RU2055898C1 - Process of working of skin and fur raw materials and gear for its implementation - Google Patents

Abstract

FIELD: leather and fur industry. SUBSTANCE: one edge of skin is fixed rigidly. Free and of skin is thrown over working tool to create forces formed by weight of skin and by interaction of skin with working tool. Proposed gear has means for rigid fixation of skin edge mounted on table for skin laying. EFFECT: expanded application field, simplified design. 6 cl, 4 dwg, 1 tbl

Description

 The invention relates to the leather and fur industry, and in particular to methods of machining leather and fur raw materials and machine designs for their implementation.

 A known method of mechanical processing of leather and fur raw materials, which consists in placing the skin in front of the working body, feeding the skin into the treatment area and then exposing it to the working body to carry out coiling, breaking, stretching, hair removal and combing. A device for implementing the proposed method comprises supports mounted on a bed with a working body made in the form of a cylindrical core with helical knives multidirectional from the center to the periphery, kinematically connected to the drive, and a skin-laying table parallel to the axis of the cylindrical core (aut. N 1588766, class C 14 B 15/00, 1987).

 The technical result of the invention is to improve the quality of leather and fur raw materials and the simplification of processing technology.

 In FIG. 1 shows an assembly for processing an assembly; in FIG. 2 screw knife; in FIG. 3, 4 the same options.

 The device comprises a bed 1 with a knife shaft 3 mounted on it on the supports 2. The knife shaft is connected to the electric drive 4. In parallel with the axis of the knife shaft 3, there is a table for laying skins 5, the edge of which together with the stop 6 form a rigid fixation device, which is actuated pedal 7, and the clamping force is created by the spring 8.

 The device operates as follows.

In the coiling operation, the edge of the skin is rigidly fixed parallel to the axis of the knife shaft 3, and its free portion is thrown with the edge on the knife shaft. Under the influence of its own weight skin fits cutter shaft and is formed in the contact angle of the blade meet with the treated surface, the size ^of which is less than 90, which provides a shear stress at the blade edge necessary to remove the layer of hide. In this case, under the action of shear stresses at the edges of the knives during processing, the skin is pulled onto the knife shaft, which ensures a certain force of pressing it against the knife shaft. Since the skin tissue has more elastic properties than the skin tissue, after removing the mezra from any area, the knife begins to make an idle passage as it passes, since the shear force at the edge of the knife is not enough to damage the skin tissue, while continuing to remove the skin from the remaining plots. The proposed method allows to exclude damage to the skin tissue even in the presence of its defects in the form of fistulas, all kinds of scars that occur during the life of an animal from insect bites or other intravital injuries. In the process of coiling, the skin is stretched in the longitudinal-transverse direction over the entire cultivated area, under the influence of knives, high-frequency movement of some of its sections relative to others occurs, as well as frictional heating. As a result, along with the removal of the medial layer, the collagen fibers of the skin tissue are loosened, which facilitates the removal of fats from the interfiber space, which become more mobile with increasing temperature. This facilitates the diffusion into the thickness of the skin tissue of reagents (acids, tanning agents) during the chemical treatment of the hide and provides an improvement in the quality of the leather-fur semi-finished product.

 Coating according to the proposed method does not require additional preparation in the form of preliminary hair cutting to a certain length or adjustment of equipment from a batch of raw materials to a batch. The method allows, without any difficulties, to mend the skins of deer and reindeer, which ensures the hair is rolled with gold and, accordingly, the receipt of high-quality leather semi-finished products from them, which significantly expands the raw material base of the leather industry.

 The operation of breaking and stretching is carried out similarly to the operation of coiling. In the process of breaking and stretching, the skin tissue is cleansed of the remnants of the mezra, various roughnesses that have arisen during the chemical treatment are eliminated, the semi-finished product in contact with the knife shaft is subjected to high-frequency dynamic action of the knives, which ensures effective loosening of the collagen fibers of the knife tissue and its simultaneous stretching in the longitudinal-transverse direction. Since the breakdown and stretching are carried out simultaneously over a large area and under the influence of frictional heating, the efficiency of the process increases, the semi-finished product is obtained in the form of an even layer, which eliminates the operation of ironing during finishing.

 In the operations of hair removal and combing, the edge of the skin is rigidly fixed parallel to the axis of the knife shaft 3 and the free area of the skin is thrown onto the knife shaft to the top with the hair side. Under the influence of its own weight, the skin fits the knife shaft, and under the action of the shear stress arising from the interaction of the knives with the hair, it is pulled onto the knife shaft, which achieves the necessary interaction force. In this case, the skin of the skin under the influence of shock loads is cleaned of burrs and dirt, adhering and tangled hairs are separated. As the skin is cleaned and combed, the knives get deeper penetration into it, resulting in an increase in the shear stress pulling the skin on the knife shaft and, accordingly, the interaction between the knives and the hairline increases. Thus, the possibility of dehairing heavily contaminated and fallen areas of the hairline is excluded.

 The operation of combing hair is similar to the operation of hair removal. The skin during the operations of coiling, breaking and stretching is placed on the table with the 5 main side up, and during the operations of cleaning and scratching the hair and the main side down. Then press the pedal 7, the edge of the skin is placed between the edge of the table and the emphasis 6, and then lower the pedal, thereby rigidly fixing the edge of the skin. A free area of the skin is thrown onto the knife shaft 3, the electric drive 4 is turned on. The knife shaft, rotating, acts on the surface of the processed skin. After processing, the electric drive is turned off, after the knife shaft stops, the skin is removed. By depressing the pedal 7, the fixation is removed, the skin is unfurled, placing its processed edge between the edge of the table and emphasis 6. The operation is repeated. It should be noted that to compensate for the wear of the knives of the knife shaft, as well as when switching from one size of the processed skins to another, if necessary, adjust the relative position of the table 5 and the knife shaft 3 by moving them in the supports.

For the operation fleshing blade shaft 3 of the apparatus for machining leather and fur materials is a cylindrical core with placed thereon in different directions from the center to the periphery of the screw blades, the lead angle ^of which is 15-30, and the angle of the blade meet with the treated surface skins 80 -85 ^about .

 In FIG. 2 schematically shows a knife shaft for crap.

Angle of lifting blades 15-30 ^of conditions caused by their operation: the angle of lift less than ^about 15 there is a chance a cut leather fabric, while increasing the angle ^of rise above 30 lose their ability to trim knives mezdryanuyu tissue due to blockage of the cutting edges are already separated tissue fragments mezdrovogo as a result of which productivity and quality of processing are sharply reduced. The angle of the blade meet with the treated surface immediately knit diameter cutterblock and the distance between the knives: angle increases, approaching ⁹⁰ °, with decreasing distance between knives: distance between the blades depending on the diameter of the cutter shaft, the angle of blade lift and the angle between the treated the surface is determined by the relation l = P · Cos α · Sin β, (1) where l is the distance between the knives,
D the diameter of the blade shaft,
β angle to the raises of the knives,
α the angle of the knife with the work surface. When reducing the angle between ^about 80 below the shear stress on the knife edge increases above the permissible which leads to gusts of the leather, while increasing above ^about 85 decreases and becomes insufficient to remove the flesh side.

For the operation breakdown and stretching leather and fur skins blade shaft device (FIG. 3) is a cylindrical core with placed thereon in different directions from the center to the periphery of the screw blades 2, pitch angle β which is ^about 30-60, and the meeting angle with the processed surface of 70-80 ^about .

Angle of lifting knives driven by the conditions of their work: if the angle lifting least 30 ^about becomes possible to cut the leather and stretch the leather and fur skins occurs primarily in the longitudinal direction, while increasing the angle of rise of over ⁶⁰ blades lose their ability erasures leather fabric from residues hems and various kinds of roughness that arose during the chemical treatment, and the semi-finished product undergoes stretching mainly in the transverse direction.

The angle of the knife with the processed surface depends on the thickness of the leather fabric of the processed semi-finished product for large thicknesses (skins of cattle, deer, reindeer) 70-75 ^o and for the average thickness (skins of sheep, calves) 75-80 ^o . When reducing the angle between the least value of the tangent 70 ^of the shear stress increases so that the gap can cause the leather treated semi-finished product, while increasing the angle in excess of ⁸⁰ tangential stress becomes insufficient, which significantly reduces the productivity and processing quality.

For carrying out hair removal and scratching operations, the knife shaft of the device (Fig. 4) is made in the form of a cylindrical core with screw knives 2 arranged in different directions from the center to the periphery, the elevation angle β of which is predominantly 45 ^° , and the angle of encounter with the treated surface is 75-80 ^o, wherein the constant cross-section blades alternate with toothed, the teeth of which are formed by dividing the transverse knife blade notches in portions of constant cross section, its thickness is equal to 3-5, and their reversal parallel to the transverse axis of the blade wa a.

The angle of rise of the knives is determined by the conditions of their work, the serrated knife performs combing and styling of hair parallel to the transverse axis of the knife shaft, the next knife of constant cross section, dynamically acting on the hair, fluffs it and puts it at an angle to the transverse axis of the knife shaft, corresponding to the angle of the knife. This process is repeated many times. With an increase in the angle of rise of the knives, the angle between the direction of hair styling and the transverse axis of the knife shaft increases, and accordingly the angle at which the hair interacts with the teeth of the knife. Excessive increase in this angle causes the teeth to become wrinkled, resulting in the hair being cut off or torn out of the skin tissue, while when the angle is excessively reduced, the teeth glide along the hair, interacting weakly with it, which reduces the quality of processing. Optimum is the angle of rise of the knives, close to 45 ^about . The angle of the knife with the surface to be treated determines the magnitude of the tangential stress that occurs when the knife interacts with the skin of the skin, under the influence of which it is stretched on the knife shaft. By increasing the angle between the excess value ⁸⁰ the value of the tangential stress becomes insufficient, resulting in decreased productivity and quality of treatment, and at decreasing angle less than the magnitude 75 ^of the shear stress becomes excessive, whereby the blades are immersed in the thickness of the hair is not in layers as carding , and immediately to the entire depth, which leads to dehairing of the skin with a fallen hair. The inventive interval of the angle of contact of the knives with the processed surface of 75-80 ^about is optimal.

 The shape of the teeth of the serrated knife on the one hand provides the process of heavily fallen parts of the hairline, and on the other hand, effectively removes burrs and dirt. Burdocks and large particles of dirt are removed when they fall between the teeth, and the hair is cleaned directly by contact with three edges of the tooth during combing. The width of the tooth, corresponding to 3-5 thicknesses, provides when combing the ironing of the tangled hair, its straightening and prevents tangling of the hair after the passage of the tooth. Reducing the width of the tooth reduces the effectiveness of scratching, and increasing its thickness over 5 thicknesses does not produce an additional effect, but increases the processing time, since the serrated knife becomes too rare.

 Thus, the claimed design of a device for machining leather and fur raw materials with the proposed set of interchangeable knife shafts is universal and allows you to perform operations of harvesting, fouling, breaking and stretching, carding hair.

 The invention is illustrated by the following examples of specific performance.

PRI me R 1. Sheepskin dried salted canning method is subjected to the harvesting. The repyurubki, like all subsequent operations, is carried out on a universal device for machining leather and fur raw materials of the claimed design. The skin is placed on the table with the fur up, the edge of the skin is fixed in a rigid fixation device, after which a free section of it is thrown onto the knife shaft, the electric drive is launched. The processing is carried out by rotating the knife shaft at a speed of 360-400 rpm for 15-20 s, after which the electric drive is turned off, the skin edges are locked, the treated edge is fixed, and the process is repeated. The blade shaft for the harvesting is made in the form of a cylindrical core with a diameter of 320 mm and a length of 1500 mm, on which are fixed multidirectional screw knives 50 mm high from its center to the periphery, i.e. the diameter of the blade shaft corresponds to 400 mm. The angle of elevation of the knives is 45 ^° , the angle of their meeting with the work surface is 78 ^° , the distance between the knives is 95 mm. Knives of constant cross section alternate with serrated, teeth are formed by cutting a blade of a knife of constant cross section to half its height into sections equal to 4 knife thicknesses, i.e. 12 mm (knife thickness 3 mm) and their subsequent rotation parallel to the transverse axis of the knife shaft.

 After the re-harvesting of the skins, they are soaked using the well-known technology, squeezed out and fed to the coiling operation.

 The skin is placed on the table with the side face upward, the edge of the skin is fixed in a rigid fixation device, its free area is thrown onto the knife shaft, and then the electric drive is started. The processing is carried out by rotating the knife shaft at a speed of 360-400 rpm for 10-15 seconds, after which the drive is turned off, the skin is removed from the knife shaft, the skin edges are locked, its processed edge is fixed, and the process is repeated.

Cutterblock for fleshing is in the form of a cylindrical mandrel of 320 mm diameter and 1500 mm in length, which are fixed divergent from its center to the periphery of the screw blades 40 mm (diameter of the cutterblock corresponds to 400 mm. The angle of lifting blades is ²⁰ °, angle of impact with the treated surface 82 ^about , the distance between the knives 60 mm).

 After the surgery, the skin is subjected to chemical treatment according to known technology, dried and fed to the operation of breaking and stretching.

 The skin is placed on the table with the skin side up, the edge of the skin is fixed with a rigid fixation device, its free area is thrown onto the knife shaft, and then the electric drive is started. Processing is carried out at a rotation speed of the knife shaft of 360-400 rpm, for 15-20 s, after which the drive is turned off, the fixing is removed, the skin is removed from the knife shaft, its processed edge is fixed, and the process is repeated.

The blade shaft for breaking and stretching is made in the form of a cylindrical core with a diameter of 320 mm and a length of 1500 mm, on which are fixed multidirectional screw knives 40 mm high from its center to the periphery, i.e. the diameter of the blade shaft is 400 mm. The angle of elevation of the knives is 45 ^° , the angle of meeting with the work surface is 75 ^° , the distance between the knives is 100 mm.

 After breaking and stretching, the hair is scratched. The scratching operation is carried out similarly to the harvesting operation using a similar knife shaft. It should be especially noted that the operation of the harvesting can be carried out with equal success both on dry skin and on the skin that has passed soaking, which is one of the advantages of the proposed method and device for its implementation. Carrying out the cleaning before soaking can significantly reduce water consumption and wastewater pollution.

 When processing the skin on any of the described operations, the edges of the skin, and especially its parts taken off its feet, can "clap" on the knife shaft, as a result of which the quality of their processing is reduced. To eliminate this, the "clapping" sections of the skin are pressed against the knife shaft by a wooden rule during processing.

 To identify the impact of the proposed method of mechanical processing of leather and fur raw materials (compared with the known) on the quality of the finished product at the Novosibirsk leather and fur factory, comparative tests were carried out when dressing a fur sheepskin. Fifty skins of sheep were cut along the ridge line, each half of the skin was numbered and became part of one of the two parties. When making the first batch, industrial technology was used using known methods of mechanical and chemical processing of raw materials. In particular, mezdrenie was carried out on the MMP-1800-K mezdrilny machine, breakdown and stretching on the TMM-2 machine. When dressing a second batch of fur sheepskin, mechanical processing was carried out using the proposed method, as shown in example 1, and chemical processing was carried out by known methods similar to processing the first batch.

 The average results of comparative tests are given in the table.

 The increase in the weldability temperature and the tensile strength of the fur sheepskin, made using the proposed method, is obviously due to the higher quality of the coiling of the feedstock. In the process of coiling, the skin is stretched in the longitudinal-transverse direction along the entire surface to be treated, under the action of the knives, high-frequency movement of some of its sections relative to others occurs, accompanied by frictional heating. As a result of dressing with the removal of the mezra, the collagen fibers of the skin tissue are loosened, which facilitates the removal of fats from the interfiber space, the mobility of which increases with increasing temperature. This facilitates the diffusion into the thickness of the skin tissue of the reagents during the chemical treatment of the skin and provides an increase in the quality of the finished semi-finished product.

 The increase in the yield of the finished semi-finished product is explained by the absence of marriage during cure and high quality breakdown and stretching.

 The use of the proposed method for the mechanical processing of leather and fur raw materials and a device for its implementation in the preparation of deer skin on the skin using known methods ensured that the hair was subjected to gold stripping and a leather semi-finished product was obtained that complies with the state standard.

Thus, the proposed method of machining leather and fur raw materials and a device for its implementation allow to obtain the following technical result:
to simplify the technology of mechanical processing of leather and fur raw materials;
to improve the quality of the finished leather and fur semi-finished product;
expand the raw material base of the leather industry;
to simplify and unify the equipment for machining leather-mechanical raw materials.

 The invention can be used in the leather and fur industry.

Claims (5)

 1. The method of mechanical processing of leather and fur raw materials, which consists in placing the skin in front of the working body, feeding the skin into the treatment area and then exposing it to the working body for hair cobbling, breaking, stretching, re-cleaning and combing, characterized in that the placement is carried out rigid fixation of one edge of the skin, when feeding, the free end of the skin is thrown onto the working body to generate forces from the weight of the skin and from friction during the interaction of the skin with the working body, The action working body for fleshing, staking and stretching is carried out from the inner side, and repeuborku and combing hair - by the fur, wherein after exposure to the working body on the free end of the rigid fixation hides is carried out for the last previous skin treatment region.  2. A device for machining leather and fur raw materials, containing supports mounted on the bed with a working body made in the form of a cylindrical core with screw knives multidirectional from the center to the periphery, kinematically connected to the drive, and a skin-laying table parallel to the axis of the cylindrical core, characterized in that it comprises a means for rigidly fixing the edges of the skin mounted on a table for folding the skin, wherein the table has a hard fixation means and a cylindrical core mounted for parallel movement relative to one another in the horizontal and vertical planes. 3. The device according to claim 2, characterized in that the angle of elevation of the helical knives for coppering is 15 - 30 ^o to ensure the possibility of formation of the angle of meeting of the knife with the surface of the skin, equal to 80 - 85 ^o . 4. The device according to claim 2, characterized in that the angle of elevation of the screw knives for breaking and stretching is 30 - 60 ^o to ensure the possibility of formation of the angle of meeting of the knife with the surface of the skin, equal to 70 - 80 ^o . 5. The device according to claim 2, characterized in that the angle of elevation of the screw knives for hair removal and combing of hair is 45 ^o to ensure the possibility of formation of the angle of meeting of the knife with the surface of the skin, equal to 75 - 80 ^o , and the screw knives contain alternating knives of constant sections and gears, developed parallel to the transverse axis of the cylindrical core.

Images