Vibratory conveyor and method for conveying silicon fragments

Abstract

A vibrating conveyor having a conveyor chute which has a conveyor surface consisting of silicon, wherein plastic elements are provided between the base body of the conveyor chute and the conveyor surface. The vibrating conveyor is suitable for use in a method for conveying silicon chunks.

Claims

1. A vibrating conveyor having a conveyor chute, the conveyor chute comprising a conveyor surface consisting of silicon, wherein plastic elements consisting of PU, PP, PE, PVDF or PA are provided between a base body of the conveyor chute and the conveyor surface, wherein the plastic elements and the silicon that forms the conveyor surface are adhesively bonded to support plates, which are laid in the conveyor chute and secured, wherein the conveyor surface consisting of silicon is partially covered with sheets of PU.

2. The vibrating conveyor of claim 1, wherein the support plates are screwed circumferentially onto the conveyor chute or to a conveyor chute bottom.

3. The vibrating conveyor of claim 1, wherein the support plates are clamped in the conveyor chute by means of clamps.

4. The vibrating conveyor of claim 1, wherein the support plates are clamped in the conveyor chute by means of clamping wedges.

5. The vibrating conveyor of claim 1, further comprising lateral parts consisting of plastic, which are fastened on the conveyor chute and which clamp the support plates.

6. A method for conveying silicon chunks, wherein the silicon chunks are conveyed over the conveyor surface of the vibrating conveyor of claim 1.

7. A vibrating conveyor having a conveyor chute, which comprises a conveyor surface consisting of silicon, wherein plastic elements consisting of PU, PP, PE, PVDF or PA are provided between a base body of the conveyor chute and the conveyor surface, wherein the plastic elements are a cladding of the conveyor chute with plastic, and wherein the conveyor surface is formed by further cladding parts consisting of silicon, wherein the plastic cladding elements are secured in the conveyor chute, wherein the plastic cladding parts consisting of silicon are laid in the conveyor chute cladded with plastic, and secured, wherein the conveyor surface consisting of silicon is partially covered with sheets of PU.

8. The vibrating conveyor of claim 7, wherein the cladding parts are screwed circumferentially onto the conveyor chute or to a conveyor chute bottom.

9. The vibrating conveyor of claim 7, wherein the cladding parts are clamped in the conveyor chute by means of clamps.

10. The vibrating conveyor of claim 7, wherein the cladding parts are clamped in the conveyor chute by means of clamping wedges.

11. The vibrating conveyor of claim 7, furthermore comprising lateral parts of plastic, which are fastened on the conveyor chute and which clamp the cladding parts.

12. A method for conveying silicon chunks, wherein the silicon chunks are conveyed over the conveyor surface of the vibrating conveyor of claim 7.

13. A vibrating conveyor having a conveyor chute, the conveyor chute comprising: a conveyor surface consisting of silicon cladding parts; a plastic support plate consisting of PU, PP, PE, PVDF or PA disposed directly beneath the silicon cladding parts; and a base body separated from the conveyor surface by the plastic support plate, wherein the plastic support plate and the silicon cladding parts are secured in the conveyor chute, and wherein the conveyor surface consisting of silicon cladding parts is partially covered with sheets of PU.

14. The vibrating conveyor of claim 13, wherein the support plate is screwed circumferentially onto the conveyor chute or to a conveyor chute bottom.

15. The vibrating conveyor of claim 13, wherein the support plate is clamped in the conveyor chute by means of clamps.

16. The vibrating conveyor of claim 13, wherein the support plate is clamped in the conveyor chute by clamping wedges.

17. The vibrating conveyor of claim 13, further comprising a lateral part consisting of plastic, fastened on the conveyor chute, and clamping the support plate.

18. A method for conveying silicon chunks, wherein the silicon chunks are conveyed over the conveyor surface of the vibrating conveyor of claim 13.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 depicts an example conveyor chute according to one or more embodiments. The FIGURES are not to scale. The size and shape of various depicted features is for illustration purposes only.

(2) The plastic elements preferably consist of polyurethane (PU), polypropylene (PP), polyethylene (PE), polyvinylidene fluoride (PVDF), or polyamide (PA).

(3) The plastic elements are preferably cladding of the conveyor chute with plastic. The cladding parts consisting of plastic are preferably secured in the conveyor chute. The silicon elements forming the conveyor surface are preferably likewise placed in the conveyor chute clad with plastic and secured.

(4) The plastic elements are preferably support plates, on which there is silicon that forms the conveyor surface. Preferably, the plastic plate and the silicon cladding part are adhesively bonded to one another. The support plates with silicon claddings are preferably secured in the conveyor chute.

(5) With the present invention, it is possible to transport highly pure fragmented polysilicon with low contamination in conveyor chutes.

(6) In order to obtain an optimal conveying behavior of the silicon chunks, the cladding parts should be clamped sufficiently in the conveyor chute.

(7) Loose or loosening parts are detrimental influences which negatively affect the conveying behavior of the chutes.

(8) In this way, above all, the vibration ranges of the chutes are altered and affect the conveying speed, and therefore the cycle rate of subsequent processes.

(9) In order to counteract this, the cladding parts consisting of silicon are preferably fastened in an assembly on common support plates.

(10) The number of bolts per support plate is 1n bolts (preferably 1-50), depending on the type of conveyor chute.

(11) For the support plate material, a low-contamination material is to be selected, preferably PU with a Shore hardness 80-98 A without additives or colorants.

(12) The support material in this case has a defined thickness of 2-30 mm, more preferably 3-5 mm.

(13) The fastening of the silicon parts on the support material is preferably carried out with low-contamination resilient adhesives with high intrinsic adhesion, for example silicone adhesives.

(14) Fastening of the silicon claddings on PU support material instead of steel support material is characterized by lower contamination of the conveyed product with iron.

(15) The manufactured cladding parts (1n) on support material are placed in the conveyor chute and changed according to the degree of wear.

(16) The clamping of the inlaid claddings (plastic cladding, silicon cladding, support plates) is preferably carried out by means of one or more of the clamping mechanisms mentioned below: low-contamination screw connections extending around on the conveyor chutes, which press directly on the cladding low-contamination clamping wedges in the conveyor chute, securing of the cladding in the conveying direction fixed clamping of the cladding by means of the lateral parts of the conveyor chute screwing of the Si cladding via the support plate to the chute bottom

(17) Clamping of the cladding 30 may be carried out by means of additional lateral parts 40 of the conveyor chutes 100, which are preferably fastened on the chutes 100 by means of a rapid clamping system.

(18) The additional clamping from above prevents lifting or loosening of the cladding during the vibrating conveying.

(19) The material to be used for the lateral parts is preferably PP and PE, adhesively bonded to PU mats, PU with a Shore hardness 60-80 A, or a comparable low-contamination and wear-resistant material, such as silicone.

(20) All polymers, types of PU and silicones are preferably free of colorants or additives, for example crushed rock, carbon black, etc.

(21) In order to protect the cladding against wear in the conveyor chutes, and in order to save on costs, separating mats made of various materials, which prevent direct contact of the silicon chunks with the cladding, are preferably fastened on the conveyor chutes.

(22) The separating mat material is preferably PU with a Shore hardness 60-80 A.

(23) The invention also relates to another type of conveyor chute cladding. This may, for example, be done by means of special plastics.

(24) Preferably, low-contamination and highly wear-resistant plastics such as PU with a Shore hardness 60-98 A are used in this case.

(25) The nature of the fastening is in this case carried out in the same way as for the silicon cladding.

(26) Bearing parts with direct contact or parts in the immediate vicinity of the product are encapsulated with special injection-molded PU parts, or entire surfaces of frameworks are clad with PU spray coating.

(27) Qualified materials are PU coating systems with Shore hardness 65-98 A without addition of additives.

LIST OF REFERENCE NUMBERS AND DESIGNATIONS

(28) 10 base body of the conveyor 20 plastic elements 30 cladding part consisting of silicon 40 lateral part 100 conveyor chute