RU2104317C1 - Method for processing of wastes of armored cable and plant for its embodiment - Google Patents

Abstract

FIELD: methods and plants for processing of wastes of armored cable; may be used at works of secondary metallurgy in recovery of nonferrous metals. SUBSTANCE: method includes successive crushing, transportation of mixture of fragments of conductors, polymer insulation and cloth sheath for separation, separation and cleaning of materials after separation. Method is distinguished by the fact that cable is cut into fragments of preset length and transportation of cable fragments prior to crushing, magnetic separation of parts of armor and their removal. Crushing of cable fragments is carried out by their supply vertically from top to bottom with simultaneous hammering of cable fragments in direction perpendicular to direction of supply. Separation of mixture of conductor fragments, polymer insulation and cloth sheath are accomplished in ascending current of air with formation of flow of fragments of conductors, flow of fragments of polymer insulation and dust air flow with particles of cloth sheath. The plant for embodiment of the offered method includes vertical hammer crusher, separator of mixture of fragments of conductors, polymer insulation and cloth sheath, devices for cleaning of separated materials and device for transportation of processing products. The plant is distinguished by the fact that it is provided with device for cutting cable into fragments, magnetic separator; crushed is provided with device for supply of cable fragments from atop. Separator is made in the form of air separator provided in its upper part with expander and device for withdrawal of dust-air flow with particles of cloth sheath connected with unit for collection of dust and particles of cloth sheath, and with device for withdrawal of separated flow of fragments of polymer insulation. EFFECT: higher efficiency. 2 cl, 2 dwg

Description

 The invention relates to the processing of wastes from the production of armored cable, as well as to the processing of armored cable, already used in the national economy and spent its resource.

 The invention can be used in secondary metallurgy plants for the regeneration of non-ferrous metals.

 With the development of the production of armored cable, it is necessary to equip it with power and lighting systems for international communication lines, to carry out electric logging while drilling deep wells, etc., the issue of recycling armored cable waste arose very urgently.

 With the long-standing method of treating cable waste by firing in furnaces, a large amount of non-ferrous metal lost quality, and there was a complete loss of the polymer used in the insulation cables. In order to reuse non-ferrous metal of the current conductor, as well as polymeric material, it is necessary to use dry processing methods, i.e. Separate cables into components while maintaining their basic properties. As you know, an armored cable contains conductive conductors made of copper or aluminum, separated from each other by insulation from a polymeric material (dielectric), for example, polyvinyl chloride (PCV), a sheath, for example, from pigmented soot fabric, on top of insulated conductive conductors, and armor (protective cover), for example, from steel tapes. Such a cable during crushing by the dry method is crushed, crushed, and then separated into its components by physical methods (magnetic and air separation, screening, etc.) It cannot be denied that dry cable processing is difficult, energy and capital intensive, but obtaining, with the least loss, recyclable materials of which the cable is made, pays a lot for these costs. And the creators of advanced technologies and equipment for dry processing of armored cable waste are aimed at reducing the labor, energy and capital intensity of processing while ensuring a minimum of loss of metal and polymer cable components. The proposed group of inventions is also aimed at achieving this technical result.

 Consider solutions of a similar purpose known from the prior art and analyze whether it is possible to achieve the indicated technical result when implementing known solutions in production.

 Thus, a known method of extracting metal from scrap and waste current conductors in polymer insulation, including the supply of raw materials, crushing, transportation for classification, classification for separation of fines, pneumatic separation, and crushing is carried out in air and the transportation of crushed material for classification is carried out pneumatically.

 Analysis of the known method from the point of view of the purpose that is indicated in the claims according to ed. St. USSR N 583190, showed that the sintering of crushed particles is a negative phenomenon when processing current conductors in polymer insulation when the entire mass of the processed material is crushed to a ground state, in order to obtain a mixture of metal particles and polymer insulation particles, a large amount of heat is released, which leads to sintering of small insulation particles and the formation of polymer insulation particles by mass close to or equal to the mass of the metal particles of the conductive core.

 This circumstance complicates both the classification of the specified mixture from dust and the pneumatic separation of this mixture to obtain as a final product a separate metal, a separate polymer material. That is why air is used in all technological operations and during transportation to prevent sintering and to ensure dispersion of the classified material over the cross section of the pneumatic separator. And the use of air is additional energy, capital and labor costs, and the loss of materials that make up the parts of the cable (current conductor), on the contrary, increase, because air entrainment of these materials at all stages of processing increases. Thus, in the analogue method indicated at the beginning of the description, the technical result is unattainable.

 Closest to the proposed is a well-known method for processing armored cable waste, described in the brochure of Scandinavian Recycling AB (see the appendix - copies of the brochures of the company and translation of the advertising text). The method includes pre-sorting the cable (separating a large-diameter cable from a cable with thin electronic hairs-wires), preliminary cutting of cable fragments of 20-200 mm in length, magnetic separation of steel parts and their removal, two stages of granulation of cable fragments, separation of granular material by fluidization granular material, the following deposition by vibrational movements on different sides of the sieve of metal particles and particles of polymer insulation. Metal particles of the required size are removed, the intermediate fraction is returned to the load at the beginning of the processing process, or directly to granulation. The polymer insulation is sent for classification to remove fine metal particles and metal dust by sieving the material subjected to vibrational movements. The resulting dusty air mixture is sent to a cyclone or filters to separate dust before air is released into the atmosphere. This method is adopted as a prototype.

 The advantage of this method is that it pre-sortes the cable and cuts the cable fragments of a given size, which allows to reduce energy consumption during further crushing, as well as reduce the wear of screening agents by the heavy parts of the cable.

 However, a big drawback, in our opinion, is that the cable fragments are granulated, and more than once. Firstly, this is already a large expenditure of electricity.

 Secondly, granulation is the shaping of the substance into small pieces - granules (grains), which, according to the specialists of Scandinavian Recycling AB, should improve the process of opening the cable as a multi-component product and, when crushed, form a mixture of components, in order to separate one material from another during further separation. But granulation of cable fragments into small pieces predetermines difficulties in separating, because granulation produces a large amount of crushed products of complex composition, and with further extraction of the metal of the conductive wires and polymer insulation, their mutual ablation is inevitable, i.e. loss of cable components. Therefore, in order to divide the cable into its constituent parts with the least losses for their secondary use, multiple separation of the cable granulated by this method will be required, which will result in additional energy, capital and operating costs.

 The problem arises - to destroy the cable in such a way as to slightly grind it, to simplify the separation of the fragmented cable, but at the same time to divide it into its constituent parts with the least loss.

 The inventors of the present application, a method of processing waste armored cable to achieve the specified technical result is created.

 The method includes sequentially cutting cable fragments of a given size, transporting cable fragments for crushing, magnetic separation of parts of the armor and removing them, transporting the mixture from fragments of conductive cores, polymer insulation and fabric sheath for separation, separation and cleaning of the separated materials.

 The method differs from the prototype in that the fragmentation of the cable fragments is carried out by feeding them vertically from top to bottom with simultaneous impact on the cable fragments by a blow in the direction perpendicular to the feed direction, separation of the mixture of fragments of conductive wires, polymer insulation and fabric sheath is carried out in an upward air stream with the formation of a stream fragments of conductive conductors, a stream of fragments of polymer insulation and a dusty air stream with particles of a tissue shell.

 However, it should be noted that the achievement of the above technical result is possible only when implementing the proposed method on the installation, which is the object of the invention according to this application.

 The patented method and installation are a group of inventions united by a single inventive concept, namely: to process waste armored cable efficiently both technically and economically, i.e. to extract from the recycled cable its components suitable for secondary use with minimal losses while reducing energy, capital and operating costs.

 By the way, as a prototype of the proposed method and installation, a group of solutions was also adopted - the technology and installation for its implementation, which follows from the advertising text of the company "Scandinavian Recycling AB".

 The need to solve the problem of highly efficient processing of cable reservation waste is due to the improvement by the authors of this application of known installations by creating a new installation for implementing the proposed method. This concludes a single inventive concept involving the sharing of inventions.

 An analogue of the claimed installation is a production line for extracting metal from scrap and waste current conductors in polymer insulation (see ed. St. USSR N 583190, class C 22 V 7/00, 1972), including a sequentially located feeder for supplying raw materials, crusher, conveyor, classifier for separating small things, paddle batcher, pneumatic separator with fan and control system. At the same time, a conveyor belt is installed in the line as a conveyor, inclined horizontally, connected with a fan at one end and with a classifier at the other end, the dispenser is installed in the middle part of the air separator and its blades are equipped with elastic elements, and the fan is equipped with an additional nozzle connected to the crusher cavity .

 A disadvantage of the known line is that all its equipment and connections between the individual types of equipment are aimed at working with material that is highly ground in the crusher, which will have sintered particles of polymer insulation as a result of grinding. To eliminate this negative phenomenon, the line is designed in such a way that all its parts are in communication with the fans, so that the air flow does not allow the insulation particles to sinter with each other, but this, in turn, will lead to an increase in energy and capital costs. Further, due to the fact that the crusher provides for strong grinding, difficulties arise in highly efficient separation, and losses of polymer current conductors with polymer particles and vice versa are inevitable. This entails the installation of additional separating devices, and, consequently, an increase in energy, capital and operating costs, which indicates the impossibility of implementing the inventive method of processing waste armored cable in this known line.

 Closest to the claimed is a cable waste recycling plant created by Scandinavian Recycling AB (see the appendix - copies of the company's brochure and translation of the advertising text).

 The installation includes a sorting unit for various types of cables, a device for cutting fragments of an armored cable of a given size, a crusher (granulators), a magnetic separator, a separator of a mixture of granular metal conductive conductors, polymer insulation and sheath, a device for cleaning (classifier) of separated materials and a device for transporting products processing.

 This installation is more advanced in comparison with the line by ed. St. USSR N 583190, i.e. a cable sorting unit and a device for cutting cable fragments are introduced into it, which eliminates the joint crushing of its various types both in size and component parts, and also reduces the energy cost of separating particles of ground cable and electric wires of different composition and density, eliminates wear by heavy cable parts of separation devices suitable for processing only electric wires.

However, the known installation has serious structural disadvantages:
- the presence of two granulators, each of which is made in the form of a horizontally located rotor with knives and small gaps between the rotor and the knife, will already cause a strong shredding of the cable, or rather its components;
- the supply of granulator sieves with a certain size of the holes involves the circulation of crushed cable materials in the drum of the granulator and the repeated exposure of the knives of the granulator to the already crushed materials, which will result in regrinding of the materials that make up the cable;
- twice granular materials, and even crushed due to circulation, will complicate the work of the separator for the separation of the crushed mixture by type of material;
- repeated granulation will cause sintering of polymer insulation particles among themselves, and this can lead to equality of masses of metal particles of conductive veins of baked particles of polymer insulation and, upon further separation, polymer specimen, and metal particles will be unloaded into one hopper, i.e. separation will not take place, or it will be ineffective, which will lead to loss of recoverable materials and to an increase in the number of separators, which means an increase in energy, capital and operating costs;
- the separators used in the installation do not allow highly efficient separation of heavily shredded cable into components, because particles of metal of conductive veins and sintered particles of polymer insulation can pass through the sieve openings due to the equality of their geometrical sizes, and a slight difference in their masses will not allow the oscillatory movements of the separator to precipitate them on different sides of the separator.

 All of the above circumstances predetermine the impossibility of using the armored cable production facilities for waste processing and led the authors to create such a technology and such an installation that, if used together, would make it possible to obtain separated cable components with the least loss and processing cost. The specified advantages have the claimed installation.

 It contains a device for cutting cable fragments, a crusher, a magnetic separator, a separator of a mixture of fragments of conductive conductors, polymer insulation and a fabric sheath, a device for cleaning the separated materials and a device for transporting processed products.

 The installation differs from the prototype installation in that the crusher is made in the form of a vertical hammer crusher with a device for feeding fragments from above, the separator is in the form of an air separator equipped with an expander installed in its upper part with a device for removing dust and air flow with particles of the fabric membrane communicated with the assembly collecting dust and particles of tissue membrane, and with a device for removing the separated stream of fragments of polymer insulation.

 The inventive method and installation meet all criteria of patentability.

 They are new, because they are unknown from the prior art, as evidenced by the above analysis of known methods (according to ed. St. USSR N 583190 and from advertising materials of the company "Scandinavian Recycling AB").

 The inventions proposed for patent examination have an inventive step, because they do not explicitly follow from the prior art for a specialist, i.e. from the prior art, no solutions having signs matching the distinguishing features of the claimed solutions have been identified, and therefore, the influence of the distinctive features on the technical result indicated by the applicant has not been confirmed.

 The claimed group of inventions meets the requirement of industrial applicability. Nothing in the method and installation does not contradict the possibility of their implementation in industry, each operation of the method and each design feature of the installation are feasible and reproducible; neither the operation of the method nor the design features of the installation impede the achievement of the technical result perceived by the applicant.

 Confirmation of this is the description of the installation in statics below and a specific example of the method when describing the operation of the installation.

 In FIG. 1 is a general installation diagram; in FIG. 2 - section AA on an enlarged scale.

 Installation for processing waste armored cable contains a device 1 for cutting cable fragments 2 - rotary guillotine, device 3 for transporting cable fragments; crusher 4, made in the form of a vertical hammer crusher with working bodies (hammers) 5, mounted perpendicular to the vertical shaft 6, with a device 7 for feeding cable fragments from above to the crusher 4 and with a device 8 for unloading 4 particles of armor, fragments of conductive veins from the crusher , fragments of polymer insulation and particles of tissue membrane; suspended magnetic separator 9 and drum magnetic separator 10; devices 11 and 12 for transporting cable components and a device 13 for transporting a mixture of fragments of conductive conductors, fragments of polymer insulation and parts of a fabric sheath; an air separator 14 provided with an expander 15 mounted in its upper part with a device 16 for removing dust and air flow with particles of a fabric membrane in communication with a collection unit, for example, cyclone 17, dust and particles of a fabric membrane, and with a device 18 for removing a stream of polymer insulation fragments and for the removal of the flow of fragments of conductive conductors in the lower part of the air separator 14 is a device 19, in addition, the air separator is equipped with a device 20 for supplying a mixture of fragments of conductive conductors, fragment comrade polymeric insulation and tissue shell particles; a device for cleaning particles of steel armor of the separated fragments in the form of a screen 21, where the fragments are transported by the device 22 and the magnetic separator 23, under which there are containers 24 and 25 for receiving, respectively, steel dust and fragments of conductive veins; a device for cleaning dust from a separated stream of polymer insulation fragments in the form of a screen 26 and a magnetic separator 27, under which containers 28 and 29 are located, respectively, for steel particles and for polymer insulation fragments. The screen 21 can be equipped with another screen 30, the cavity of which is communicated with the oversize space of the screen 21, the sub-sieve space being communicated with the device 7 of the crusher 4, and the oversize space is connected with the device 1. Above the crushers 4 are loading bins 31 with belt feeders 32. A container 33 is installed under the magnetic separator 9, and a container 34 under the magnetic separator 10, and a container 35 under the cyclone 17.

 The implementation of the method and the operation of the installation is as follows.

 The armored cable is fed into the rotary guillotine 1, with which cable fragments are cut to a size of not more than 40 mm, which must be observed for the crusher to work effectively 4. Cable fragments are transported by device 3 to the bunkers 31, from where the cable fragments are fed vertically from top to bottom through tape feeders 32 through device 7 into a vertical hammer mill 4. When moving from top to bottom, the fragments experience the impact of the hammers 5 rotating on the shaft 6 in the direction perpendicular to the feed direction of the fr gmentov, whereby steel armor shell flies and tissue fragments with a cable portion and fragments of conductors equal to the size of fragments of the cable after the cutting off from the polymeric insulation fragments also equal sized fragments of the cable. All cable components through the device 8 are discharged to the device 11. When the mixture of cable materials passes under the magnetic separator 9, the steel parts are separated and loaded into the container 33, and the remaining mixture enters the device 12, is transferred from it to the drum magnetic separator 10 for additional extraction of steel parts of the cable armor and unloading them into the container 34. A mixture of fragments of conductive veins, fragments of polymer insulation and particles of tissue sheath, which is transported to stroystvo 20 of the air separator 14 where separation is produced in the rising stream of air. Under the influence of this jet, fragments of polymer insulation, particles of tissue membrane and dust are carried away by air to the upper part of the separator 14, enter the expander 15, where the speed of the jet of air decreases so that the fragments of polymer insulation stop moving up and fall down to the device 18 for removal from the separator 14, and the air with dust and particles of the tissue membrane continues to move upward and through the device 16 are sent to the cyclone 17 to collect dust and particles of tissue membrane before the air is released into the atmosphere. Fragments of conductive wires under the action of gravity move down the separator 14 to the device 19. Thus, during the separation of three separate streams due to the structural design of the separation part of the installation. The separated streams of conductive core fragments and polymer insulation fragments are supplied to separate devices for each of them to clean them of armor particles that could have formed during processing of cable fragments in the crusher 4. The stream of polymer insulation fragments enters the selective screening screen 26, into the under-sieve space which receives particles of steel armor, and fragments of polymer insulation remain in the oversize space. They again pass through the drum magnetic separator 27, where they are cleaned of steel particles. These particles and fragments of polymer insulation are unloaded into containers, respectively, 27 and 28. The stream of fragments of conductive veins from the device 19 enters the device 22, which fragments are fed for selective screening in the screen 21.

 The lattice in the screen 21 is made in such a way that fragments of conductive conductors fall through its openings into the under-lattice space, and fragments of conductive conductors in polymer insulation that fly through the whole crusher 4 without being hit by hammers 5 remain in the oversize space of the screen 21 fragments of cable, the size of which exceeded 40 mm, and therefore in the crusher 4, the blow of hammers 5 had no effect. Experimentally, the authors of this application have determined the mandatory cutting of cable fragments with a size of not more than 40 mm. It is up to this size that conductive conductors fall out of polymer insulation. The over-sieve product of the screen 21 enters the screen 30, where fragments in polymer insulation no larger than 40 mm are in the sub-sieve space, and they are returned to the crusher 4, and the over-screen product of the screen 21 - fragments of conductive conductors enters the drum magnetic separator 23, where it is cleaned from steel particles, and then steel particles and fragments of conductive conductors are discharged into containers 24 and 25, respectively.

 Thus, in the inventive installation by the claimed method eliminates overgrinding in the waste crusher of the armored cable, which creates favorable conditions for the separation of the destroyed cable to highlight its components while minimizing losses and eliminating additional separation, which means that energy, capital and operating costs will not be enlarged.

Claims (2)

 1. A method of processing waste armored cable, including sequentially crushing, transporting a mixture of fragments of conductive cores, polymer insulation and fabric sheath for separation, separation and cleaning of the separated materials, characterized in that they cut cable fragments of a given size and transport cable fragments before crushing, magnetic separation of parts of the armor and their removal, crushing of cable fragments is carried out by feeding them vertically from top to bottom with simultaneous impact viem into fragments cable stroke in a direction perpendicular to the feeding direction, separation of the mixture of fragments of conductors, insulation, and a polymeric shell fabric is produced in an ascending air stream to form a stream of fragments of conductors, the flow of polymer insulation fragments and dust-air flow with a fabric shell particles.  2. Installation for processing waste armored cable containing a vertical hammer mill, a separator of a mixture of fragments of conductive cores, polymer insulation and fabric sheath, a device for cleaning the separated materials and a device for transporting processed products, characterized in that it is equipped with a device for cutting cable fragments, magnetic separator, the crusher is made with a device for feeding cable fragments from above, the separator is made in the form of an air separator equipped with installed in its upper part with an expander with a device for the removal of dust and air flow with particles of tissue membrane, in communication with the unit for collecting dust and particles of tissue membrane, and with a device for removal of the separated stream of fragments of polymer insulation.

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