RU2309849C2 - Apparatus for guiding piston motion in housing of machines designed for pressing waste materials - Google Patents

Abstract

FIELD: pressing machines designed for pressing waste materials.

SUBSTANCE: apparatus includes housing with chamber open at least at one side or at both end sides. Piston is arranged in said chamber. Axial line of piston is arranged along horizontal axial line of said chamber. Piston is mounted with possibility of motion along central axis of housing relative to wall of chamber. In order to keep uniform gap, guiding members are mounted randomly or randomly and at arbitrary order. Guiding members are in the form of sliding guides with controlled and changeable supporting shoes whose axial line is normal relative to axial line of piston.

EFFECT: possibility for changing worn parts without dismounting pressing machine, increased useful life period of machine.

32 cl, 5 dwg, 3 ex

Description

The piston in the housing of pressing machines designed for pressing waste materials is located on the guide, while an open internal common space is formed in the housing on one or both side surfaces, where the piston is placed, the axial line of which approximately coincides with the vertical axial line of this space. For uniform air gap in the chamber wall, guide units are installed that form sliding guides with adjustable and replaceable support shoes in the form of a geometric body having a vertical axial line on the axial line of the piston. This means that the support shoes (9) are located in the wall of the chamber (2) randomly and / or in random order.

Pressing machines designed to flatten materials have long been known. For example, for the application of coal dust arising in the process of coal mining and processing, loose pulverized coal is used in briquettes. During this workflow, the result of a three-fold reduction in the starting material is a solid.

For a long time, to facilitate storage, the waste is pressed, for example, scrap vehicles, which significantly reduces the storage area. These pressing machines compress the waste by moving in the opposite direction two parallel pressing plates. Thus, the flattening of the scrap leads to a decrease in its size.

The third version of pressing machines for pressing loose waste is to halve the initial volume. First, the material is pressed across, then cut into pieces. For such machines, loose material is delivered in a cylinder, then a slider or piston located on one of the ends of the press cylinder moving forward into a space with a smaller longitudinal section reduces the material volume by half. Flattened and cut into pieces material coming out of the installation is exported or stored.

In recent decades, the storage and disposal of industrial or municipal waste and environmental pollution has become a big problem due to the rapid growth of industrial production.

The pressing of municipal waste occurs with the help of the aforementioned halving of the initial volume. In such machines, waste is fed into the cylinder by gravity and a piston or slider compresses loose debris using a constriction at the end of the cylinder. Then a cylinder with a small cross section pushes the flattened material into the hole. The movement of the piston in the cylinder is carried out by an electric motor equipped with a lead screw. This method is used, for example, in US patent No. 3604345.

In another press machine described in US Pat. No. 4,269,115, the loose waste entering the cylinder is cut using special blades located on the upper edge of the end face of the piston. These blades are positioned in such a way that the waste stream coming from the loading funnel can be interrupted, but small particles cannot be excluded between the piston and the cylinder, which can interfere with the piston.

Garbage is mainly loose material, which is sorted in several places, which is associated with its possible further processing and recycling. The garbage is not homogeneous, therefore, during pressing in a compression piston machine, its density changes. During the movement of the piston, the force on the surface of the piston of the end face is distributed unevenly and the additional force changes the scope and direction. Those. In different places between the piston wall and the cylinder wall, different forces work, which can lead to an expansion of the gap and a stop of the piston due to debris entering the gap.

To reduce or eliminate the above-mentioned undesirable phenomena, it was proposed to install guides in the direction of the generatrix of the cylinder to the side surface of the piston and cylinder, which can prevent friction between the piston wall and the cylinder wall and make the intermediate gap uniform. With this solution, only the guides are subject to wear, which, when the wear reaches the maximum level, must be replaced, since otherwise the piston and cylinder will be damaged.

To address these shortcomings, in the already mentioned US Pat. No. 4,269,115, it was proposed to additionally place sliding guides on the side surface of the piston used for pressing garbage, where along the entire length of the side surface of the cylinder there are tracks with a profile necessary for uniform piston stroke. These tracks are fastened with bolts not only to the inner wall of the cylinder, but also to the axes with a radial direction that pass through its wall. So, in case of wear, you can rearrange the tracks in the radial direction by tightening the fixing nuts, i.e. the gap decreasing due to wear can be set to its original size.

This design of the guides is without a doubt a good solution for the guides used earlier, but the movement of the tracks and the guides led to wear of the components moving along each other, and this drawback can be eliminated only by replacing the worn parts, for which it is necessary to dismantle the whole machine. This is associated with significant costs, because The dismantling of the press machine cannot be carried out on site. Changes must be made at several points of the piston, since the guides are located along two or more surfaces of the cylinder and are located at an equal distance from each other. If the cause of wear is abrasive residues falling between the two rails in the air gap, then retrofitting may be difficult. Another disadvantage of this method is that the rearrangement of tracks at one point causes a proportional displacement of the tracks in other parts, or large costs may be required to displace other tracks, and later bending forces may occur on tracks that make it difficult to shift tracks at other points.

It is known from experience that, on die-cutting or deformation pressing machines, when the direction of movement is along, smaller force moments arise and the piston path becomes much shorter than on pressing machines designed for pressing waste. Such a deformation machine was mentioned in European Patent No. 0360875 A1.

In this method, the guide of the moving slider is used, which is located on the guiding units going through the wall, the axial line of which coincides with the vertical line of the slider during vertical movement. The number of guide units parallel to the direction of travel is at least two on each side of the slider. The slider during the movement of the piston occupies all the guide units.

This method cannot be applied on pressing machines used for pressing waste, since the slider (piston), due to the sufficiently long lifting length between both end positions, everywhere requires a guide that supports the slider during its movement against the action of forces arising randomly and having a magnitude and direction that cannot be calculated in advance.

The objective of the invention is to eliminate the disadvantages of the already mentioned methods while maintaining their advantages and the creation of a method that, in case of wear, will allow the replacement of worn parts at the place of use without dismantling the pressing machine and thus significantly extend the life of the machine.

The basis of the invention is the knowledge that the sliding guide between the piston and the inner surface of the cylinder is formed not by a two-dimensional guide directed to the housing, but by support shoes moving from point to point through the housing wall in the radial direction. Support shoes, on the one hand, can be installed at any point on the inner surface of the cylinder of the housing, i.e. these points do not have to be along the generatrix, which eliminates the need for tracks. On the other hand, all support shoes are additionally installed independently of each other, i.e. support shoes do not cause pinching.

The essence of this invention is that the support shoes are located in the wall randomly and / or in any order.

A piston is a cylinder with a section in the form of a circle, ellipse or polygon (quadrangle, hexagon, etc.), for example, a slider, the generators of which are arranged vertically in a transverse section. A cylindrical body is a body with a passageway, and the shape and dimensions of the inner space of the said piston correspond to the shape and dimensions of the piston so that the piston is positioned with a gap to the wall of the inner space of the cylindrical body and can move in the direction of its own axial line.

The designation "equal axial line" means in this description that all axial lines (axes) do not necessarily coincide, but can deviate slightly from each other, go parallel to each other, or form a small angle.

“Horizontal center line or axis” means that small deviations from the horizontal position do not interfere with the operation of the press machine based on the present invention.

The total area of a cylinder is understood to mean the area whose curve forms a circle, ellipse, triangle, quadrangle or polygon and which is performed using a parallel movement of one vertical line (generatrix) along the moving curve at the level of the moving curve.

The invention is described in more detail in the examples reflected in the drawings, while FIG. 1 shows an example of the arrangement of rails made according to this invention and equipped with shoes on the outer wall of the housing, a view from the side of the housing, in FIG. 2 - a pressing machine shown in FIG. 1, shown in section, figure 3 - the design of the rail made according to this invention and equipped with support shoes along the axial line of the housing or the guide structure, is presented in section, in figure 4 - the design of the rail minutes, performed according to another embodiment of the invention and equipped with support shoes at the axial line of the housing and the guide structure, shown in section, Figure 5 shows a portion B displayed in Figure 4 with Example bonded to each other and slide bolt.

In the housing (1) of the press machine shown in FIG. 1, a chamber (2) is formed in the form of a closed cylinder with one or two open internal common cylinders on both of its side surfaces. The axis of the chamber (2) is in the horizontal plane, and a piston is located in it, adjacent to the wall with an air gap evenly distributed over the entire generatrix. That is, if the piston (3) does not have a circle section, then the section of the chamber wall (2) also does not have a circle shape, but corresponds in shape and size to the piston section (3). The movement of the piston (3) should be carried out using known control systems.

An inlet (4) is provided in the upper part of the housing (1) for introducing debris by gravity. The upper part of the casing (1) consists of a section (5) with a smaller cross-section, the shape of which coincides with the cross-section of the space (2) and is a truncated pyramid connecting the casing (1) with a section (5) or, for example, a press section (6) with a truncated cone. In the upper part, it is in contact with the inlet opening (4) of the end surface (7) of the piston (3) and is located opposite the section (6) with a cutting edge (8) intended for cutting the incoming material.

To stabilize the size of the air gap between the space wall and the piston (3), such sliding guides are used that are formed by support shoes (9) passing through the wall of the housing (1) and are connected in the generatrix of the piston (3). They have the shape of a vertical geometric body located on the axial line of the piston (3), and move in the direction of the axial line of the piston (3). The support shoes (9) are located in the direction of any generatrix of the space wall and / or in any section of the chamber (2) at the required unequal distance. That is, if one of the shoes (9) wears out faster than others due to heavy loads, you can replace the shoes (9) absolutely independently of each other.

In some places, it is advisable to carry out an orderly installation of shoes (9). For example, if one part of the shoes (9) behind the inlet (4) of the housing (1), into which the pressing material enters, is located in a certain order at a distance from the inlet (4), which allows to adjust the shoes on a vertical plane relative to the axis of the cylindrical chamber (2), then the shoes (9) form an obstacle to the material compressed by the piston (3), which may fall into the air gap between the housing (1) during the movement of the piston (3) and a piston. This method is presented in section aa of figure 1, shown in figure 2.

Obviously, it is not difficult to locate the known guide system between invented slide guides.

The equipment of the sliding guides according to the invention is discussed below with examples.

On the sliding guide, shown in figure 3, there is a support shoe (9), coinciding with the inner surface of the tube passing through the wall of the housing (1), and driven by a bolt (11), which has the same axial line as and support shoe (9). According to an example, the support shoe (9) and the inner surface of the tube (10) on its part connected with the support shoe (9) and leading to the generatrix of the support shoe form a closed cylinder. The end of the inner hole of the tube (10), remote from the piston (3), is equipped with an internal thread for installing the bolt (11). According to the arrangement in FIG. 4, the end of the bolt (11) close to the support shoe (9) is formed as a bolt (12). The diameter (section) of the bolt (12) is smaller than the diameter of the support shoe (9). The inner surface of the forming tube (10) continues in the part with a thread having a shoulder (13) with a large diameter. Bolt (11) can be screwed into this threaded part. The length of the bolt (12) and the threaded part of the tube (10) is chosen so that the support shoes (9) that are subject to wear can be lowered with the bolt (12) deeply, but so that they fulfill their function of supporting the piston (3 )

According to the example, the bolt (12) can only touch the support shoe (9), i.e. the support shoe (9) when tightening the bolt (12) to the stop will be shifted to the surface of the piston (3). The sliding guides are located below the horizontal axial level of the pressing machine, further only above the axial level, where the piston (3) in its both end positions is in the chamber (2).

In the example embodiment of FIG. 5, the end surface of the tube (10) remote from the piston (3) is closed by the wall of the tube (10) and the bolt (11) is connected to the support shoe (10) by means of a threaded hole on this end surface. In this case, it is advisable to present the bolt (11) along its entire length as a thread. The advantage of this design is that a blind hole (14) is formed with a thread on the near end surface of the support shoe (9), in which the support shoe (9) and the bolt (11) are connected using a bolt (11). That is, option B of FIG. 4, shown in FIG. 5, a sliding guide, can be used in various places above the horizontal axial level by a pressing machine, where the piston (3) does not end up in the chamber (2) at any end position.

When applying the methods shown in FIGS. 4 and 5, there are no difficulties, because the support shoe (9), similar to the piston (3), forms a common cylinder. In this case, the surface on which the support shoe (9) is located takes a shape similar to that of the support shoe (9). The surfaces of the bearing shoes (9) in contact with the piston (3) are recommended to be made of metal or plastic, preferably of a material with a lubricating effect. According to another method, it is proposed to form an opening (15) for introducing lubricants along the axial line of the bolt (11) and shoe (9) and on the head of the bolt (11) - as already known - to establish a domed reservoir for the lubricant.

Claims (32)

1. A device for guiding the movement of the piston in the housing of pressing machines designed for pressing waste materials, in the housing of which a chamber is made open from at least one or both end surfaces, in which a piston is placed, the axial line of which is located along the horizontal axial line of the chamber, this piston is arranged to move along the central axis of the housing relative to the chamber wall, to maintain uniformity of the gap in the chamber wall, guide units are installed, characterized in that the guide units are installed randomly or randomly and in random order, while they are made in the form of sliding guides with adjustable and replaceable support shoes, the axial line of which is perpendicular to the axial line of the piston. 2. The device according to claim 1, characterized in that the part of the support shoes located on the part of the housing between the inlet of the housing and the wall opposite the outlet of the pressing machine is arranged to adjust them to prevent material from entering the air chamber during operation of the piston . 3. The device according to claim 1 or 2, characterized in that the cross section of the piston has a configuration similar to the configuration formed by the inner wall of the chamber in its cross section, while the piston is installed with the formation of a uniform gap between the surface of the piston and the inner wall of the chamber. 4. The device according to claim 1 or 2, characterized in that between the mentioned sliding guides can be additional guide units. 5. The device according to claim 3, characterized in that between the mentioned sliding guides can be additional guide units. 6. The device according to any one of claims 1, 2 and 5, characterized in that the support shoes located on the sliding guides of the housing are equipped with bolts to enable movement of the shoes, and the axis of the bolts coincide with the axes of the respective shoes. 7. The device according to claim 3, characterized in that the support shoes located on the sliding guides of the housing are equipped with bolts to enable movement of the shoes, and the axis of the bolts coincide with the axes of the respective shoes. 8. The device according to claim 4, characterized in that the support shoes located on the sliding guide rails of the housing are equipped with bolts to enable movement of the shoes, and the axis of the bolts coincide with the axes of the respective shoes. 9. The device according to claim 6, characterized in that the support shoe has the shape of a cylinder, and the sliding guide is made in the form of a cylindrical tube. 10. The device according to claim 7 or 8, characterized in that the support shoe has the shape of a cylinder, and the sliding guide is made in the form of a cylindrical tube. 11. The device according to claim 6, characterized in that the end of the sliding guide tube remote from the piston is closed by a side wall with an internal threaded hole that is connected to the support shoe by means of a bolt. 12. The device according to any one of claims 7 to 9, characterized in that the end face of the sliding guide tube remote from the piston is closed by a side wall with an internal threaded hole that is connected to the support shoe by means of a bolt. 13. The device according to claim 10, characterized in that the end of the sliding guide tube remote from the piston is closed by a side wall with an internal threaded hole that is connected to the support shoe by means of a bolt. 14. The device according to claim 9, characterized in that on the inner surface of the end of the cylindrical tube remote from the piston, a thread is applied to tighten the bolt. 15. The device according to claim 10, characterized in that on the inner surface of the end of the cylindrical tube remote from the piston, a thread is applied to tighten the bolt. 16. The device according to 14 or 15, characterized in that the end of the bolt closest to the support shoe is made with a diameter larger than the inner diameter of the sliding guide tube, with the formation of a threaded part, and a protrusion is made in the inner hole of the tube. 17. The device according to 14 or 15, characterized in that on the end surface of the support shoe a blind threaded hole is made in which a bolt is screwed. 18. The device according to clause 16, characterized in that on the end surface of the support shoe a blind threaded hole is made in which a bolt is screwed. 19. The device according to any one of paragraphs.1, 2, 5, 7, 8, 9, 11, 13-15 and 18, characterized in that the surfaces of the shoes in contact with the piston are made of metal, plastic, preferably made of a material with a lubricant effect. 20. The device according to claim 3, characterized in that the surfaces of the shoes in contact with the piston are made of metal, plastic, more preferably of a material with a lubricating effect. 21. The device according to claim 4, characterized in that the surfaces of the shoes in contact with the piston are made of metal, plastic, more preferably of a material with a lubricating effect. 22. The device according to claim 6, characterized in that the surfaces of the shoes in contact with the piston are made of metal, plastic, more preferably of a material with a lubricating effect. 23. The device according to claim 10, characterized in that the surfaces of the shoes in contact with the piston are made of metal, plastic, more preferably of a material with a lubricating effect. 24. The device according to p. 12, characterized in that the surfaces of the shoes in contact with the piston are made of metal, plastic, preferably from a material with a lubricating effect. 25. The device according to clause 16, characterized in that the surfaces of the shoes in contact with the piston are made of metal, plastic, preferably from a material with a lubricating effect. 26. The device according to 17, characterized in that the surfaces of the shoes in contact with the piston are made of metal, plastic, preferably from a material with a lubricating effect. 27. The device according to any one of paragraphs.9, 11, 13-15, 18, 20-26, characterized in that the bolt and support shoe are made with an axial hole for introducing lubricant, and the bolt head is equipped with a dome-shaped reservoir for storing lubricant. 28. The device according to claim 10, characterized in that the bolt and the support shoe are made with an axial hole for introducing lubricant, and the bolt head is equipped with a dome-shaped reservoir for storing lubricant. 29. The device according to p. 12, characterized in that the bolt and the support shoe are made with an axial hole for introducing lubricant, and the bolt head is equipped with a domed reservoir for storing lubricant. 30. The device according to clause 16, wherein the bolt and the support shoe are made with an axial hole for introducing lubricant, and the head of the bolt is equipped with a dome-shaped reservoir for storing lubricant. 31. The device according to 17, characterized in that the bolt and the support shoe are made with an axial hole for introducing lubricant, and the bolt head is equipped with a dome-shaped reservoir for storing lubricant. 32. The device according to claim 19, characterized in that the bolt and the support shoe are made with an axial hole for introducing lubricant, and the bolt head is equipped with a domed reservoir for storing lubricant.

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