SU1608341A1 - Device for electrohydraulic rock drilling - Google Patents

Abstract

The invention relates to the mining industry, is intended for electro-hydraulic drilling and can be used in the construction of underground structures. The purpose of the invention is to increase the efficiency by utilizing the energy of the discharge. The device comprises a housing 1 with a rock-breaking tool 2, a working cylinder 3 with a shock piston (P) 4 and an electric discharge chamber (ERC) 5, a current pulse generator (HIT) 6 with a controlled discharge voltage 7, an expansion cylinder 8 C P 9, connected with the converter 10 of mechanical energy into electrical energy, inlet 11 and exhaust 12 windows and a device 13 for supplying fuel and oxidant to ERK 5 with a controllable valve. Moreover, ERK 5 is equipped with electrodes 24 and 25 connected to the output of HIT 6, and filled with working fluid 27. Converter 10 is connected to the input of HIT 6 and is designed as a double-acting hydraulic turbine and electric generators. The movable elements of the controlled discharger 7 and the fuel pump are installed with the possibility of interaction with the P 9. When current pulses are applied between the electrodes 24 and 25, a growing streamer arises and a cavitation cavity is formed into which the fuel and the oxidizer are fed. The resulting vapor and gaseous products of combustion of the fuel expand in the piston cavity 61 as P 9 moves upwards. The movement of P 9 is converted into a rotation by the water turbine 40. The shock waves of ERK 5 provide drilling of rocks due to the impacts of the hemispherical striker 23 of the shock P 4 and the generation of vibration pulses. 5 il.

Description

The invention relates to the mining industry, in particular to electro-hydraulic drills, and can be used in the construction of underground structures in rocks of medium and high degree of strength.

The purpose of the invention is to increase the efficiency by utilizing the discharge energy.

Figure 1 shows the proposed device, a longitudinal section; in fig. 2 - electrical circuit diagram of the current pulse generator; on fig.Z - the fuel pump, a longitudinal section; figure 4 is a converter of mechanical energy into electrical energy; Fig. 5 is a fragment of a scan of a two-way hydraulic turbine.

The device for electrohydraulic drilling of rocks includes a housing 1 with a rock-cutting tool 2, a working cylinder 3 with a shock piston 4 and an electric discharge chamber 5, a generator of 6 current pulses with a controlled discharge 7, an expansion cylinder 8 with a pore 9 connected with a converter of mechanical energy into electrical energy 10, inlet 11 and exhaust 12 windows, and a device 13 for supplying fuel and oxidant to the electric discharge gap 14 with a controllable valve 15.

The housing 1 has upper adapters 16 and 17 for connecting to a drill rod consisting of coaxially arranged external and internal drill pipes, and a lower adapter 18 for connecting to a rock cutting tool 2, the type of which is selected depending on the category of rocks for drillability.

The working cylinder 3 in the lower part has a cavity 19 with a spring 20, filled with brake fluid 21, ensuring the return of the shock piston 4 to its original position. Impact piston 4 is equipped with sealing rings 22 and hemispherical striker 23.

The electrical discharge of the chamber 5 is provided with electrodes 24 and 25 connected to the output 26 of the generator 6 of current pulses and filled with working fluid 27. To reduce the wetting area, the electrodes 24 and 25 are enclosed in dielectric sleeves 28 and 29, for example, from polyethylene. As the working fluid 27, technical water can be used. In order to compensate for the loss of the working fluid 27, a cranked channel is provided connecting the internal cavity 30 of the electric discharge chamber 5 with a source (not shown).

The current pulse generator 6 consists of a high-voltage rectifier 31, including a three-phase boost transformer 32 and semiconductor power diodes 33, a storage capacitor 34, a controlled discharger 7 with a movable element 35 and high-voltage interlocks 36 and 37. The movable element 35 is installed in the expansion cylinder 8 with the ability to interact with its piston 9 in the process.

The expansion cylinder B is mounted on the electric discharge chamber 5 and is open in the direction of the electric discharge gap 14. The piston 9 is provided with sealing rings 38.

A mechanical-to-electrical energy converter 10 is connected to the input 39 of the generator 6 of current pulses and G is made in the form of a two-sided hydraulic turbine 40 installed in the over piston cavity 41 of the expansion cylinder 8 and electric generators 42 located in the central body 43 of the turbine 40. The hydraulic turbine 40 has two-sided action symmetrical with respect to the plane 44 of rotation of the blade 45-47 of the rotor 48 and guide vanes 49 and 50. The rotor 48 of the turbine 40 is rotatably mounted around the longitudinal axis 51 of the expander cylinder 8 by means of bearings 52 and 53. The rotors 54 of the electric generators 42 are connected to the rotor 48 of the turbine 40 by means of a tubular hub 55 through which the rod 56 is passed, fixed on the piston 9 and provided with a cover 57. The connection of the piston 9 to the hydro turbine 40 is performed by the column 58 of the liquid filling the supra piston cavity 41. The connection of the converter 10 to the input 39 of the generator 6 current pulses is achieved by connecting the output terminals of the electric generators 42 to it by means of power cables (not shown).

The inlet ports 11 are communicated with the central channel 59 by means of the pipeline 60 and serve to feed the fresh piston atmospheric air into the piston cavity 61 of the expansion cylinder 8. Outlet ports 12 posts; peripheral channel 62 via conduit 63 and serves to remove exhaust gases. Outlet ports 12 are located slightly below inlet ports 11 to allow purging of the piston cavity 61 in a valveless gas exchange loop.

A device 13 for supplying fuel and an oxidizer to an electric discharge gap 14 is made in the form of a fuel pump 64 containing a plunger 65 with a spring 66, a pusher 67 with a lever 68 cooperating with the piston 9 of the expansion cylinder 8, a fuel supply channel 69 provided in electrode 24 , controlled by the valve 15 and the adjusting needle 70 with a latch 71. The inlet of the fuel pump 64 is connected to the fuel supply tank 72 via a pipe 73.

When used as an oxidizer for atmospheric air, a pipe 74 is provided connecting the electrical discharge gap 14 with the sub-piston cavity 61 through a channel (not shown) in the electrode 25 and an air valve 75.

To start the device, a head 76 is provided, mounted on the cover 57, which serves to initially raise the piston 9 of the expansion cylinder 8 with the help of a catcher, which is lowered along the drill string on the rope.

A device for electro-hydraulic drilling of the ropHi.ix rocks works as follows.

The working bodies and agents of the device are the working fluid 27, for example, technical water, filling the electric discharge chamber 5, filling the pre-piston cavity 41, liquid 58, 45, for example, low-grade mineral oil. The working fluid 27 is poured into the electric discharge chamber 5 and fills its internal cavity 30 through a bent channel (not shown).

50 Electric current is generated by electric generators 42 driven by a double-acting hydro turbine 40 and supplied to input 39 of the generator 6 current pulses via power cables (not shown) to charge accumulative capacity 34. Fluid 58 of the piston cavity 41 interacts with the turbine 40 bilateral action. B- the result of reciprocating movement of the piston 9 in the expansion cylinder 8, a column of fluid 58 of the over-piston cavity 41 performs harmonic oscillations and causes the rotor 48 of the hydraulic turbine 40 of double-sided action to one-sided uniform rotation. 5The current pulses are produced by the current pulse generator 6 as a result of the fast discharge of the precharged storage capacitor 34 through the controlled discharge 7 and fed to the electrodes 10 24 and 25 of the electric discharge chamber 5 filled with the working fluid 27 when the piston 9 of the expansion cylinder 8 reaches bottom dead center (nmt).

The fuel comes from the fuel supply tank 72 through the pipeline 73 and is injected under high pressure by the fuel pump 64 through the channel 69 into the cavitation cavity of the electric discharge gap 14 together with compressed atmospheric air at the moment of the lever 68 interacting with the piston 9 of the expansion cylinder 8 located near the n.m.

Atmospheric air enters through the central channel 59, the pipeline 60 and 5 inlet ports 11 and the sub-piston cavity 61 of the expansion cylinder 8 as the piston 9 moves upwards to the top dead center (rm), is compressed in the sub-piston cavity 61 of the expansion cylinder 8 when moving - 0 Research Institute of piston 9 down to m.t. and partly enters the cavitational cavity of the electric discharge gap 14 together with the fuel through the pipe 74 and the air valve 75. When the piston 9 5 moves down to m.t. The level of working fluid 27 in the internal cavity 30 of the electric discharge chamber 5 remains unchanged due to the resistance of the spring 20 and brake fluid 21 in the cavity 19. 0 An electric discharge occurs in the internal discharge 30 of the electric discharge chamber 5 filled with working liquid 27 and the electrical discharge of the electric discharge gap 14 current pulses that are applied to the electrodes 24 and 25 from the generator 6 current pulses.

Electro-hydraulic shock waves occur in the working fluid 27 which fills the internal cavity 30 of the electric discharge chamber 5 as a result of the thermoelectrohydraulic effect, and mechanically act on the shock piston 4, which, having overcome the opposition of the spring 20 and the brake fluid 21 in the cavity 19, is hemispheric 23. through the rock-breaking tool 2, it hits and destroys the rocks at the bottom of the well. In this case, vibration pulses of a wide frequency range are generated, intensifying the drilling process.

Steam and gaseous products of combustion are formed in the cavitation cavity and in the piston cavity 61 of the expansion cylinder B when the piston 9 is near the NMT, as a result of the interaction of the working fluid 27, atmospheric air and sprayed fuel with electrical discharge, evaporation of the working fluid 27 and burn fuel. Steam and gaseous products of fuel combustion have a large internal energy due to the transformation of the chemical energy of the fuel and the electromagnetic energy of the electric discharge into heat. When they expand into the piston cavity 61 of the expansion cylinder 8, the internal energy is transformed into mechanical work and the piston 9 together with a column of fluid 58 moves upwards to mt.t. accumulates potential energy, which passes into kinetic energy as the piston 9 moves along with the column fluid 58 down to n.mt and consumes both the rotation of the rotor 48 of the hydraulic turbine 40 of two-sided action and the rotors 54 of the electric generators 42, and the compression of the atmospheric air in the piston cavity 61 of the expansion cylinder 8.

The exhaust gases are formed from the vapor expansion cylinder 8 expanded in the piston cavity 61 and the gaseous products of the combustion of fuel and are ejected when the piston 9 moves upwards to the engine weight. through the exhaust port 12, the pipe 63, the peripheral channel 62 and the drilling camp.

The brake fluid 21 filling the cavity 19 ensures that the level of the working fluid 27 in the electric discharge chamber 5 remains unchanged when the piston 9 moves down to mt.t. and return shock piston 4

after striking the initial position when the piston 9 of the expansion cylinder 8 moves upward to the engine weight meter.

The dynamics of the combined thermoelectric-hydraulic process is as follows. As a result of electrical breakdown of the electric discharge line Kutka, a growing streamer arises, a cavitation cavity is formed, into which the atomized fuel and compressed hot air is supplied, the cavitation cavity increases, reaches the surface of the working fluid 27 and communicates with the piston cavity 61 of the expansion cylinder 8, forming steam the working fluid 27 and the gaseous products of the combustion of fuel expand in the piston cavity 61 of the expansion cylinder 8, and the cavitation cavity collapses.

In the proposed device, a combined thermo-electro-hydraulic cycle is carried out, consisting of a thermodynamic cycle with internal heat supply and a steam-power cycle, which create conditions for the implementation of an electro-hydraulic cycle. In turn, the electrohydraulic cycle creates the prerequisites for the implementation of a thermodynamic cycle with internal heat and steam power supply.

Claims (1)

Invention Formula A device for electrohydraulic drilling of rocks, comprising a housing, an operating cylinder with a shock piston and an electric discharge chamber, the electrodes of which are connected to the output of a current pulse generator by means of a controlled discharge element with a moving element, and a rock cutting tool, characterized in that In order to increase the efficiency due to utilization of the discharge energy, it is equipped with an inlet and outlet windows with an expansion cylinder with a piston, a converter of mechanical energy into electrical and a device for supplying fuel and an oxidizer to an electric discharge chamber with a controllable valve having a movable element, the expansion cylinder being made open to the electric discharge chamber and mounted above it, and its piston connected to a converter placed in the expansion cylinder current pulses, while the movable elements of the controlled spark gap and the controlled valve are installed in the housing c. possibility of interaction with the piston of the expansion cylinder. FIG. 2 2ff Phage .З 15 50 tfl five/ usM