Device for transporting a material strand

Abstract

A device for transporting a material strand, in particular a sticky plastic material strand. The device includes a transport unit for transporting the material strand and a discharge unit for discharging a separating powder. The discharge unit is arranged to apply the separating powder directly onto an underside of the material strand.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

Further advantages will be appreciated from the accompanying descriptive drawings. Illustrative embodiments of the invention are depicted in the drawing. The drawings, the description and the claims contain numerous characterizing features in combination. A person skilled in the art will appropriately also consider the characterizing features individually and will combine them to produce sensible additional combinations. In the drawings:

FIG. 1 illustrates a device according to an exemplary embodiment for transporting a material strand depicted in a side view;

FIG. 2 illustrates a device for transporting a material strand as a second embodiment depicted in a side view; and

FIG. 3 illustrates an alternative discharge unit for the device shown in FIG. 2 depicted in a side view.

DETAILED DESCRIPTION

A device 10a for transporting a material strand 12a is illustrated in FIG. 1. The device 10a includes a transport unit 14a, which is arranged for transporting the material strand 12a, together with a discharge unit 16a and a unit 28a, which is arranged for the purpose of dispensing the material strand 12a. The material strand 12a emerges from the unit 28a in a molten state. The material strand 12a is formed from a thin and sticky plastic strand, for example a glass fiber-reinforced plastic strand.

The discharge unit 16a is arranged for the direct application of a separating powder 18a onto an underside 20a of the material strand 12a. The separating powder 18a in this case is adapted to a filler material of the material strand 12a or corresponds to a filler material of the material strand 12a, so that the material characteristics of the material strand 12a remain unaffected by the separating powder 18a.

The discharge unit 16a includes a nozzle 22a for the direct application of the separating powder 18a onto the underside 20a of the material strand 12a. In addition, the discharge unit 16a includes a heating chamber 30a, in which the separating powder 18a together with fluidization air 24a is heated to a temperature of the material strand 12a. For this purpose, the heating chamber 30a includes heating elements (not illustrated in more detail here), which heat the separating powder 18a together with the fluidization air 24a to the desired temperature, so that moisture formation during heating of the separating powder 18a is avoided advantageously. On reaching the temperature of the material strand 12a, the fluidization air 24a and the separating powder 18a are conveyed together via a channel 32a to the nozzle 22a of the discharge unit 16a. The separating powder 18a and the fluidization air 24a are sprayed together in finely distributed form onto the underside 20a of the sticky material strand 12a by means of the nozzle 22a. The separating powder 18a in this case is sprayed with a uniform layer thickness 34a onto the underside 20a of the material strand 12a. Adhesion between the separating powder 18a and the material strand 12a is achieved by a sticky surface of the underside 20a of the material strand 12a.

The material strand 12a with a separating powder layer 36a sprayed onto the underside 20a is then laid with its side exhibiting the separating powder layer 36a onto a transport belt 38a of the transport unit 14a. The transport unit 14a comprises two transport belts 38a, 48a, each with a drive roller body 40a, 50a, and each with a roller body 42a, 52a carried along by the drive roller body 40a, 50a. The transport belts 38a, 48a in this case are arranged one after the other, whereby these are tensioned in each case by the drive roller bodies 40a, 50a and the roller bodies 42a, 52a. During operation of the transport unit 14a, each of the transport belts 38a, 48a is driven via the drive roller bodies 40a, 50a. A direction of running of the transport belts 38a, 48a is indicated in FIG. 1 with arrows. The material strand 12a is transported away from the unit 28a in a direction 46a by means of the transport belts 38a, 48a. A belt speed for the transport belts 38a, 48a and a discharge rate for the material strand 12a of the unit 28a are advantageously matched to one another in this case.

The separating powder 18a includes a non-adhesive characteristic in relation to the surfaces of the transport belts 38a, 48a, so that adhesion of the material strand 12a to the transport belts 38a, 48a is prevented. The layer thickness 34a of the separating powder layer 36a on the underside 20a of the material strand 12a is designed in this case in such a way that it provides separation of the material strand 12a and the transport belts 38a, 48a for the duration of the transport of the material strand 12a on the transport belts 38a, 48a. If, following unrolling of the material strand 12a, residue of the separation powder 18a remains on the transport belts 38a, 48a, these are removed by a suction unit 74a. For this purpose, the suction unit 74a for each transport belt 38a, 48a includes a suction means 76a, 78a, which removes the residues of the separating powder 18a by suction at the ends of the transport belts 38a, 48a facing towards the roller bodies 42a, 52a in each case.

For further processing of the material strand 12a together with the separating powder 18a, there is arranged between the two transport belts 38a, 48a a cutting device 54a, so that, in conjunction with cutting of the material strand 12a, adhesion to one of the two transport belts 38a, 48a is avoided. The cutting device 54a is provided for the purpose of cutting the material strand 12a and comprises two cutting means 56a, 90a, in each case in the form of a cutting blade, and two blade guides 58a, 60a, each of which is provided for one of the cutting means 56a, 90a. For cutting, the material strand 12a together with the separating powder 18a is guided to the cutting device 54a and is parted by the cutting means 56a, 90a as they move up and down synchronously in relation to one another. In conjunction with this, one of the cutting means 56a, 90a in each case is guided in relation to the material strand 12a in a position necessary for cutting by means of one of the blade guides 58a, 60a in each case. Strand sections 62a that have been separated from the material strand 12a are transported onwards to a press device 64a by the transport belt 48a.

The press device 64a, which is provided for the compression molding of the individual strand sections 62a, includes a lower mold part 66a and an upper mold part 68a, which is movably arranged in relation to the lower mold part 66a along a vertical axis 70a. The upper mold part 68a is pressed by means of a hydraulically driven press element 72a onto the lower mold part 66a during a pressing operation by the press device 64a. Fundamentally, however, press devices driven mechanically and/or with compressed air are conceivable at any time in a further embodiment of the invention. If a strand section 62a is guided by the transport belt 48a of the transport unit 14a into the press device 64a and onto the lower mold part 66a, this is followed by the compression of the upper mold part 68a onto the lower mold part 66a by the press element 72a, and the strand section 62a is pressed together with the separating powder 18a adhering to the underside 20a into the desired form.

A further embodiment of the device 10b for transporting a material strand 12b is illustrated in FIGS. 2 and 3. Reference can be made to the description of the illustrative embodiments in FIG. 1 in respect of characteristic features and functions that remain the same. Component parts and characteristic features which correspond in essential respects are basically identified with the same reference designations, in conjunction with which the letters a (in FIG. 1) or b (in FIGS. 2 and 3) have been added to the reference designations for the purpose of distinguishing between the illustrative embodiments. The subsequent description in FIGS. 2 and 3 is restricted essentially to the differences from the illustrative embodiment in FIG. 1.

A device 10b for transporting a material strand 12b is illustrated in FIG. 2. The device 10b includes a transport unit 14b, which is arranged for transporting the material strand 12b, together with a discharge unit 16b and a unit 28b, which is arranged for the purpose of dispensing the material strand 12b. The material strand 12b emerges from the unit 28bin a molten state. The material strand 12b is in the form of a thin and sticky plastic strand, for example a glass fiber-reinforced plastic strand.

The discharge unit 16b is arranged for the dispensing of a separating layer 26b, which provides for the separation of the material strand 12b and a transport belt 38b, 48b of the transport unit 14b. The separating layer 26b in this case is in the form of a nonwoven glass fiber fabric, which provides a continuous and—where considered necessary—wall-to-wall substrate for the material strand 12b. The separating layer 26b formed by the nonwoven glass fiber fabric is advantageously adapted in this case to a reinforcing material for the material strand 12b formed from glass fiber.

The discharge unit 16b comprises a seat 80b, a discharge channel 82b and the transport belt 38b. The separating layer 26b is suspended in rolled-up form in the seat 80b and is unrolled in conjunction with its discharge. The separating layer 26b is discharged via the discharge channel 82b in an unrolled condition. The discharge channel 82b is surrounded for part of its section by heating elements 84b, 86b, which preheat the separating layer 26b to a temperature of the material strand 12b. The preheated separating layer 26b is applied to the transport belt 38b, and the material strand 12b is then laid with its underside 20b in front onto the separating layer 26b, so that the separating layer 26b is arranged between the material strand 12b and the transport belt 38b. The separating layer 26b in this case adheres to a sticky surface of the underside 20b of the material strand 12b. In addition, the separating layer 26b includes nonstick characteristics in relation to the transport belt 38b, so that adhesion between the material strand 12b and the transport belts 38b is prevented.

Further processing of the material strand 12b together with the separating layer 26b takes place via the transport unit 14b, a cutting device 54b and a pressing device 64b. Transporting, parting and pressing of the material strand 12b together with the separating layer 26b take place in this case in a manner that remains identical to the embodiments in FIG. 1.

Illustrated in FIG. 3 is an alternative embodiment to that illustrated in FIG. 2 for a discharge unit 16b for a separating layer 26b. The discharge unit 16b in this case comprises a seat 80b, a discharge channel 82b and a roller body 88b. A separating layer 26b is applied in this case through the discharge unit 16b directly onto an underside 20b of a material strand 12b. The separating layer 26b is suspended in rolled-up form in the seat 80b and is unrolled in conjunction with its discharge. The separating layer 26b is discharged via the discharge channel 82b in an unrolled condition. The discharge channel 82b is surrounded for part of its section by heating elements 84b, 86b, which preheat the separating layer 26b to a temperature of the material strand 12b. The preheated separating layer 26b is applied directly to the underside 20b of the material strand 12b via the roller body 88b. The roller body 88b, by which the separating layer 26b is guided to the material strand 12b, causes the separating layer 26b to be pressed against the underside 20b of the material strand 12b. The separating layer 26b adheres to the material strand 12b through a sticky surface of the underside 20b of the material strand 12b. The material strand 12b is then laid with a side exhibiting the separating layer 26b in front onto a transport belt 38b of the transport unit 14b, so that adhesion of the material strand 12b to the transport belt 38b is prevented.

The invention is described herein in detail with particular reference to presently preferred exemplary embodiments. However, it will be understood that variations and modifications can be effected within the scope and spirit of the invention.

Claims

1. A device for transporting a sticky plastic material strand, comprising: a transport unit for transporting the material strand; anda discharge unit for applying a separating powder to the material strand, whereinthe discharge unit is so arranged as to apply the separating powder directly onto an underside of the material strand.

2. The device according to claim 1, wherein the discharge unit includes at least one nozzle for spraying the separating powder onto the underside of the material strand.

3. The device according to claim 2, wherein the discharge unit is so arranged as to heat the separating powder before it is sprayed onto the underside of the material strand.

4. A method for transporting a sticky plastic material strand, comprising: applying a separating powder directly to an underside of the material strand; andtransporting the material strand.

5. The method according to claim 4, further comprising heating the separating powder together with fluidization air.

6. The method of claim 5, further comprising spraying the separating powder together with the fluidization air onto the underside of the material strand.

7. The method of claim 4, wherein a material of the separating powder is adapted to a material of the material strand.

8. The method of claim 4, wherein the separating powder together with the material strand is further processed.

9. A device for transporting a sticky plastic material strand, comprising: a transport unit for transporting the material strand; anda discharge unit being arranged to apply a separating layer onto an underside of the material strand.

10. The device according to claim 9, wherein the discharge unit is arranged to apply the separating layer between the underside of the material strand and the transport unit.

11. The device according to claim 9, wherein the discharge unit is arranged to apply the separating layer in heated form between the underside of the material strand and the transport unit.

12. A method for transporting a sticky plastic material strand, comprising: applying a separating layer to an underside of the material strand; andtransporting the sticky plastic material strand.

13. The method according to claim 12, wherein the applying a separating layer to an underside of the material strand comprises applying the separating layer in heated form between the underside of the material strand and the transport unit.

14. The method according to claim 12, wherein a material of the separating layer is adapted to a material of the material strand.

15. The method according to claim 12, wherein the separating layer is in the form of a continuous substrate.

16. The method according to claim 12, wherein the continuous substrate is formed from a nonwoven glass fiber fabric.

17. The method according to claim 12, wherein the separating layer together with the material strand is further processed.

18. The method according to claim 12, further comprising compressing the separating layer with the material strand.