DE3527640C2 - Device and method for producing belts from plasticizable material - Google Patents

Description

The invention relates to a device for producing Belts made of plasticizable material according to the generic term of claim 1. Furthermore, the invention relates to a Process for producing belts from plasticizable Material according to the preamble of claim 8.

Belts made of plasticizable material that act as two part belts and a tensile insert are from the state of the Technology well known. The GB-PS 12 51 908 shows one such straps. When manufacturing the belt according to GB-PS 12 51 908 finished pre-formed part belts by Vulkani connected with each other. The connecting surfaces of both Part belts must therefore be reheated in a complex manner to join the sub-belts together.

DE-AS 21 23 902 also shows a belt with a tensile strength Insert, which is however made in one piece. At the Her Position of the belt according to DE-AS 21 23 902 are reinforcement strands applied to a molding wheel during casting. The Reinforcement strands must therefore be in a cumbersome way a mouthpiece of an extruder are inserted.  

DE-PS 11 10 397 discloses a belt consisting of two ge separate main sections. The two main sections of the belt are laid face to face and include stranded tension elements.

Proceeding from this, the present invention has the problem based, an improved method and an apparatus for Manufacture of belts from plasticizable material too create.

To solve this problem, the Vorrich invention device for producing belts from plasticizable material the features of claim 1. According to the invention Form wheel of the first form designed as a pulley, wherein the tension members are inserted into grooves in the form wheel. this has the advantage that straps with the device according to the invention can be manufactured in which the tension members are defined at precisely Places.

The method according to the invention for producing a belt Made of plasticizable material has the features of the patent claims 8. According to the invention, the tension members before applying the plasticized material for one Partial belt placed on the form wheel of the first form. Hereby can the tension member in a particularly simple manner to the Manufacture of the first sub-belt are fed. About that In addition, it is possible to position the tension members exactly in the grooves of the Align the form wheel. The tension members are therefore at ferti belt at precisely defined points.

The first part belt is made by casting or Injection molded an insert, the material in the plastic condition is applied to the insert. By the Forming the partial belt on the insert is always in a defined position to the part belt. The casting or Injection molding enables a particularly intimate connection between the insert and the belt.  

The second belt part is attached to the first belt part on the Molded side of the insert. This makes the position of the Inlay also immovable compared to the second belt fixed. In a preferred embodiment of the invention becomes the first part belt in the area of the connecting surface both belts replastified. This will make the connection between the two belts particularly intimate and can in the area due to possible stresses (gravity) not easily solved.

The material is essentially depressurized in corresponding Shapes entered. This makes it possible to Forming mold halves inexpensively because of expensive Sealant can be dispensed with.

The individual part belts can be made of different Materials are manufactured and so the union various properties in a single belt cause. Required properties can be: Abrasion resistance on the overlying side, tensile strength overall, heat or radiation resistance on the of Side facing the action, high vibration damping, for example with particularly long straps, etc.

The division level of the belts according to the invention is in the bending-neutral zone. It is prevented that in operation at the division level, shear forces occur that lead to a Destruction of the connection of both belt parts.

The strap comes with a (particularly tensile) insert provided that firmly in the side facing the division level of the belt part is embedded. The deposit is also there in the bending-neutral zone and is made of the material of the belt completely included.

The surface of the side, in which the insert is embedded, in the longitudinal direction extending triangular profile-like depressions enlarges what later enables a more intimate connection of the part belts.  

Because the insert is not as usual during production to lie immediately in the middle of a (one-piece) belt comes, but first in an outer surface of a belt part is embedded, you can see the spatial location of the insert in the Fix the manufacturing process more easily and precisely.

In continuation of the inventive concept, the belt corresponds in its transverse dimension several arranged side by side Single belt, with the tensile inserts inside of the belt are arranged side by side so that they are each correspond to the width of the individual belts. By this measure can inexpensive multiple straps, e.g. B. with DIN width, can be manufactured at the same time, with only one more Operation for cutting the belt into individual belts is required.  

The strap can also be in two parts without using a train fixed insert. The first part belt is then made from a particularly tensile material.

In another advantageous embodiment, the Belts made up of more than two part belts, especially three Partial belt made, the middle part of the belt Function of the tensile insert takes over. The medium part belts should not be made too thick the shear forces on the connecting surfaces of the part belts not to let it get too big.

Further features of the invention emerge from the sub claims.

An embodiment of the belt and the device is explained below with reference to the drawing.

Here shows

Fig. 1 is a side view of a device for the produc tion of a first belt part with a tensile strength;

Fig. 2 shows a section along the line II-II in Fig. 1,

Fig. 3 is a side view of a device for Anfor tion of a second belt part to a first belt part with insert, and

Fig. 4 shows a section along the line IV-IV in Fig. 3.

Figs. 2 and 4 are compared with the corresponding Fig. 1 and 3 increases.

The belt 10 shown ( Fig. 3) consists of a partial belt 11 and a partial belt 12 , which is seen on the side of the belt 11 facing away with a tooth profile 13 ver. The two sub-belts 11 , 12 are firmly and permanently connected to one another in the area of a connecting plane 14 . On the side of the belt 11 , the Ver connecting plane 14 between the two belts 11 , 12 facing, a tensile insert 15 is formed.

A device for manufacturing the belt 10 shown consists of two molds 16 , 17 . The form 16 for the manufacture of the belt 11 consists of a forming belt 18 and a form wheel 19 ( Fig. 1). The forming belt 18 is fed along a portion of the forming wheel 19 and runs over an upper pressure roller 20 , a lower pressure roller 21 and a guide roller 22nd As shown in Fig. 1 ersicht Lich, the upper pressure roller 20 is disposed above the molding wheel 19 at a distance from this. The guide roller 22 is arranged to the right of the form wheel 19 , the connecting line between the guide roller 22 and form wheel 19 having an angle of 90 ° to the connecting line between the upper pressure roller 20 and form wheel 19 . The lower pressure roller 21 is arranged below the form wheel 19 , namely on the extension of the connecting line between the upper pressure roll 20 and form wheel 19 downwards. The form wheel 19 rotates clockwise and forms together with the form band 18 a mold cavity 23 from the upper pressure roller 20 to the lower pressure roller 21st The mold cavity 23 can be adjusted via the distance of the pressure rollers 20 , 21 from the mold wheel 19 . The form wheel 19 is designed as a pulley with circumferential grooves 24 on its circumferential surface. The grooves 24 have a V-shaped or triangular cross-sectional configuration.

As can be seen from FIG. 3, the shape 17 for forming the partial belt 11 on the partial belt 12 consists of the forming belt 25 and the forming wheel 26 . The forming belt 25 runs over an upper pressure roller 27 , a lower pressure roller 28 and a deflection roller 29 , which are arranged relative to the forming wheel 26 in the same way as the rollers 20 , 21 , 22 to the forming wheel 19 . Between the clockwise rotating mold wheel 26 and the forming belt 25, there is a mold cavity 30 from the upper pressure roller 27 to the lower pressure roller 28 . This mold cavity 30 is adjustable via the distance between the pressure rollers 27 , 28 from the mold wheel 26 . The form wheel 26 consists of a tool disc 31 and laterally closing flanges 32 and 33 . The tool disc 31 is provided for the purpose of shaping the tooth profile 13 with circumferential successive depressions 34 , the lower edges 35 , seen from the center 36 of the form wheel 26 , are lower than the peripheral surfaces 37 , 38 of the flanged wheels 32 , 33 .

In the manufacture of the belt 10 , the part of the belt 11 is first produced by a plastic stream 40 being fed into the mold 16 from an extruder 39 . The material - here the plastic stream 40 - is not, as is customary in injection molding, placed under pressure in the mold 16 , but essentially without pressure. On the molding wheel 19 , which is designed as a grooved disk, the tension-resistant insert 15 , which was previously fed to the molding wheel 19 via the guide roller 41, lies in the grooves 24 . The guide roll 41 is arranged so that the tensile insert 15 rests on the pulley 19 before the plastic stream 40 enters the mold 16 . The plastic stream 40 is dimensioned such that the tensile insert 15 is just covered. The plastic stream 40 is pressed by the pressure of the upper pressure roller 20 with the tensile position 15 on the pulley 19 and receives its final shape by the pressure of the forming belt 18 and the lower pressure roller 21 . The distance between the two pressure rollers 20 , 21 from the forming wheel 19 can be adjusted in order to be able to manufacture partial belts 11 of different thicknesses. The shape band 18 exerts a pressure in the direction of the center of the shape wheel 19 due to its geometric arrangement, provided that it is under tension. In the finished part belt 11 , the tensile insert 15 is now embedded on the side facing the molding wheel 19 .

According to FIG. 3, the belt part 11 is formed on the portion of belt 12 in a next step, and pressed with the SEM. For this purpose, a plastic material stream 44 is placed between the upper pressure roller 27 and the molding wheel 26 in the mold 17 from an extruder 43 . The plastic stream 44 rests on the molding wheel 26 and is covered from the outside by the partial belt 11 , which is simultaneously fed via the upper pressure roller 27 . Just as with the form 16 , the pressure rolls 27 , 28 are adjustable in their distance from the form wheel 26 in this form 17 in order to be able to set different belt thicknesses.

If the belt 10 is manufactured as a toothed belt, the pitch of the toothed belt can also be adjusted within narrow limits by adjusting the pressure rollers 27 , 28, in order to adapt the toothed belt to a specific load case during production.

Preferably, the belt part 11 is wider than the tool disk 31 , so that outer edges 45 , 46 of the belt part 11 protrude up to the flanges 32 , 33 . The pressure roll 27 , 28 are set so that between the Kan th 45 and 46 of the belt 11 and the flanges 32 and 33 there is a defined gap 47 , which corresponds to the thickness of the belt 12 , minus the height of the existing before Tooth profile 13 .

The finished toothed belt 10 occurs between the lower pressure roll 28 and the mold wheel 26 from the mold 17 . Preferably, the tensile insert 15 consists of individual tension members 48 , for. B. steel wire strands that come to lie cleanly next to each other in the grooves 24 of the molding wheel 19 . The diameter of a single tension member 48 is at most as large as the distance from the lowest point of a groove 24 to the bottom point of the adjacent groove and at least so large that part of the cross section of the tension member 48 projects beyond the circumferential surface of the pulley 19 ( FIG. 2 ).

According to Fig. 4, the tension members 48 of the tension-proof insert 15 to Zugträgergruppen 49 (deposits groups) combined, such that the belt cross-section is not provided over its ge entire width with tension members 48 but that exist between the tension members 48 gaps 50, Zvi the Define the two gaps lying tension member 48 as belonging to a train member group 49 . In this arrangement of the tension members 48 , the belt 10 is divided in a further work step by longitudinal cuts into individual belts accordingly the width of the tension member groups 49 .

Reference list

10 straps
11 part belts
12 part belts
13 tooth profile
14 connection level
15 tensile insert
16 form
17 form
18 shaped ribbon
19 form wheel (grooved disc)
20 upper pressure roller
21 lower pressure roller
22 pulley
23 mold cavity
24 groove
25 form ribbon
26 form wheel
27 upper pressure roller
28 lower pressure roller
29 pulley
30 mold cavity
31 tool disk
32 flanged wheel
33 flanged wheel
34 deepening
35 bottom edge
36 center point
37 peripheral surface
38 peripheral surface
39 extruders
40 plastic stream
41 Leadership role
43 extruders
44 plastic flow
45 edge
46 edge
47 gap
48 tension members
49 tension member group (insert group)
50 gap

Claims (10)

1. Apparatus for the production of belts made of plasticizable material, with a first mold for the production of a first belt part and a second mold for the formation of a second belt part on the first belt part, which is connected to the first mold, each of which is a mold Extruder is arranged, which is arranged in front of a mold cavity of the respective mold and supplies the material for the part to be manufactured, characterized by the following features:

• a) the molds ( 16 , 17 ) each consist of a rotatable molding wheel ( 19 , 26 ) and an endless molding belt ( 18 , 25 ) which is brought together along a partial circumference with the molding wheel ( 15 , 25 ), such that the Mold cavity ( 23 , 30 ) is created between the two,
• b) the molding wheel ( 19 ) of the first mold ( 16 ) is designed as a grooved disk which has recesses formed on its circumferential surface as grooves running around it ( 24 ),
• c) the first form ( 16 ) are assigned means for supplying individual tension members ( 48 ) or groups of tension members ( 48 ) for forming the insert ( 15 ) to the forming wheel formed as a grooved disk ( 19 ), these means being arranged in this way that the tension members ( 48 ) come to rest essentially in the grooves ( 24 ).

2. Apparatus according to claim 1, characterized in that the endless forming belt ( 18 ) of the first mold ( 16 ) at the beginning and at the end of the mold cavity ( 23 ) is guided via adjustable pressure rollers ( 20 , 21 ), the extruder ( 39 ) located pressure roll ( 20 ) is arranged such that the material donated by the extruder ( 39 ) is pressed with the insert ( 15 ) resting on the form wheel ( 19 ) formed as a grooved disk ( 19 ). 3. Apparatus according to claim 1 or 2, characterized in that the endless forming belt ( 25 ) of the second form ( 17 ) at the beginning and at the end of the mold cavity ( 30 ) is guided by adjustable pressure rollers ( 27 , 28 ), which are such are arranged so that the partial belt ( 11 ) is fed via the pressure roller ( 27 ) located on the extruder ( 43 ) and this presses the partial belt ( 11 ) onto the extruded material on the molding wheel ( 26 ). 4. Device according to one or more of claims 1 to 3, characterized in that the means for supplying the position ( 15 ) as guide rollers ( 41 ) and in the direction of rotation of the formed as a grooved wheel ( 19 ) seen in front of the extruder ( 39 ) are arranged in such a way that the tensile insert ( 15 ) rests on the molding wheel ( 19 ) designed as a grooved disc before the insert ( 15 ) runs past the extruder ( 39 ) and enters the mold cavity ( 23 ). 5. The device according to one or more of claims 1 to 4, characterized in that the molding wheel ( 26 ) of the second shape ( 17 ) is formed with successive openings in the circumferential direction ( 34 ) and from a tool disc ( 31 ), in the peripheral surface thereof the recesses ( 34 ) are formed as open slots to the end faces, and consists of two flanges ( 32 , 33 ), which are essentially flush with the peripheral surface of the tool disc ( 31 ). 6. The device according to claim 5, characterized in that the tool disc ( 31 ) is narrower than the partial belt ( 11 ) supplied via the upper pressure roller ( 27 ) is ready. 7. The device according to one or more of claims 1 to 6, characterized in that the pressure rollers ( 27 , 28 ) of the second form ( 17 ) are arranged such that between the outer belt part ( 11 ) and the form wheel ( 26 ) defined gap ( 27 ). 8. A process for the production of belts from plastibilierba rem material, wherein two sub-belts are produced, characterized in that to form the first sub-belt ( 11 ) first individual tensile insert ( 15 ) forming train carrier ( 48 ) in depressions of a form wheel ( 19 ) who inserted, then the plasticized material for the first part belt ( 11 ) is applied to the forming wheel and connected to the tension members ( 48 ), and finally the second part belt ( 12 ) is formed. 9. The method according to claim 8, characterized in that after the production of the first part belt ( 11 ), the second part belt ( 12 ) is molded on the side of the insert ( 15 ) by casting on the first part belt ( 11 ). 10. The method according to claim 8 or 9, characterized in that the material for both belt parts ( 11 , 12 ) is injected without pressure into a corresponding shape ( 16 , 17 ).