surface roughness of the contact surface areas.

An advantageous embodiment may further provide a plurality of chain links, which are connected to each other endlessly by means of bolts and / or pins, wherein the chain links have contact surface areas on their upper side and / or their lower side. If the chain links are provided on their upper side with contact areas with structural elements, the friction between the chain links and the transported material conveyed thereon is reduced. This can be advantageous, in particular in accumulation conveyor chains, where the conveyor chains pass under congestion of the conveyed material under the conveyed material. So far, accumulation conveyor chains are provided for this purpose with rollers. Contact surface areas with structural elements on the underside of the chain links come into contact with the guide or drive parts for the conveyor chain and lead there to a friction and Verschließverringerung.

If contact surface regions cooperating with one another between the various elements of the conveyor chain are formed, of which at least one is provided with structural elements, the friction and the wear within the conveyor chain can also be reduced.

With respect to the profile system, the object of the present invention is achieved in that at least one of the contact surface areas of the profile system, which is subject to fretting, is provided with the real contact surface of the contact surface areas reducing structural elements. By reducing the actual contact surface, adhesion mechanisms, and thus friction and wear, are reduced here as well.

In a preferred embodiment of the profile system can be provided that the structural elements are made of the same material as the respective contact surface areas. The structural elements and the contact surface areas can therefore be made in one piece. This achieves good mechanical properties. In addition, a simple production is possible.

According to yet another embodiment of the profile system can be provided that the structural elements have projections. The structural elements therefore protrude beyond the main plane of the respective contact surface areas. The term "main plane" refers to the plane of the contact surfaces and areas in which the base points of the structural elements lie. In this way, the desired reduction of the actual contact area between two components is easily achieved.

According to yet another advantageous embodiment of the profile system can be provided that the structural elements have rounded contours. The rounded contours also reduce the deformation mechanisms between two contacting components, so that a further improvement of the friction and wear behavior of the conveyor chain system is achieved.

It may further be provided that the height of the structural elements of the profile system is between 0.05 mm and 2 mm. The height of the structural elements is defined as the distance between the main plane of the respective contact surface areas and the highest point of the structural elements. It has been shown that the desired ratios are achieved in the specified range.

It can also be provided that the radii of the rounded structural elements of the profile system are in a range of 0.01 mm to 2 mm. As a result, the desired reduction of the deformation mechanisms is achieved.

Advantageously, it may be provided that the width of the structural elements of the profile system is approximately 0 to 10 mm. The width of the structural elements is defined as the width of the protrusions in the region between the rounded contours. With a width of 0 mm, the structural elements are therefore completely rounded off and have, for example, the shape of spherical or cylindrical cutouts. It has been shown that this achieves the desired effects. Preferably, the width of the structural elements may be in a range of 0.05 mm to 2 mm.

According to yet another embodiment of the profile system can be provided that the structural elements are spaced apart and the distance between the highest points of two adjacent structural elements is 0.04 mm to 10 mm. This also leads to a friction or Verschließreduzierung. It may also be sufficient if the distance is not more than 2 mm. It should also be noted that the comments regarding the structural elements in a conveyor chain also apply to the structural elements of the profile system.

With regard to the conveyor chain system, the object underlying the invention is achieved in that the conveyor chain system comprises a conveyor chain as described above and / or a profile system as described above. Characterized in that at least one of the elements conveyor chain or profile system is provided with structural elements, the desired friction and wear reduction is achieved.

Advantageously, it can be provided that at least one of the contact surface regions of the conveyor chain interacts with an opposite contact surface region of the profile system and at least one of the contact surface regions is provided with structural elements. Between the contact surface areas of the conveyor chain and the contact surface areas of the profile system, the highest resistance to movement of a conveyor chain system is caused. If at least one of these contact surface areas is provided with structural elements according to the invention, a substantial reduction in the wear and the resistance to movement of the conveyor chain system is achieved.

Furthermore, it can be provided that the contact surface regions of the conveyor chain and the opposite contact surface regions of the profile system consist of different materials and only the contact surface regions with higher material hardness are provided with structural elements. It has been found that it is sufficient to improve the friction and wear behavior, if only these contact surface areas are provided with structural elements.

As material for the chain links of the conveyor chain plastic and metal for the profile system can be provided. As a result, a simple production of the chain links is possible and it can be ensured that the components have the necessary strength. It is also possible that the chain links made of metal and the profile system made of plastic. In addition, both the profile system and the chain links may be made of plastic.

A simple and cost-effective production can be made possible in that the structural elements are produced by injection molding of the respective components. The structural elements can be determined by the injection mold. This is particularly advantageous in plastic components. However, it can also be provided that the structural elements are produced by machining.

In the following the invention will be described in more detail with reference to figures. Show it:

1 Conveyor chain system with a profile system and a conveyor chain,

2 View of a chain link of the conveyor chain 1 from underneath,

3 Another embodiment of a conveyor chain system with a profile system and a conveyor chain,

4 View of the conveyor chain 3 from underneath,

5 Conveyor chain off 3 with a drive wheel or a deflection,

6 Conveyor chain off 3 with another diversion,

7 Section through a contact point with two opposite contact surface areas of a conveyor chain system,

8th Top view of another contact surface area with structural elements,

9a Top view of another contact surface area with structural elements,

9b Cross section through one of the structural elements 9a ,

In 1 is a conveyor chain system according to the invention 1 shown. The conveyor chain system 1 includes a profile system 2 on which a conveyor chain 3 is guided. This is indicated by the profile system 2 two rails 4 . 5 on, which are spaced apart. The conveyor chain 3 is made up of individual chain links 6 together, by means of bolts 7 are endlessly connected. These are on the chain links 6 tabs 8th provided, which are inserted into each other and with the bolts 7 be connected to each other. The tabs 8th and the bolts 7 Stand down and walk between the rails 4 . 5 of the profile system 2 , On the tops of the rails 4 . 5 of the profile system 2 are contact surface areas 9 . 10 formed on which the chain links 6 rest. Furthermore, the conveyor chain system 1 at least one drive (not shown), with which the conveyor chain 3 via the profile system 2 is pulled. In addition, deflections (not shown) are provided with which the desired path for the conveyor chain 3 is achieved.

2 shows a chain link 6 out 1 from underneath. At the bottom of the chain link 6 are also contact surface areas 11 . 12 educated. The contact surface areas 11 . 12 of the chain link 6 lie on the contact surface areas 9 . 10 of the profile system. During operation of the conveyor chain system, the conveyor chain 3 by means of the drive via the profile system 2 drawn. On the conveyor chain 3 , ie on the top of the chain links 6 , the conveyed goods are arranged. There is therefore friction between the contact surface areas 9 . 10 of the profile system 2 and the contact surface areas 11 . 12 the chain links 6 , In addition, it can also lead to friction between contact surface areas on the top of the chain links and the conveyed. This is the case in particular with accumulation conveyor chains. As materials for the profile system 2 and the chain links 6 mainly metal and plastic are used. Thus it can be provided that the profile system consists of metal and the chain links made of plastic. It is also possible to manufacture the chain links made of metal and the profile system made of plastic or to use plastic both for the profile system and for the chain links.

In 3 is another embodiment of a conveyor chain system 1' shown. The conveyor chain system 1' is essentially identical to the conveyor chain system already described 1 , In the following, the differences are essentially described. Also this conveyor chain system 1' includes a profile system 2 ' on the one conveyor chain 3 ' is guided. The conveyor chain 3 ' is made up of individual chain links 6 ' together, by means of tension elements 15 . 16 , Bolt 7 ' and pins 18 are endlessly connected. The profile system 2 ' has two rails 4 ' . 5 ' on which the chain links 6 ' glide along. For the formation of contact surface areas 9 ' . 10 ' are on the profile system 2 ' U-shaped reinforcements 13 . 14 arranged. Again, between the undersides of the chain links 6 ' and the contact surface areas 9 ' . 10 ' of the profile system or between the reinforcements 13 . 14 Formed contact points where friction takes place. The profile system 2 ' and the chain links 6 ' may consist of the same materials as described above. In particular, it is possible that on metallic rails 4 . 5 ' U-shaped reinforcements 13 . 14 be attached from plastic.

4 shows a detailed view of the conveyor chain 3 ' out 3 , The conveyor chain 3 ' is shown from below. The conveyor chain 3 ' has tension elements 15 . 16 on, by means of bolts 7 ' and pins 18 connected so that a three-dimensional movement of the conveyor chain 3 ' is possible. The chain links 6 ' are on the tension elements 15 . 16 attached. Between the pins 18 and the tension elements 15 . 16 , between the individual tension elements 15 . 16 and between the bolts 7 ' and the pins 18 contact points are formed at which touch each two contact surface areas.

In 4 are also the contact surface areas 11 ' . 12 ' shown, by means of which the chain links 6 ' on the contact surface areas 9 ' . 10 ' of the profile system 2 ' rest.

5 shows the conveyor chain 3 ' of the conveyor chain system 1' that have a drive or a diversion 19 to be led. The drive or the deflection 19 are designed as a sprocket, in which the tension elements 15 the conveyor chain 3 ' intervention. Here, too, so contact points, namely between the tension elements 15 and the drive wheel 19 formed, contact the contact surface areas.

6 shows another example of possible contact points in the conveyor chain system 1' , The conveyor chain 3 ' is about a bow wheel 20 guided, so that a deflection in the horizontal is made possible. Both the chain links slide 6 ' above the bow wheel 20 so that between the chain links 6 ' and the bow wheel 20 Contact points are formed with contacting contact surface areas. In addition, the pins come 18 in contact with the bow wheel 20 , so that here too a contact and friction takes place. There is also a contact between the tension elements 15 . 16 and the bow wheel 20 instead of.

At all contact points of the conveyor chain system 1 . 1' where there is movement between two contact surface areas, friction and thus wear occurs. In the case of accumulation conveyor chains, this of course also applies to the contact points between the conveyed material and the conveyor chain. In order to minimize this friction and wear, it is provided that at least a part of the contact surface areas of the contact points is provided with structural elements. In the 7 to 9 Examples of such structural elements are shown. These structural elements may be provided at each of the contact points in the conveyor chain system. The structural elements are formed integrally with the contact surface areas. The structural elements are therefore made of the same material as the contact surface areas. There may be other structures that achieve similar effects.

7 shows a section through one of the contact points of the conveyor chain system 1 . 1' , At the contact point 21 two contact surface areas touch 22 . 23 of two opposing components. These components may be, for example, the rails 4 . 5 ; 4 ' . 5 ' of the profile system 2 ; 2 ' and the respective chain links 6 ; 6 ' the conveyor chain 3 ; 3 ' act. It is also possible that it is one of the other contact points described above. The contact surface area 23 of the upper component 7 is designed as a smooth surface. The lower contact surface area 22 in 7 is provided with structural elements. These structural elements are in the form of webs 24 , The bridges 24 protrude over a main levels 25 the contact surface 22 out. The main level 25 the contact surface 22 is through the foot points F of the webs 24 established. The height H1 of the bridges 24 is the distance of the highest points of the webs 24 from the main level 25 the contact surface 22 , The bridges 24 form on the surface of a rectangular area. This rectangle surface transitions into a tangential edge rounding with the radius R1 at the edges. The bridges 24 So have rounded contours 26 on. The radius R1 is in a range of 0.05 mm to 1 mm. The rectangular area of the webs 24 forms the contact surface to the counter body with the contact surface area 23 , so the real contact surface, from. The width B1 of the webs 24 is defined as the distance at the surface of the webs 24 on which no rounding begins. This width B1 is in a range of 0.05 mm to 1 mm. Experiments have shown that even with widths up to 10 mm, the desired effect is still achieved. It can also be provided that the webs have a width of 0 mm, so that the webs take the form of a cylinder jacket surface. The individual bridges 24 are spaced from each other. The distance A1 of the individual webs is defined as the distance between the webs on which the tangential edge rounding R1 begins. The distance A1 of the webs is in a range of 0.05 mm to 10 mm, preferably 0.05 to 2 mm.

8th shows a further modification of a contact surface area 22 ' , The contact surface area 22 ' is back with structural elements 24 ' provided, wherein the structural elements have the shape of intersecting webs. The bridges 24 ' intersect at a right angle. The dimensions and the design of the webs correspond to those of the webs as in 7 shown.

The bridges 24 . 24 ' may be longitudinal, transverse or oblique with respect to the direction of movement at the contact point.

9a and 9b show a further modification of a contact surface area 22 '' , Also in this case, the contact surface area 22 '' again structural elements 24 '' on. In the following, only the essential differences to the structural elements already described, The structural elements 24 '' are arranged in a pattern, spherical elevations. The spherical elevations 24 '' have a diameter D of 0.02 mm to 2 mm. The height H2 of the spherical elevations 24 '' ie the distance from the base of the spherical elevations 24 '' in the main plane of the contact surface 22 '' to the highest point of the spherical elevations 24 '' , lies in a range of 0.05 to 2 mm. As in 9a shown are the spherical elevations 24 '' arranged in straight rows, wherein adjacent rows are offset from each other. The distance E of the centers of two spherical elevations 24 '' in the same row is in a range of 0.16 mm to 2 mm. The distance B2 of the centers of the spherical elevations 24 '' of every other row, that is to say the distance of the centers of the spherical elevations lying one above the other, is in a range of 0.08 mm to 1 mm. The distance A2 of the centers of one of the spherical elevations 24 '' to the next, offset to arranged spherical elevation 24 '' is also in a range of 0.08 mm to 1 mm. The height difference C of two centers of two adjacent spherical elevations 24 '' is in a range of 0.04 to 1 mm. Even with larger distances up to 10 mm, a friction or Verschließreduzierung is still achieved. Of course, these surveys need not necessarily be spherical, there are other forms, such as an oval conceivable.

These structural elements are provided in particular at the contact points between the chain links and the profile system. It is possible that the contact surface areas of the chain links are provided with structural elements, wherein the contact surface areas of the profile system has a smooth conventional surface. But it is also possible that the contact surface areas of the chain links have a smooth conventional surface shape and the contact surface areas of the profile system are provided with structural elements, or that both the contact surface areas of the chain links and the contact surface areas of the profile system are provided with structural elements.

Preferably, the components having structural elements are produced by injection molding. The injection molds are then designed so that the structural elements are produced by injection molding. If materials are used which do not allow injection molding, the structural elements want to be machined.

Claims (15)

Conveyor chain ( 3 . 3 ' ) having a plurality of contact surface areas ( 11 . 12 ; 11 ' . 12 ' ) subject to fretting, characterized in that at least one of the contact surface areas ( 11 . 12 ; 11 ' . 12 ' ) with the real contact surface of the contact surface areas ( 11 . 12 ; 11 ' . 12 ' ) reducing structural elements ( 24 ; 24 '; 24 '' ) is provided. Conveyor chain according to claim 1, characterized in that the structural elements ( 24 ; 24 '; 24 '' ) are made of the same material as the respective contact surface areas ( 11 . 12 ; 11 ' . 12 ' ). Conveyor chain according to one of claims 1 to 2, characterized in that the structural elements ( 24 ; 24 '; 24 '' ) Have projections. Conveyor chain according to one of claims 1 to 3, characterized in that the structural elements ( 24 ; 24 '; 24 '' ) have rounded contours. Conveyor chain according to one of claims 1 to 4, characterized in that the height (H1; H2) of the structural elements ( 24 ; 24 '; 24 '' ) is between 0.05 mm and 2 mm. Conveyor chain system according to claim 4, characterized in that the radii (R1, D12) of the rounded structural elements ( 24 ; 24 '; 24 '' ) are within a range of 0.01 mm to 2 mm. Conveyor chain according to one of claims 1 to 6, characterized in that the width (B1) of the structural elements ( 24 ; 24 '; 24 '' ) is about 0 mm to 10 mm. Conveyor chain according to one of claims 1 to 7, characterized in that the structural elements ( 24 ; 24 '; 24 '' ) and the distance (A1, A2, B2, C, E) between the highest points of two adjacent structural elements ( 24 ; 24 '; 24 '' ) 0.04 mm to 10 mm. Conveyor chain according to one of claims 1 to 8, characterized in that a plurality of chain links ( 6 ; 6 ' ) provided by means of bolts ( 7 ; 7 ' ) and / or pins ( 18 ) are endlessly interconnected, the chain links ( 6 ; 6 ' ) on its top and / or its bottom contact surface areas ( 11 . 12 ; 11 ' . 12 ' ) exhibit. Conveyor chain according to claim 9, characterized in that between the different elements of the conveyor chain mutually cooperating contact surface areas are formed. Profile system ( 2 ; 2 ' ), in particular for a conveyor chain system, having a plurality of contact surface areas ( 9 . 10 ; 9 ' . 10 ' ) subject to fretting, characterized in that at least one of the contact surface areas ( 9 . 10 ; 9 ' . 10 ' ) with the real contact surface of the contact surface areas ( 9 . 10 ; 9 ' . 10 ' ) reducing structural elements ( 24 ; 24 '; 24 '' ) is provided. Profile system according to claim 11, characterized in that the structural elements ( 24 ; 24 '; 24 '' ) are made of the same material as the respective contact surface areas ( 9 . 10 ; 9 ' . 10 ' ). Conveyor chain system with a conveyor chain ( 3 ; 3 ' ) according to one of claims 1 to 10 and / or with a profile system ( 2 ; 2 ' ) according to one of claims 11 to 18, which guides the conveyor chain. Conveyor chain system according to claim 19, characterized in that at least one of the contact surface areas ( 11 . 12 ; 11 '; 12 ' ) of the conveyor chain with an opposing contact surface area ( 9 . 10 ; 9 '; 10 ' ) of the profile system and at least one of the contact surface areas ( 11 . 12 ; 11 '; 12 '; 9 . 10 ; 9 '; 10 ' ) with structural elements ( 24 ; 24 '; 24 '' ) is provided. Conveyor chain system according to claim 20, characterized in that the contact surface areas of the conveyor chain and the opposite contact surface areas of the profile system consist of different materials and only the Contact surface areas with higher material hardness with structural elements ( 24 ; 24 '; 24 '' ) are provided.

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