RU2553755C1 - Vibration device for finishing and hardening processing of parts - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: device comprises working chamber with drive resiliently fitted on the bed. Work chamber is made hollow in form of square with helical surface and with pockets having different polygonal form and dimensions, and made out of rigidly connected in series with each other four hollow sections in form of round sector and four hollow straight sections. The sections in form of round sectors are made out of sub-sections with multifaceted surface having square with same size. Each of four hollow straight sections is made out of at least one strap bent at straight lines and turned in cylindrical turns connected with each other along the longitudinal edges of the strap, creating broken helical lines and broken helical pockets with different polygonal form and size.

EFFECT: enhanced technological abilities of the device, higher efficiency of parts processing.

14 dwg

Description

The invention relates to the processing of parts in containers that perform low-frequency vibrations, and may find application in various industries for grinding, polishing and hardening of the surface layer of parts.

Known vibration installation with a volumetric movement of the working chamber (RF patent No. 2288830, class B24B 31/073, 2006), containing a toroidal working chamber, elastically mounted on the base with a vibrator, made of sections mounted from strips bent to one side in straight lines, placed at an angle to the edges of the strips, with alternating formation along the length of the strip of equal-sized equilateral and isosceles triangles, while on the two sides of the largest equilateral triangle, two identical isos unified triangles, on the sides of which are two identical equilateral triangles with two identical isosceles triangles located to their bases, on one of which is an equilateral triangle, and the sides of smaller equilateral triangles differ from the sides of large equilateral triangles by the same linear value, and the sections are connected to each other by the free sides of these triangles with the formation on the outer and inner surfaces of oidalnoy working chamber of polygonal lines screw and helical surfaces.

A disadvantage of the known vibration installation with a volumetric movement of the working chamber is the limited technological capabilities due to the fact that the processing is carried out with insufficient intensity and insufficient energy consumption of the interaction of parts and particles of the working medium with each other over a relatively short length (around the circumference) of the working chamber in the form of a torus.

Closest to the proposed invention is a vibration installation with a toroidal working chamber (RF patent No. 2468906, class B24B 31/073, 2012), containing a toroidal working chamber resiliently mounted on the base with a vibrator, made in the form of a torus with a wave-shaped multi-start helical surface of double curvature, equipped with helical grooves inside and outside the working chamber at an angle to its axis in the form of pockets of curvilinear shape with centers of curvature located outside and inside the cross section of the working chamber, is mounted from sections, each of which is made in the form of a circular sector, made of a strip bent in a wave-like fashion along fold lines to form different-sized quadrangles with two parallel sides in the form of fold lines and rolled into a ring, while the sections are connected to each other by the free sides of said quadrangles with the formation of a hollow working chamber with wavy helical surfaces directed in one direction along its outer and inner surfaces in the form of pockets of various curvilinear shapes size, and the distance between the fold lines of the strip is equal to the sum of the scan lengths of the curved surface of the pockets along the inner and outer surfaces of the working chamber.

A disadvantage of the known vibroinstallation with a toroidal working chamber is the limited technological capabilities due to the fact that the processing is carried out with insufficient intensity and insufficient energy consumption of the interaction of parts and particles of the working medium with each other over a relatively short length (around the circumference) of the working chamber in the form of a torus.

The technical result of the invention is the expansion of technological capabilities, increase productivity and path (length) of movement of the workpieces and particles of the working medium in the working chamber.

The technical result is achieved in that in a vibrating installation for finishing and hardening processing of parts containing a working chamber resiliently mounted on the base and equipped with a drive, the working chamber is hollow in the form of a square with a screw surface along the inner and outer perimeters and with pockets of various polygonal shapes and sizes , and is mounted from four hollow sections rigidly connected alternately to each other, made in the form of a hollow circular sector, and four hollow rectilinear sections, and sections in the form of a hollow circular sector are made of a strip rolled into a ring with a multifaceted surface and the formation of different-sized quadrangles with two parallel sides parallel to each other with the formation of subsections, while the subsections are connected to each other by the free sides of the said quadrangles with the formation of a circular sector, made with a multiple helical surface, provided with helical grooves inside the circular sector at an angle to its axis and in the form of pockets of various polygonal shapes, the distance between the straight fold lines being equal to the length of the sides of each quadrangle, and the four hollow straight sections are made of at least one strip bent along straight lines placed at an angle to the edges of the strip to form quadrangles located on the strip alternately in opposite directions, while the strip is folded into cylindrical coils connected to each other along the longitudinal edges, with the formation on the outer surface of unidirectional broken spiral lines, and on the inner surface - broken spiral pockets of a polygonal shape, which along the perimeter can be different not only in shape but also in size, while the distances between the fold lines of the strip are equal to the length of the sides of the said pockets.

According to the patent technical literature, no technical solution was found that is similar to the claimed one, which allows one to judge the inventive step of the proposed vibration installation for finishing and hardening of parts.

The novelty lies in the fact that the working chamber is made hollow in the form of a square with a curved helical surface along the inner perimeter in the form of pockets of a multifaceted shape, which expands technological capabilities, with the same dimensions with the working chamber made in the form of a torus, technological capabilities expand and the path (length) of movement of the workpieces and particles of the working media in the square working chamber increases, since the length along the perimeter of the torus (circle) of diameter D is L ₁ = πD, and the length along the perimeter of the quad The ratio is L ₂ = 4D. (L ₂ > L ₁ ).

The novelty is also due to the fact that the working chamber is mounted from four sections rigidly alternately rigidly connected to each other, made in the form of a circular sector with four rectilinear sections, which expands technological capabilities and since with the same dimensions the working chamber made in the form of a torus , expanding technological capabilities and increasing the path (length) of the movement of the processed parts and particles of the working medium in a square working chamber.

The novelty is seen in the fact that the pockets of the working chamber are made in the form of geometric polygonal shapes of at least one strip, which expands the technological capabilities.

The novelty also lies in the fact that the pockets around the perimeter of the working chamber can be different not only in shape but also in size, which expands technological capabilities.

The novelty is also due to the fact that the distances between the fold lines of the pockets of the inner surfaces are equal to each other and equal to the sum of the lengths of the perimeters of the geometric figures of the pockets of the inner surfaces, which expands the technological capabilities.

The novelty is due to the fact that the working chamber is made hollow, in the form of a square, with a curved helical surface along the inner perimeter in the form of pockets of a multifaceted shape in the form of various geometric shapes with four or more sides, which provides not only the intensification of the interaction of the processed parts and particles of the working environment , increasing productivity, but also expanding technological capabilities.

The novelty of the proposal lies in the fact that on the inner surface of the working chamber polygonal surfaces are formed, which along the perimeter can be different not only in shape but also in size, which provides a change in the direction of movement of the workpieces and particles of the working medium, resulting in increased productivity expanding technological capabilities.

The novelty is due to the fact that the sections from which the working chamber is assembled are mounted around the perimeter from strips with quadrangles marked on them of different sizes and sizes; therefore, the intensity and productivity of finishing hardening increases, and technological capabilities expand.

The novelty of the proposal also lies in the fact that around the entire perimeter of the working chamber, the passage section varies not only in shape, but also in area, which provides alternate compression and expansion of the flows of processed parts and particles of working media in each section of the working chamber, which means an increase in productivity and expansion of technological capabilities.

The novelty of the invention lies in the fact that the quadrangles of the strips from which the sections are mounted are not only inclined to each other, but also to the axis of symmetry of the working chamber; therefore, the compression ratio of the processed parts and particles of the working media increases, and the feed preparation process is intensified.

The novelty also lies in the fact that the working chamber is made of sections and subsections, the walls of which are not only inclined to each other, but also to the direction of the rotational movement of the workpieces and particles of the working medium moving under the influence of vibration in planes perpendicular to the passage section of the working chamber, which complicates the trajectory of their movement and increases the intensity of finishing and hardening processing of parts and expands technological capabilities.

The novelty also lies in the fact that when the vibrator is installed horizontally (unlike its counterpart, patent No. 2358620, class A23N 17/00, publ. 06/20/2009, Bull. No. 17, in which the vibrator is installed vertically), the flows processed parts and particles of the working medium, circulating inside the working chamber in planes perpendicular to the axis of symmetry of the working chamber, receive additional movement from the walls of the pockets of the polygonal shape of all eight sections inclined to each other, which expands the technological capabilities and AET productivity finishing and hardening treatment processing parts.

The invention is illustrated by drawings, where: in Fig.1 shows a vibrating installation for finishing and hardening processing of parts, General view; figure 2 - working chamber in the form of a square, top view; figure 3 is a section aa in figure 2; figure 4 - one of the four sections, made in the form of a hollow circular sector, top view; figure 5 is a section bB in figure 4; figure 6 is a strip with marked straight lines of bending and cutting lines of the edges of the quadrangles; 7 is a strip after trimming the edges of the quadrangles; on Fig - strip after trimming the edges of the quadrangles, bent along the straight lines of the fold; Fig.9 is a perspective view of a strip folded into a ring subsection; figure 10 is one of four hollow rectilinear sections with pockets of a polygonal shape, General view; figure 11 is a section bb in figure 10; on Fig - strip with marked lines of fold in the form of straight lines for pockets of a polygonal shape of the hollow rectilinear section in figure 10; in Fig.13 - a strip bent in straight lines with the formation of pockets of a polygonal shape; Fig. 14 is a perspective view of a strip folded into a cylindrical coil.

Vibration installation for finishing and hardening processing (figure 1) consists of a working chamber 1 mounted on a platform 2, equipped with a vibrator 3. Platform 2 by means of springs 4 is installed on the base 5.

The working chamber 1 is made in the form of a square (Fig. 2) with a polygonal screw surface along the inner perimeter (Fig. 3) in the form of pockets of a polygonal shape and is mounted from four sections 6, 7, 8, 9, rigidly connected alternately to each other, made in in the form of a circular sector with four rectilinear sections 10, 11, 12, 13 (figure 2).

Sections 6, 7, 8, 9 (Fig. 4) with a multifaceted helical surface along their inner perimeter are made of subsections 14 (one of the subsections in Fig. 4 is highlighted by solid thickened lines), interconnected by known methods, for example, welding, gluing etc., with the formation of helical lines on the outer and inner surfaces (in Fig. 4, one of the helical lines is shown by a thickened line 15-16-17-18-19-20-20-22-22-23) and polygonal helical surfaces in the form of various geometric shapes with four or more sides, for example, a straight nik, trapezoid, rhombus, etc., in the form (5) of the outer surface of the pockets 24, 25, 26, 27, 28, 29 and the inner surface of the pockets polygonal shape 30, 31, 32, 33, 34, 35.

Each of the subsections 14 is made in the form of a circular sector (Fig. 4, Fig. 5) and is mounted from a strip 36 (Fig. 6, Fig. 7) on which rectangles are marked, along the diagonals of which there are fold lines passing through points 37, 38 , 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60 at distances from each other, equal to the length of the side of the geometric figure, for example, as in Fig.6 at a distance L ₁ , L ₂ , L ₃ . The fold lines of the strip 36 are shown in FIG. 6 with a thickened line. On the strip 36 also marked are the trim lines 61 of the edges of the strip 36 shown in FIG. 6 with a dash-dot line with two points. After marking along the edge-cutting line 61, the sections of the strip 36 (in FIG. 6 these sections of the strip 36 are shaded) are cut off and the strip 36 takes on the form shown in FIG. 7, in which the fold lines of the strip 36 are different in length L ₄ , L ₅ , L ₇ , L ₈ , L ₉ , L ₁₀ , L ₁₁ , L ₁₂ , L ₁₃ , L ₁₄ , L ₁₅ , L _16, L ₁₇ , L ₁₈ , L ₁₉ , L ₂₀ , L ₂₁ , L ₂₂ , L ₂₃ , L ₂₄ , L ₂₅ , L ₂₆ , L ₂₇ .

The strip 36 (Fig.7) after trimming the edges of the rectangles along the trim lines 61 is bent in straight lines - the fold lines 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, placed at an angle α to the edges of the strip 36 (Fig.6, Fig.8) with the formation of different sizes of quadrangles with two parallel sides - t. e. along the diagonals passing through the points 37-60 of the rectangles (Fig.6) parallel to each other, and then collapses into a ring 14 with a multifaceted surface, as shown in Fig.9. The transverse edges 62 and 63 of the strip 36 (Fig.6, Fig.7) after folding into a ring 14 are connected by known methods, for example by welding, soldering, etc., with the formation of a subsection 14 in the form of a circular sector - ring 14 (Fig.9 4)

Thus, sections 6, 7, 8, 9 (Figs. 4, 5) are made around the perimeter in the form of a multi-helical surface with helical lines that vary in diameter of the section in increments of the perimeter of the section (one of the helical lines shown in Fig. 4 is thickened with a line 15-16-17-18-19-20-21-22-23-23 and screw grooves inside and outside sections 6, 7, 8, 9 in the form of pockets of a polygonal shape, at an angle to the axis of sections 6, 7, 8, 9 .

Sections 6, 7, 8, 9 (Figs. 4, 5) with a screw surface along its inner and outer perimeters with the formation of pockets of a polygonal shape can be made in other ways.

Four hollow rectilinear sections 10, 11, 12, 13 (Fig. 10, 11) with polygonal pockets, for example, section 10, are made of at least one strip 64 connected along the longitudinal edges 65 (shown in Fig. 10 by a dot-dash line ) by known methods, for example, welding, with the formation on the outer and inner surfaces of helical lines (in Fig. 10, one of the helical lines is shown by a thickened line 66-67-68-69-70-71-72-73-74-75-76- 77) and screw surfaces (11) of a rectangular shape in the form of pockets of the outer surface 78, 79, 80, 81, 82, 83 and pockets of the inner second surface 84, 85, 86, 87, 88, 89.

Strip 64 (FIGS. 12, 13) is bent along straight lines 90 at equal angles α to the longitudinal edges 65 of strip 64 placed at distances equal to the length of the polygon elements of the pockets, for example, for pocket 81 at distances L ₁ , L ₂ , L ₃ .

The strip 64 after bending along straight lines (Fig. 12, 13) is folded into cylindrical coils (Fig. 14), connected to each other along the longitudinal edges 65 by known methods, for example by welding, into hollow straight sections 10, 11, 12, 13.

Hollow rectilinear sections, for example 10, 11, 12, 13, with pockets of a polygonal shape are rigidly connected alternately with hollow sections 6, 7, 8, 9 with pockets of a polygonal shape (figure 2) along lines II, II-II, III- III, IV-IV, VV, VI-VI, VII-VII, VIII-VIII with the formation of a continuous hollow working chamber 1 in the form of a square with polygonal pockets along its inner perimeter can be made in other ways.

Vibration installation for finishing and hardening processing works as follows.

The perturbing force of the vibrator 3 through the walls of the working chamber 1 is transmitted to the workpieces and particles of the working medium inside the working chamber 1. The processed parts and particles of the working medium under the influence of vibration rotate in planes perpendicular to the axis of symmetry of the hollow working chamber 1 and pockets of a polygonal shape in its perimeter. The presence of pockets of a polygonal shape around the perimeter of the working chamber 1 changes the direction of movement of the workpieces and particles of the working medium, as a result of which they not only acquire directional movement from loading to unloading, but also compression zones are formed along the entire length of the path of movement inside the working chamber 1, productivity increases hardening treatment, expanding technological capabilities.

Particles of the working media and the workpieces not only intensively interact with each other, mixing, but also under the influence of vibration rotate in a plane perpendicular to the bore of the working chamber 1. Since the dimensions of the cross section along the length of the working chamber 1 change, then the disturbance of the movement of working particles and workpieces is exacerbated, i.e. there is an increase in the performance of hardening treatment. The presence of polygonal helical surfaces and helical lines around the perimeter of the working chamber ensures the movement of the processed parts and particles of the working medium not only in hollow rectilinear sections of the working chamber 1, but also in hollow sections made in the form of a circular sector, which contributes not only to complicate the trajectories of their movement , but also their movement along the passage section of the working chamber 1 from loading to unloading. When the workpieces and particles of the working media move along the bore of the working chamber 1 due to a change in the bore in shape and size, compression and rarefaction zones are formed in each section of the working chamber 1 over its entire volume, which also intensifies the process of finishing and hardening expands technological capabilities.

The technical and economic advantages of the vibrating installation for hardening treatment arise due to the execution of the working chamber in the form of a square, the expansion of technological capabilities, increasing productivity and the path (length) of movement of the workpieces and particles of the working medium in the working chamber, the surface of which is equipped with unidirectional helical lines and screw surfaces, in the form of pockets of a polygonal shape, which provide a change in the direction of flow of the workpieces and parts q working environments, and the expansion of technological capabilities.

Claims (1)

A vibrating installation for finishing and hardening processing of parts, comprising a working chamber elastically mounted on the base with a drive, characterized in that the working chamber is hollow in the form of a square with a helical surface along the inner and outer perimeters and with pockets of various polygonal shapes and sizes and is mounted rigidly four hollow sections alternately connected to each other in the form of a circular sector and four hollow rectilinear sections, while the sections in the form of circular sectors are made of subsections, each of which is made of a strip bent along the fold lines and rolled into a ring to form a polyhedral surface with different-sized quadrangles with two parallel sides, the distance between the straight fold lines of the strip being equal to the length of the side of each quadrangle, and the subsections are connected to each other other free sides of the said quadrangles with the formation of a circular sector with a multiple helical surface having helical grooves at an angle to its axis in the form of pockets of different polygonal shape, while each of the four hollow rectilinear sections is made of at least one strip bent in straight lines placed at an angle to the edges of the strip, with the formation of quadrangles located on the strip alternately in opposite directions, and folded into cylindrical coils, connected to each other along the longitudinal edges of the strip, with the formation on the outer surface of unidirectional broken helical lines, and on the inner surface - broken helical pockets of different polygons shape and size, and the distance between the fold lines of the strip is equal to the length of the sides of the said pockets.

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