LV14527B - Detachable laminated chain with articulated and one-side turn links - Google Patents

Abstract

The invention relates to mechanical engineering, in particular to the dismountable hauling chains of conveyers. Such chains can be used in various branches of agriculture and industry for provision operation of continuous scrapper conveyors transporting various loads (for example, dusty, fine grain, hot, abrasive loads etc.) in horizontal, inclined or vertical directions. The proposed technical solution laminated chain is characterized by construction of chain axes and plates. The aim of the invention is to increase service life of flat-link chains by using chain with one-sided turn of its links. The ends of axes are formed with concave working planes, but the figurative holes of both plates are formed asymmetric and are offset radially relative to the axis of symmetry of the plates. Such chain construction allows to reduce the dimensions and metal consumption of chain links and eliminates excess movement of its pivots.

Description

Description of the Invention

The invention relates to mechanical engineering, in particular to dismountable disc chains with roller shears used in chain conveyors. Such a chain can be used in various agricultural and industrial chain conveyors for transporting different loads. The invention extends the life of the chain due to rolling friction in the chain shams, but the one-sided rotation of the sections allows to increase the radius of curvature of the working surfaces of the chain parts, reducing contact stresses in the shams, increasing the part strength.

Analysis of prior art

Known standardized conveyor chains (eg TOCT 588-81; 589-85; 2319-70; 4267-78; 12996-90, etc.) use only slip friction shamers. Conveyor chains work on cargo mass during transportation, which makes lubrication of chain shamers difficult. When lubricating slip friction shammers, the chain has a lifetime of at least 10,000 h, but without lubrication it is 10 times less [ΓοτοΒρεΒ Α. A., Ctojī6hh Γ. Ε., Κοτθηοκ Η. Π. ĪIpoeKTHpoBaHHe pemn.ix not taken. - M. MamHHocipoeHHe, 1973-384 c] When using rolling friction shear, lubrication has less effect on the wear resistance of the sham and the chain can operate for a long time without lubrication, which is important in rust conveyor chains.

In known conveyor chains with rolling friction shamers, for example, Latvian patent no. 10417 and the USSR Certificate of Authorization no. 1270072; 942485; 412090 uses chain with two-way link. If all the sprocket chain sprockets are on one side of the chain contour, a rolling friction joint with a one-way link of the chain link should be constructed, since no reverse link is necessary.

Known as a prototype disassembled chain of discs (LV Patent No. 10417), which has been selected as a prototype, has internal and external links, the lintel connects cylindrical blades with double-sided radial holes at the ends. The outer and inner plates have figurative holes at the ends where the curved working surface forms a symmetrical arc with respect to the longitudinal axis of the plate, allowing for a two-sided rotation of the chain links. The design of such a chain is not useful for a conveyor where all the asterisks are placed on one side of the chain outline (this is the most common case).

Purpose and substance of the invention

The object of the invention is to extend the lifetime of the chain by using a one-sided rotation of the chain, which increases the bending radii of the operating surfaces of the chain and thereby reduces contact stresses in the hinges and prevents the motion resistance applied to cantilevered torsion bars as well as uneven movement of the chain), as well as increasing the strength of the chain parts and reducing the material volume.

The stated aim is accomplished by creating flat curved working surfaces at the ends of the blade by radially displacing the two figural holes of the plates relative to the longitudinal axis of the plate and eliminating one side of the arc of the plate curved surface. Thus, it is possible to reduce the plate width and material volume without reducing the strength. As the width of the plate allows the single-sided radius of the curved working surface to be increased, the contact stresses in the chain pivots also decrease.

BRIEF DESCRIPTION OF THE DRAWINGS The following drawings illustrate the invention:

Fig. -1 is a top view of a proposed disassembled chain of discs;

- Fig. 2 a side view of the proposed plate chain is shown;

- Fig. 3 a top view of the chain axis is shown;

- Figure 4 A-A is a cross-sectional view;

- Fig. 5 a side view of the chain plate is shown;

- Fig. 6 a side view of the disassembled plate chain is shown with its sharpened blade ends (see section designation B-B l.fig);

- Fig. 7 a side view of the washer is shown;

- Fig. 8 the s-pin is shown;

- Fig. 9 chain assembly and dismantling is shown;

- Fig. 10 the position of the chain elements in a linear motion is shown;

-11 .fig shows the position of the chain elements as the links turn to the asterisk.

The dismountable single-action plate chain (l.fig) with rolling friction shamers comprises internal sections 1 and outer sections 2 formed by equal plates 3 and axes 4 with a cylindrical center. The axial fixation of the plates 3 to the ends of the axes 4 is provided by washers 5 and wire pins 6 which, after insertion in the radial bores at the ends of the axes 4, bend in s-shape (fig. 2). The axis 4 (Fig. 3) has symmetrical recesses 7 (Fig. 4) at both ends of radius R ₂ formed by planes 10 with height c at one end. The width s (Fig. 3) of the cavities 7 is chosen such that two plates 3, a washer 5 and a cotter pin 6 on one side of the chain 1 and 2 can be freely positioned by calculating the height c of the blade planes 10 so as to guarantee contact strip. The minimum allowable distance b between the ends of the axis 10 is determined by the calculation of the axis strength. In the axis AA (Fig. 4), there are arcs 8 and 9 in the area 10 of its planes and in the area R _{2 of} radii joining planes 10 or the ends of radii R ₂ at points A _b Bi Fi and Ei. The circles 7 of the axis 4 are used in the process of rolling the stages, when the stars arrive at the chain, the stars turn with each other at an angle γ (fig. 11). The asymmetric figurative holes 11 of plate 3 (fig. 5) for mounting and dismounting the chain and positioning the end planes 10 of the axle in working position (fig. 6) are disposed asymmetrically with respect to the longitudinal axis 0-0 of the plate. and (e). This offset is necessary to obtain a uniform stiffness of the plate at all its ends, ie that the dimensions K and P are the same. The figurative hole 11 is formed by two circular sections 12 and 13 of equal shape and length and a circular section 14 with a straight lower portion AC having a height c corresponding to the plane 10 of axis 4 (FIG. 4) and perpendicular to the axis OO of the plate. 15. Sections 12 and 13 are disposed on either side of the plate symmetry axis 0-0 with an indentation relative to the inner portion of the figurative hole 11. The arc 16 at E is connected to arc 13 and G is connected to R 15. Section 15 is positioned perpendicular to the axis 3 of symmetry of the plate OO. The radii R of the sections 12 and 13 are equal to the radius 4 (d / 2) of the axis and their centers are on the line DD which is perpendicular to the axis 00 symmetry of axis 00. The circles 12, 13, 14 and 16 and line 15 interconnect at punk, B ', G, E, and F. The line DD is located at a distance b / 2 from the straight lower portion AC of the circle 14. The radius Ri of the arc 14 is determined constructively with respect to the width L of the plate 3 and the dimensions K = P, which are determined by the strength calculation. The center of the radii Ri is on the line Oj-Oi which runs parallel to the axis 0-0 of the plate through point C. The radius 7 of the working surface of axis 4 is R ₂ = 1.02Ri.

Chain assembly sequence:

a) the ends of the axles 4 (Fig. 9) are inserted by plates 10 into the figural holes 11 of the inner section 1 plates 3 so that the axial planes 10 are in contact with the straight part AC of the rim 14 of the figurative hole 11;

b) the plates 3 of the outer section 2 are applied to the ends of the axes 4 so that the planes 10 of the axes 4 are in contact with the straight part AC of the rim 14 of the figurative hole 11;

c) Place washers 5 (figs. 1 and 7) on the ends of the axles 4;

d) Insert a wire into the radial holes d] of the axles and bend the ends to form a s-pin (Figs. 2 and 8) to prevent it from falling out.

Since the figural holes of the plates are disposed asymmetrically with respect to the O-O of the plate's longitudinal axis, the end corners of each plate are phased to properly orient the plates at assembly and correctly position the chain (Fig. 5).

Operation of chain link

In a linear motion of the chain (Fig. 10), the plane portion 10 of the axles 4 contacts the straight portion AC of the figurative holes 11 of the inner 1 and outer 2-section plates 3. Axis arcs 7 do not contact plates 3 arcs 14. There is a gap between arcs 4 of the blade 4 and arcs 13 of the plates 3, but arcs 4 of the axes 4 face arcs 12 of the plates 3. The points A and Ai coincide but the points B 'and Bi do not the axis of the axis Ai Bi is smaller than the arc A B 'of the plate. The 4 points E1 and Fi of the axis are in contact with the arcuate sections 16 of the discs 3. Thus, the axis is fixed in the figurative holes 11 of the discs 3 and the chain conveyor contour at straight sections prevents chain section fluctuations. As the straight sections of the chain outline can be large (more than 100m), the shamers wear out mainly in these sections. The chain links can only turn to one side.

Consider the action of the chain plates and the axis in the turn (fig. 11), explaining the interaction of only one outer and inner plate 3 with the axis 4. Fig. 1 shows the input of the inner chain link 1 in contact with the chain star (not shown). the direction of rotation is ω _ζν . The outer chain link 2 plates 3 and the spindle 4 are already on the star and rotate together as one whole article. The plate 3 of the inner chain link 1 maintains a horizontal position as a result of the tensile force Fi of the chain when entering this star. As the asterisk rotates, the angle γ changes from zero to Y _max (at this angle, step 1 will sit on the asterisk, that is, it will enter into full engagement). Since the outer plate 2 plates 3 do not rotate relative to the asterisk axis 4, the convex arcuate portion 14 of the inner portion 1 plate 3 frictional hole 14 will freely wash through the right hollow rim 7 of the blade 4 and the position of the contact point will change continuously. ). When the developed torque of the force applied to the axle becomes greater than the resistance of the frictional forces of the axle and the star, the axle on the asterisk (0) 4) begins to rotate and the circular hollow 7 on the left side of the axis 4 14. The plates 3 of the inner section 1 and the outer section 2 rotate with respect to the axis γ ^ χ / ζ. The total rotation angle of the section plates y _m2X = 360 ° m / z (here m is the number of asterisk strokes; z is the number of asterisk teeth, for example if m = 2 and z = 13 then Ymax = 55.38 °). At the end of the rotation of the plates 3 of the inner section 1 relative to the axis 4 (at an angle max / 2), the phase 9 of the axis 4 faces the circle 13 of the plates 3 and the point 9 of the circle 4 as a result of the action of the inner plate 1 plates 3, the left-hand rim of the axis 7 is flush with the outer plate 2 plate 3 circle 14, the point 4 Fj of the axis 4 will contact the plate point F (similar movement as turning the inner plate 1 plates 3). Turning the chain sections 1 and 2 by 7 _max , the points 4 and 4 of the axis 4 of the axis touch the rectangular section 15 of the inner 1 and outer 2 plates 3, which prevents the plates 3 from slipping arbitrarily through the hollow circles 7. axes) also occur when entering into outer star 2 wafers 3 at the end of the turn of chain link 1 and 2 (chain movement is v) the front ends of inner 1 wings 3 move slightly up radially and outer 2 wings 3 rear ends move down.

Claims (1)

Claim 1. A disassembled plate chain with roller shears which provides a one-sided rotation of the sections relative to the axis of symmetry of the chain, wherein: the chain consists of cylindrical shafts with symmetrically arranged cylindrical recesses at both ends; one end of said cavities being formed by a flat section with the same outer and inner plates provided with two identical asymmetrically shaped figurative holes, the outline of which is formed by four circular sections; in addition: the middle of said arcuate sections is closer to the end of the plate, curved inwardly of the figurative hole, and having a straight section perpendicular to the axis of symmetry of the plate; the two outermost circular sections, the upper and the lower one, are on the sides of the middle section and their curvature is on the side edges of the plate, in addition, the radii of curvature of these two circular sections are equal to the radius of the axis; the fourth of said arcuate portions being in the part of the figurative hole which is closer to the middle of the plate and joining at one end to the upper peripheral arc and to the other end joining a straight section perpendicular to the symmetry axis of the plate; distinguished by the fact that both figurative holes in the chain plates are formed asymmetrically and offset in order to reduce the chain link excess oscillations in the straight sections of the chain, to reduce the chain capacity of the chain and to provide only one side of the chain turns, in relation to the axis of symmetry of the plate.