SU962602A1 - Device for metered feed of fuel into combustion chamber of gas-pulse percussive apparatus for breaking rock - Google Patents

Description

actuation of the device dop fuel supply. Delivered by tseg Achieved by the fact that the pump injection pressure is formed by a cylindrical resiliently deformable shell, the end of which is spirally connected to the gas drive by a pair of pivoting double-link arms and carries the top catcher, while the fixture is equipped with a locking needle installed with the opportunity to interact with the plunger. FIG. 1 is a schematic diagram of a percussion device with a method for supplying fuel thereto; FIG. 2, a fuel delivery device, longitudinal section; in fig. 3 is a section A-A in FIG. 2. The percussion device (FIG. 1) includes a housing 1 with an exhaust 2 and a blowing 3 windows, inside of which is located a distribution piston 4 and a piston 5 in contact with a working tool 6. On the housing 1 a stopper mechanism 7 is mounted, which interacts with distribution piston 4, as well as the trigger mechanism 8 connected to the pneumatic chamber O of the device. The device 10 for the purpose of delivering the fuel is fixed on the housing 1 and connected by a line with the fuel tank 11 and the gas chamber 12 of the device. Inside the housing 13 of the device 1O (Fig. 2), gas channels 14 are provided, communicating with the gas chamber 12 of the device, and a cylindrical, elastically deformable shell 15, a locking needle 16, a pusher 17, a reverse valve 18, two levers 19 and 20, a membrane 21 with a rod 22 having projections 23 and 24 (FIG. 3) and a seat. 25 for a needle 16. The housing 13 of the device 10 is closed on top by a cover 26. The sheath 15 is connected through a non-return valve 18 to the fuel tank 11. The device and the metering device operate as follows. In the initial fit, the working tool 6 with the piston 5 is displaced to the right up to the stop of its end face to the end of the body 1 of the device under the action of an external tool. Using the locking device 7 and the starting mechanism 8, the device is put into operation. Compressed air is supplied to the chamber 12 from an independent source (not shown), which moves the piston 4 to the right, up to the opening of windows 2 and 3 of the housing 1, thus creating a closed volume in chamber 9 In this position, the piston 4 is fixed by a locking mechanism. Then through the trigger mechanism 8 from an autonomous source, compressed air is supplied to chamber 9 and the piston 4 is released from fixing mechanism 7, which moves to the left, closes windows 2 and 3 and compresses the air in chamber 12. Compressed air enters from it through the gas channels 14 of device 10 into its internal cavity 27 located around the shell 15 and in communication with the cavity 28 in front of the membrane 21. As a result of the action of compressed air inside the shell 15, the pressure of fuel entering it from tank 11 through a check valve-18, a the membrane 21 bends inward and through the protrusion 23 of the rod 22 interacts with the two-link lever 19. At the same time, the axis of the lever 19 passes the dead point and it instantly collapses, releasing the end of the elastically deformable shell 15, which is connected to the needle 16 by means of a high pressure The fuel and hydrodynamic forces of the needle 16 rise all the way to the push rod 17, and through the annular gap between the needle 16 and the saddle 25 the fuel is injected into the chamber 12. At the time of fuel injection, the two-link arms 19 and 20 are folded In position, the piston 4 continues to move again, and the pressure in chamber 12 increases. Thereby, an increasing force of compressed air acts on the membrane 21, as a result of which it continues to bend inwardly, the protrusion 24 of the stem 22 sets the lever 20 so that its axis goes beyond the dead point. In this case, the lever 20, having straightened, abuts one condom against the cover 26, and returns the end of the elastically deformable shell 15 and the initial position to another. The sheath 15 pushes the needle 16 through the pusher 17, which rests against the SEDLO 25, cutting off the ring chips and stopping the flow of fuel into the chamber 12 of the device. The piston 4, continuing to move to the left, squeezes the air mixture in the chamber 12 to the necessary degree of the hedgehog. what happens is its self-ignition. The pressure of the combustion products in the chamber 12 simultaneously acts on the piston 5, tool 6 and through it on the rock mass to be destroyed, as well as on the piston 4,

The tool 6 is inserted into the massif, and the piston 4 moves to the right and opens windows 2 and 3, and the gases are removed from the chamber 12 to the atmosphere. When windows 2 and 3 of housing 1 are opened, the pressure in chamber 12, in channels 1–4, cavity 27 and 28 drops sharply. Under the action of elastic forces, the volume of the cavity of the shell 15 increases and the check valve 18 opens the line connecting the cavity of the shell with the fuel tank 11, where the fuel is under excessive pressure. As a result, the cavity of the shell 15 is filled with fuel.

The membrane 21, under the action of elastic forces, takes the initial position, the lever 20 is folded, and the lever 19 is expanded, and the fuel supply device 10 is ready for operation again.

Continuing to mix to the right, the piston 4 forms an enclosed space in box 9, where air is compressed to the pressure necessary to return the piston 4 to the extreme left position. Further, the cycles of operation are repeated in the same sequence.

The application of the proposed fuel supply metering device ensures reliable operation of the device at a shock frequency above 50 Hz.

Claims (2)

1. USSR author's certificate No. 432201, cl. E 21 C 37/14, 1974. 2. Authors certificate of the USSR N 621868, cl. E 21 C.3 / 18, 1977 (prototype). FIG.