SU1720953A1 - Flight conveyer test stand - Google Patents

Abstract

The invention relates to a technique for testing scraper conveyors and can be And 7 used in the mining industry, for example, in determining the operability of tensioning devices of conveyors. The purpose of the invention is to reduce the dimensions of the stand and reduce the cost of testing the conveyor while maintaining the natural conditions of operation. For this, the stand is equipped with a simulator of a larger segment of a chain traction body, made in the form of compression springs 13, a movable 8 and two fixed plates 9 and 10. The latter are attached to one end of a smaller segment of a chain traction body and interconnected by guide pins 7 The movable plate 8 is made with holes to accommodate the guide pins 7, attached to the other end of a smaller segment. View A o C C XI o 0 ate co / 4

Description

FIG. Z

chain traction body through the ti 14 and placed between the fixed plates 9 and 10 with the possibility of displacement along the guide pins 7, and the compression springs 13 are placed between the movable 8 and the stationary 9 plates on the side of the pull 14. At the same time, the total stiffness of the compression springs 13 equal to the rigidity of the larger segment of the chain traction device simulated by them. When the conveyor drive motor is switched on, a stretching effect occurs in a smaller segment of the chain traction body.

the force that is transmitted through the simulator 6 is compressed by the springs 13 by the movable plate 8, which, together with the thrust 14, moves along the studs 7, as a result of which a slack is formed of a smaller segment of the chain draft body. The total deformation of the compression springs 13 and a smaller segment of the chain traction body corresponds to the deformation of the entire traction body of the conveyor, which allows determining the working capacity of the tensioning device. 1 hp f-ly, 2 silt,

The invention relates to a test technique for scraper conveyors and can be used in the mining industry, for example, in determining the performance of conveyor tensioning devices.

A stand for testing a scraper conveyor is known, which includes two full-scale samples of conveyors containing end and drive heads with gearboxes whose input shafts are connected to an electric motor.

The disadvantage of this stand is that due to the small length of the grating stand of the bench conveyors, the actual nature of the loading and the elastic deformation of the traction body is not preserved, which does not allow testing by determination of the working capacity of the tensioning devices.

The closest to the claimed is a stand for testing the traction body of the scraper conveyor and examining the cargo traffic generated on it, including a chute mounted on the frame for positioning a traction body on its bottom and a wire driving element of the drive mechanism encircling it. body. The stand provides the possibility of obtaining various characteristics of the cable body, for which it is equipped with a cable that is wound on the guide blocks mounted on the frame in such a way that it is possible to form an infinitely closed contour with the cable body section.

The disadvantage of the design of this stand is that the amount of elastic deformation of the cable and the length of the pulling body, forming an infinitely closed loop, is relatively small, which does not allow testing the performance of tensioning devices, as it is distorted

the nature of the load, since the traction body, due to its limited length, does not possess its inherent elasticity. Assembly. Same conveyor at full length (200-250 m)

requires significant dimensions of the bench installation and the large labor intensity of the installation and dismantling works.

The purpose of the invention is to reduce the dimensions of the stand and reduce the cost of testing the conveyor while maintaining the natural conditions of operation.

To achieve this goal, the stand is equipped with a simulator of a larger segment of the chain traction body, made in

in the form of compression springs, movable and two fixed plates, while the fixed plates are fixed to one end of a smaller segment of the chain draft body and are interconnected by

the guide pins, the movable plate is made with openings to accommodate the guide pins, secured to the other end of a smaller segment of the chain traction body by means of pulling and placed between the fixed plates with the possibility of displacement along the guide pins, and the compression springs are placed between the movable and stationary plates from the side of gi. In order to simulate the actual nature of the loading, the total stiffness of the compression springs is equal to the stiffness of the larger segment of the chain-pull organ simulated by them.

.In FIG. 1 shows a constructive

a scraper conveyor test bed; in fig. 2 shows the construction of a simulator-1 pa of a larger segment of a chain traction body, type A in FIG. one.

The stand contains a load node 1 and

scraper conveyor that includes a drive station 2, an end station 3, a grille becoming 4 with a smaller segment of traction body 5 placed in it 5. in the section of which is installed a simulator of a larger segment of chain traction body 6 fixed at points B and D of the circuit circuit (Fig. 1).

The simulator of a larger segment of the chain m - body b (Fig. 2) is a prefabricated metal structure formed by four studs 7 installed in the holes of the movable 8 and the fixed 9, 10 rectangular plates. Plates 9 and 10 are fixed at the ends of the studs 7 with nuts 11, and plate 8 freely moves along the pins 7. At the bases of the plate 9 and plate 8 there are blind end holes 12, in which compression springs 13 are installed.

The fixed plate 9 is the supporting base for the springs 13 and has a centering hole for the passage of the pulling 14. One end of the pulling is connected to the movable plate 8, and the second is pulled out through the opening in the fixed plate 9 behind the body of the simulator of a larger segment of the chain organ 6. A bracket 15 is welded to the outer side of the fixed plate 10. At the free ends of the rod 14 and the bracket 15, holes are made through which the simulator of a larger segment of the chain draft body 6 is connected with bolts 16 and 17 at points B and D (FIG. 1) with a cut bar - Sheha chain traction body 5.

When testing a tension device, for example, with an end stop fixture, the stand operates as follows.

The conveyor drive is reversed (the direction of movement of the chain is indicated by the arrow in Fig. 1). The upper branch of the traction device is locked by means of the test fixture, which forms the load unit 1. Behind the stop in the direction of movement of the traction body, set the simulator 6 of a larger segment of the chain traction body. When the electric motor is switched on, a tensile force occurs in a smaller section of the chain traction unit 5, which is transmitted through the simulator 6, and since the working branch is locked by the stopper device 1, the springs 13 are compressed by the plate 8, which together with the tension 14 moves along heels 7,

In this case, the end of the rim 14 extends beyond the case of the simulator 6 and extends the traction body 5 of the bench mount, as a result of which, in the main drive 2, the slack of the A.R. chain is formed on the working branch (fig. Determining the operability of the tension device).

The total deformation of the springs 13 of the bench conveyor corresponds to the deformation of the simulated larger segment of the chain traction organ of the conveyor of natural length (200-250 m), which makes it possible to determine the performance of tensioning devices under conditions as close as possible to natural

The length of the conveyor body simulated on the stand can be determined by the formula

one

one

 (t ± - + „,,

C2 n Ci A where Eo is the longitudinal rigidity of the traction organ;

C2 is the stiffness of a smaller segment of the chain traction unit mounted on the stand;

n is the number of springs installed in the elastic element; .

GI - spring stiffness.

The stand design allows discrete adjustment of the length of the traction device simulated on the stand, installing one central, two extreme, or three springs.

These options will correspond to the assembly of the conveyor on the length fi 100 m, k 150 m and 1 3 200 m with the same length of the stand. Thus, the use of a simulator of a larger segment of a chain traction unit allows one to have a stand 10–12 m long, at the same time imitating a lengthy conveyor organ and recreating the actual loading pattern. This allows you to have a compact stand design, reduce labor costs for assembly and disassembly work during the assembly of the stand installation and testing, reduce the cost of the stand due to the reduction of the length of the pan and the conveyor.

Invention Formula

Claims (2)

1. A test stand for a scraper conveyor, including a load unit and a scraper conveyor, containing drive and end stations and a smaller segment of a chain traction unit placed in a grating position, characterized in that, in order to reduce stand dimensions and reduce the cost of carrying out tests of the conveyor preservation of natural conditions of operation, it is equipped with a simulator of a larger segment of the chain traction body, made in the form of compression springs, a movable and two fixed plates, while the fixed plates are locked caps to one end of a smaller segment of a chain traction organ and are connected between by means of guide pins, the movable plate is made with holes to accommodate the guide pins, secured to the other end of a smaller segment of the chain draft body by pulling and placed between the fixed plates with the possibility of displacement Editor V.Danko Tehred M. Morgateal Order 922 Circulation: Subscription VNIIPI State Committee for Inventions and Discoveries at the State Committee on Science and Technology of the USSR 113035, Moscow, Zh-35, 4/5 Raushsk nab. Production and publishing company inat ChTatent, Uzhgorod, Gagarin st., 101 along the guide pins, and the compression springs are placed between the movable and fixed plates on the thrust side. 2. A stand according to claim 1, characterized in that the total stiffness of the compression springs is equal to the stiffness of the larger segment of the chain traction device simulated by them. Proofreader S.Shevkun