LV13935B - Dismountable plate chain with rolling friction joints - Google Patents

Abstract

The invention relates to machine building, definitely to dismountable plate chains used in chain conveyers which are used for transportation of different loads in industry as well as in agriculture. In the offered technical solution of the chain equipment the construction of axles is changed. At the ends of the axles flat inclined operation surfaces are formed. The aim of the invention is increase of the chain load and operation life using chain axles with changed geometrical shape of the operation surface. The stated aim is achieved by changing the geometrical shape of the operation surface. The cylindrical axle of the new construction has radius profiled inclined surfaces instead of plates at both ends.

Description

REMOVABLE PLATE CHAIN WITH RITBERZA JOINTS

The invention relates to mechanical engineering, in particular to dismountable towing chains for use in chain conveyors. Such chains can be used in various agricultural and industrial conveyors (for example, conveyor belts).

In known conveyor chains with rolling friction shamers (e.g., USSR Authorization Nos. 412090, 582697, 942485, as well as LR Patent No. 13694), the working surface of the blade and blade is formed by contact between a plane (blade) and a cylindrical surface (blade). use flat blade sharpeners. In rolling friction articulation, the contact strengths, which depend on the contact area load and the size of the contact area, determine performance. The theory of contact stresses proves that by comparing two types of surface contact: cylinder - plane (d; D - oo) and cylinder concave surface (a - D / d> 1, the center of curvature of both surfaces is on one side), maximum contact stresses in the second case of load, diameter d and D, are about seven times smaller (if a = D / d = 1.02, where D is the diameter of the concave surface; d is the diameter of the cylinder).

The known disassembled single-action rolling friction chamfer chain (LR patent N ⁰ 17694), which has been selected as a prototype, contains inner and outer plate sections connected by cylindrical shafts. The ends of the axles have symmetrical ribs on both sides. The two figurative holes in the plates, which are joined by a longitudinal section, contain a mounting and a working hole. In the process, the cylindrical surface of the working hole of the plates with the cavity is washed along the axis of the axes. The advantage of such a chain design is the ability to ensure correct kinematics of movement of the blade and the blade (non-slip) under all operating conditions, but the disadvantage is that which towing chains used on conveyors should be as large as possible.

SUMMARY OF THE INVENTION The object of the present invention is to increase the load and the durability of the chain by applying chain shafts with a modified geometric shape of the working surface.

The stated aim is realized by changing the geometric shape of the working surface of the blade. The cylindrical shaft of the new design uses radially profiled concave surfaces at both ends instead of planes.

Brief Description of the Drawings

- 1 -fig- - breakable plate chain (from above);

- Fig. 2 - disassembling plate chain (side view);

- Fig. 3 - chain link (from above);

- Figure 4 - axis A-A (rotated);

- Fig. 5 - chain plate (side view);

- Fig. 6 - disassembling plate chain (side view);

- Fig. 7 - washer (side view);

- Fig. 8 - s-type split pin;

- Fig. 9 - chain assembly and dismantling (sharpened ends);

Fig. 10 - position of the chain elements in a linear motion:

.fig. - position of the chain elements when the links turn asterisk.

The dismountable single-action plate chain (l.fig) with rolling friction joints comprises inner sections 1 and outer sections 2 formed by plates 3 and cylindrical shafts 4. The plates are axially secured to the shafts by means of washers 5 and wedged pins 6. - way (fig.2). curved surfaces 7 (Fig. 4) are formed at the ends of the cylindrical axis (Fig. 3). The lengths s (Fig. 3) of the rims 7 are chosen such that two discs 3, a washer 5 and a split pin 6 (Figs. 1 and 2) can be placed freely on one side of the chain link sections 1 and 2. Slide pins 6 are inserted into the holes at the ends of the axles (Figs. 3 and

Figure 4). The radius R of the arc 7 of the concave part of the blade 4 is calculated as follows:

cheeky '0.25 d ² - (b / 2) ^{2 2} R ₂ (R ₂ + (b / 2) arccosh '0.25d ² - (b / 2) ² ' 2R ₂ (R ₂ + (b / 2) π z

where R ₂ is the radius of the central arc 14 of the figurative hole of the plate (fig. 5); z - number of asterisk teeth; d - diameter of the axis (figs. 3 and 4);

b is the width of the narrowest flat part of the axis in cross-section (fig. 4).

The center of the radius R is on a line perpendicular to the vertical axis of symmetry. The minimum allowable distance b between the ends of the axis of the axis is determined by the calculation of the axis strength. In the section A-A (Fig. 4), there are arcs 8 and 9 in the area of its active stages, which at points Ai, Bi, Fj and E] connect with planes in section c and curved section 7 in the plane of section c (Fig. 4). ) along the length s is the toothed rib 10. The width of the straight section c, which also includes the rib 10, is determined by the calculation of the contact durability. The portion of the axis width h = L - c is used in the rolling process, when the curved segments 7, when they arrive at the asterisk, rotate by an angle γ (Fig. 11). The plate (Fig. 5) has two identical figurative holes 11 for mounting and dismounting the chain, as well as the end face 7 of the blade 4 together with the straight part c for positioning it in the working position (Fig. 6). The figurative hole 11 is formed by two circular sections 12 and 13, a circular section 14 with a straight lower portion perpendicular to the axis 0-0 of the plate and a rectilinear section 15. Sections 12 and 13 are located on either side of the the inner portion of the figurative hole 11. The section 15 is placed perpendicular to the axis 0 - 0 of the plate 3. The radii Rj of the sections 12 and 13 are on the line Μ - M which is perpendicular to the axis 0-0 of the plate 3. Circles 12, 13,14 and line 15 interconnect at points A, B, F and E.

The line Μ - M is located at a distance b / 2 from the straight line c 14. The length of the straight lower part of the rim 14 equals the dimension c of the axis 4 (Fig. 4). A recess 16 is formed in the middle of the rectangle of the rim 14, which accommodates the toothed rib 10 of the spindle 4. The radius R2 of the rim 14 (fig. 5) is calculated as follows:

where the parameter designations are named near the formula for the calculation of radius R. The center of the radius R2 of the central arc 14 is on the lines 0i - Oj parallel to the axis 3 of the symmetry axis 0 - 0 and offset therefrom by the value e (Fig. 5). Dimension e shall be determined in a constructive manner such that the distances Kj = K2 which provide the plates in the equilateral section

Μ - M. Radius Ri = d / 2. The centers of these radii are on the line Μ - M. Using the given relation radius for determination of R and R2, it is assumed that R> R2. The distance of the straight section 15 from the line Μ - M is determined by observing the plain rotation of the plate relative to axis 4 at an angle γ (Fig. 11), i.e., that the point Bi of the axis touches the section 15 only at the end of the plate turning. Thus the points B and E are also constructively obtained. The chain pitch t is the distance between the lines Μ - M of the figurative hole 11 (Fig. 5).

Chain assembly sequence:

a) the ends of the axles 4 (fig. 9) with the hoops 7 are inserted into the figurative holes 11 of the inner plate 1 so that the flat surfaces c of the axles are in contact with the straight part 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 7 of the axes 4 are in contact with the straight part of the rim 14 of the figurative hole 11 and the protuberance 10 is in the recess 16 of the plate;

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

d) Insert a wire into the 4 holes of the axles and bend the ends to form a s-pin 6 (figs. 2 and 8) to prevent it from falling out.

Shifting of the plates 3 towards the center of the axis 4 is prevented by the incline of the axis formed between the surface of the circles 7 and the outer diameter d of the axis (figs. 3 and 4). The chain plates have no mounting bore or longitudinal section compared to the prototype.

The operation of the chain link is as follows:

In a rectangular motion (FIG. 10), the plane portion c of the arcs 4 of the axles 4 is in contact with the straight portion c of the circle 14 of the inner 1 and outer 2 portions 3 of the plates. The toothed protrusion 10 of the blade 4 is located in the recess 16 of the blades 3. The points Fi and Ei of the blades 4 of the blade 4 do not touch the respective blades of the blades 3. The gap 4 between the blade 4 and 9 of the blade 3 faces the blade 12. Points A and Ai coincide. The tooth of the blade cam 10 and blade recess 16 prevents the sliding working surfaces of the shoe from slipping arbitrarily throughout the range of rotation angles γ of sections 1 and 2. The chain links can only turn to one side. This type of chain is useful if the chain sprockets are only on one side of the chain (the most common variant in practice).

The chain tension force is transmitted by straight sections of axles 4 and plates 3 c. The blades are in contact with the chain sprocket teeth.

One-sided action circuit boards can be narrower (size H, fig. 5), which avoids excessive shakes in the shams. Turning the links of the chain to the asterisk at an angle γ (FIG. 11), the circle 14 of the plate hole 3 will wash along the concave surface 7 of the blade 4. The toothed protrusion 10 of the blade 4 remains in contact with the plate recess 16 at all times.

Theoretical analysis shows that the slip of the working surface of the rolling sham parts (with respect to the gap in the tooth) is negligible relative to the slip rate and the forces between the blade cam 10 and the plate cavity 16. Therefore, friction energy consumption will also be negligible and gearing wear will be negligible. When designing slip-resistant elements, their geometric shape and profile angle must be correctly defined so that no self-braking effect occurs in the tooth.

At the end of the turn of the stage (fig. 11), the stage 4 of the blade 9 faces the plate circle

13. The point F1 is in contact with point 13 of the outer ring 2 of the plate 3, the point F of the outer ring 2 is in contact with the point 4 of the ring 3 of the inner plate Εμ The points Ai and Bi touch the figurative hole of the respective inner 1 and outer 2 plates. 11. At the end of the turning of the chain links 1 and 2, the axes 4 rotate sliding relative to the asterisk to an angle γ / 2.

During the turning of the inner chain link 1 and outer link 2, the chain tension force is absorbed by the active concave surface 7 of the blade 4 and the active convex surface of the plate.

14. The contact stresses on such oriented surfaces are significantly lower than when the contact is formed between a cylindrical and a flat surface. Thus, the object of the invention is realized.

Claims (1)

Claim Disassembling, single-action chain of slats with rolling friction shammers, consisting of cylindrical shafts with symmetrically shaped, symmetrical surfaces at the ends and a rectangular toothed outer and inner plate with two identical figurative cuts with two contours straight sections with the middle of the circles curved inwardly of the figurative cutout and containing a straight section with a cavity perpendicular to the axis of symmetry of the plate, the second straight section being perpendicular to the axis of symmetry of the plate and the other two the sections are located on the side of the middle segment and their curvature is directed towards the outside of the plate, the radii of curvature of these two arcs being equal to the radius of the axes, except that in order to reduce the to increase chain load and lifetime, cylindrical blades are used with two symmetrically curved, radius-profiled worktops at each end.