SU1511379A1 - Electromagnetic percussive machine - Google Patents

Abstract

The invention relates to the mining industry, to impact devices for drilling holes. The goal is to increase the reliability of the machine by reducing the shock loads on the machine during the reverse of the striker and at the same time using the damping energy to rotate the tool. The machine has direct coils 1 and 2 reverse electromagnets, firing pin 3 in cylinder 6. Stage 4 of punch 3 forms a cavity 8 in cylinder 6 between stage 4 and coil 2. Cavity 8 is an integral part of the hydraulic network of the tool rotating tool. consecutively connected cavities 8, channel 9, reverse hydraulic valve 13, suction main 11, reservoir 14, hydraulic engine 19, throttle 17, second reverse hydraulic valve 15, second channel 10 and cavity 8. When the machine is working during idling of the striker 3, the liquid is displaced From the cavity 8 to the hydraulic motor 19, which turns the tool 23. With the working stroke of the striker 3, the liquid is sucked into the cavity 8. 1 sludge.

Description

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The invention relates to the mining industry, in particular, to a percussion-rotary device for drilling holes, destroying solid media.

The aim of the invention is to increase the reliability of the machine by reducing the shock loads on the machine.

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together with the gearbox 22, the second channel 10 forms a tool for turning the tool 23.

Electromagnetic machine works as follows.

The coils 1 and 2 of the electromagnets are powered by current pulses, which are alternately supplied to

during the reverse course of the striker and at the same time-10 windings of these coils 1 and 2. Let us use the damping energy to rotate the tool. The drawing shows a schematic diagram of an electromagnetic machine

percussion .15

: The electromagnetic percussion machine contains the coils 1 and 2 of the electromagnet, the firing pin 3 with the step and

 Piston 5 and cylinder 6 mounted

 between coils 1 and 2.

; Piston 5, (located in cylinder 6, divides it into front 7 and rear

8 cavities, with the rear cavity 8

placed between the stage k of the piston 5 and the coil 2 of the reverse stroke of the striker 3.

The rear cavity 8 of the cylinder 6 is connected to the suction 11 and 30 pressure 12 hydro lines, respectively, via the first and second radial channels 9 and 10, which are made in the side wall of the cylinder 6. The suction hydraulic line 11 is equipped with the first reverse hydraulic valve 13 installed on the outer surface of cylinder 6 and connected to the reservoir k for the liquid, and the pressure hydraulic main 12 to the second hydraulic valve 15, hydraulic accumulator 1b, adjustable throttle 17, hydraulic ram20

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a current pulse is applied to the coil 1 of the electromagnet, and the reservoir 14 and the initial volume of the rear cavity B are filled with liquid and the firing pin 3, which is made in one piece with the piston 5, is in the position shown in the drawing. In this case, under the action of electromagnetic forces, the hammer 3 with the piston 5 moves to the right. Reverse hydrovalve 15 during this movement is closed, and the reverse hydrovalve 13 is open.

When the piston 5 moves to the right, the free volume of the cavity 8 gradually increases and a vacuum is created in it. Therefore, the liquid from reservoir k begins to flow through the suction hydraulic line 11 through the open return hydrovalve 13 and channel 9 into the rear cavity 8. This continues during the piston stroke 5. to the right. The first stroke of the striker 3 ends with a blow to the shank of the tool 23.

At the moment of impact, a current pulse is applied to the coil 2 of the electromagnet and, under the action of its electromagnetic force, the firing pin 3 with the piston 5 begins to move in reverse. move left. When this piston 5 starts

The distributor 18 and the hydraulic motor 19.40 smoothly without impact. Pressing on the incompressible fluid in the cavity 8 of the cylinder 6, as a result, the pressure in the cavity 8 filled with liquid increases. Since during this course

| installed on the side surface of the coil 1 of the forward stroke. Preventive hydraulic valve 20 communicated with reservoir I and with mainline

The liquid in the cavity 8 is cylinder 6; as a result, pressure rises in this cavity 8 filled with liquid. Since during this course

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il2. The drain of the hydraulic line 21 of the hydrodz orshn 5 return hydraulic valve 13 of the engine 19 is communicated by means of the hydraulic distributor 18 to the reservoir C, in the front part of the coil 1 case there is a gear 22, which is kinematically connected with the shank of the working tool 23 and the hydraulic motor 19.

The hydraulic system in the form of a series-connected cavity 8, the first channel 9 of the reverse hydraulic valve 13, hydraulic line 11, reservoir 14, hydraulic line 21, hydraulic engine 19, hydraulic line 12, throttles 17, the second reverse hydraulic valve 15 and

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closed, and the hydraulic valve 15 is open, the fluid from the cavity 8 through the channel, the reverse hydraulic valve 15 displaces into the pressure line 12 and further through the throttle 17 and the hydraulic valve 18 enters the hydraulic engine 19, which causes the rotation 23 of the rotation 23 through a gearbox 22, kinematically connected with Neither the waste liquid from the hydrodvigate 19 enters through the overflow pipe 21 into the reservoir 14. This continues as the piston travels to the left.

windings of these coils 1 and 2. Let

a current pulse is applied to the coil 1 of the electromagnet, and the reservoir 14 and the initial volume of the rear cavity B are filled with liquid and the firing pin 3, which is made in one piece with the piston 5, is in the position shown in the drawing. In this case, under the action of electromagnetic forces, the hammer 3 with the piston 5 moves to the right. Reverse hydrovalve 15 during this movement is closed, and the reverse hydrovalve 13 is open.

When the piston 5 moves to the right, the free volume of the cavity 8 gradually increases and a vacuum is created in it. Therefore, the liquid from reservoir k begins to flow through the suction hydraulic line 11 through the open return hydrovalve 13 and channel 9 into the rear cavity 8. This continues during the piston stroke 5. to the right. The first stroke of the striker 3 ends with a blow to the shank of the tool 23.

At the moment of impact, a current pulse is applied to the coil 2 of the electromagnet and, under the action of its electromagnetic force, the firing pin 3 with the piston 5 begins to move in reverse. move left. When this piston 5 starts

smoothly without impact. Press on incompressible fluid in cavity 8 of cylinder 6, as a result, pressure rises in this cavity 8 filled with liquid. Since during this course

Orshn 5 reverse hydrovalve 13

closed and the hydraulic valve 15 is open, the fluid from the cavity 8 through the channel 10, the reverse hydraulic valve 15 is forced into the pressure line 12 and further through the throttle 17 and the control valve 18 enters the hydraulic motor 19, which drives the tool 23 to rotate by means of a gear 22, kinematically connected with them. The spent fluid from the hydraulic motor 19 flows through the drain main 21 into the reservoir 14. This continues throughout the stroke of the piston 5 to the left.

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Pressure line 12 has a hydroaccumulator 16 designed to smooth out the fluid pressure pulsations in the pressure line 12 and uniformly supply fluid to the hydraulic motor 19. Adjustable throttle 17 serves to maintain a predetermined flow rate depending on the pressure differential in the pumped and evacuated working fluid flows . The valve 18 is designed to change the direction or start and stop the flow of working fluid in hydraulic lines depending on an external control action (for example, to reverse the rotation of the hydraulic motor 19). The safety valve 20 serves to transmit the working fluid when it reaches a predetermined pressure value.

When the striker 3 reaches its extreme rear position, during the reverse course, a current impulse is delivered to the coil 1 and under the action of the electromagnetic force the striker 3 begins to move to the right for forward travel. When this hydraulic valve 13 is open, and the hydraulic valve 15 is closed. With a gradual increase in the free volume of the cavity 8, the liquid from the reservoir 14 through the suction ma 796

the ports 11 go through the return valve 13 and the channel 9 enters this cavity 8, and the next cycle of operation repeats.

Claims (1)

Invention Formula Electromagnetic percussion machine, including a cylinder, forward and reverse coils, a firing pin in the cylinder, a working tool and a device for its rotation, characterized in that, in order to increase the reliability of the machine by reducing the impact loads on the machine during reverse during the striker and at the same time using the damping energy to rotate the tool, the striker has a stage, and in the cylinder there is a cavity with two channels, which is located between the striker stage and the return coil, e for rotating the instrument has a hydraulic network with a hydraulic motor and two reverse pidro valves, with a cavity, the first channel in the cylinder, the first reverse hydraulic valve, the hydraulic motor, the second reverse hydraulic valve, the second channel in the cylinder, the cavity in series in the hydraulic network.