SU602676A1 - Percussive electrodynamic action mechanism - Google Patents

Description

The present invention relates to a percussion mechanism of an electrodynamic action type and can be used, in particular, for crushing non-dimensions of rocks after blasting, concrete, boulders, old foundations, etc.

A device of the principle of electrodynamic action is known, used for "illogical purposes" and containing several split rings of magnetic, located outside the inductor which is connected to a powerful pulsed source Tosa fij.

However, the operation of this device is impacted by the need for drilling.

suvura in a destructible object to place split rings with an inductor in it.

The closest technical solution of the invention is an impact mechanism of electrodynamic action, comprising a working tool and a hollow guide rail, stator and measles with electrical windings connected to the generation of electric pulses and having the possibility of axial movement in opposite directions under the action of an electrodynamic force to communicate an impact jsj tool

The known mechanism is intended exclusively for driving piles and, by its design features, can only work in an upright position, and therefore it is not adapted for the previously mentioned types of work.

To ensure the impact mechanism of an electrodynamic action at different spatial positions, the proposed device is provided with a housing in which a stator is mounted movably and connected to the tool, and a damping element located in the tail of the pilot cylinder and is used to brake and return the core and inert to it. mass after impact.

FIG. 1 shows the described device, a general view {in FIG. 2 is the same, node 1 in FIG. one.

The percussion mechanism includes a housing 1, in which, using the guide bushings 2 and 3, the cup 4 with the stator 5 is movably axially secured, the cantilever 6 is fixed to it, rigidly fastened to an inert mass 7. A cap 8 is attached to the glass end 4, connected to working tool 9. Through the bark 6, the fallen guide cylinder 1O is passed, fixed rigidly at one end in the lid 11 of the housing 1 and through the sleeve 12 (Fig. 2) resting on the cylindrical protrusion 13 of the lid 8.

In the tail part of the guide cylinder C, there is a damping element 1 formed; coaxially about the damper 14 (Fig. 1) mounted inside the cylinder C, and a spring 15 located outside it.

A winding 16 is laid on the stator 5 (FIG. Forming a multi-pole system with alternating poles along a generator. The winding 17 on the bark 6 is likewise laid. In order to reduce friction losses, the inert mass 7 is provided with bushings 18 of antifriction material.

The axial movement of the stator 5 is limited relative to the housing 1 by the protrusion 19,

The percussion mechanism works as follows.

The work tool 9 is pressed through the body 1 (by the machine's manipulator) to the destructible material. At the same time, the stator 5 placed in the glass 4 moves.-To the extreme right position against the stop in the projection 19. The relative position of the stator 5 and the core 6 at the initial moment before applying the pulse to the windings 16 and 17 is shown in FIG. 2, at. Electrodynamic force arises through the cables 2O and 21 in the windings 16 and 17 after an electric pulse.

In this case, the inert mass 7 with the bark 6 and the stator 5 begin to move relative to the housing 1 in opposite directions, and the stator 5 with the cover 8 and the tool 9 moves relative to the housing 1 in the sleeves 2 and 3 and relative to the guide cylinder 10 fixed to

It has a sleeve 12. Since the resistance to the movement of the stator 5 is considerably, almost all electrical energy converted to mechanical energy on the stator 5 is transferred through the cup 4, the cover 8 and the tool 9 to the material being crushed.

At the same time, the inert mass 7 with the bark 6 and the sleeves 18 slides along the guide cylinder 10, compressing the spring 15 and acting on the rod of the damper 14, Energy, communicated to the inertial mass 7, dampens to him. Inert mass 7 is stopped and then under the action of springs; 15 returns to the starting position.

The duration of the shock pulse can be adjusted by means of a time shift between the supply of pulses to the stator winding and the core winding. When pulses are simultaneously applied to both windings, the pulse duration is equal to the nominal one.

Claims (2)

1. USSR author's certificate No. 485221, class E 21 C 37/18, 1974. 2. USSR author's certificate NO 37-2318, cl. E 02 S) 7/08, 1967.