SU1590238A1 - Arrangement for dimensional electric machining - Google Patents

Abstract

The invention relates to mechanical engineering, in particular, to electrophysical methods of metal processing, and can be used on EDM or electrochemical machines with an open drive for feeding an electrode tool. The purpose of the invention is to increase productivity by reducing the time to set up the machine. A system for monitoring the magnitude of the displacement of the center of oscillations of the moving part of the vibrator carrying the electrode tool is installed on the feed drive carriage. The monitoring system is connected with the system of stabilization of the center of oscillations, which is connected with the movable part of the vibrator through the unloading mechanism. To eliminate the rigid action on the movable part of the vibrator, the discharge mechanism is made in the form of an elastic element. The control system contains a sliding bracket, a linear displacement sensor and an indicator plate mounted on the movable part of the vibrator. The elements of the sliding bracket have the opportunity in the adjustment mode to be spread by a distance equal to twice the amplitude of oscillations of the movable part of the vibrator. 1 hp f-ly, 7 ill.

Description

The invention relates to mechanical engineering, in particular, to electrophysical methods of metal processing, and can be used on electroerosive or electrochemical machines, the drive of which the electrode-tool is fed is open-circuited.

The aim of the invention is to improve the performance of the device by reducing the time for its adjustment.

Figure 1 shows a diagram of a device for dimensional electrical processing; FIG. 2 is a section A — A of FIG. 1; in FIG. 3, node j in FIG. 1, in FIG. 4 is a view B in FIG. 3; in FIG. 5 a section B - C in FIG. 3; in fig. 6- device for monitoring the displacement of the center of oscillations of the system (electrode-tool)

an embodiment; FIG. 7 shows a section G-f in FIG. 6,

The device consists of a feed drive 1, on the carriage 2 of which the electromagnetic vibrator 3 and the actuator 4 with electric drive 5 are rigidly fixed. The electromagnetic vibrator 3 consists of the housing 6, on the upper part of which the mount 7 is fixed to the AC coil 8, In the lower part of the housing 6 on an elastic suspension, consisting of membranes 9 and 10, mounted along one side of the vibrator, consisting of a core 11 with electrode holder 12 and electrode-tool 13 fixed on it, electrode holder 12 for the purpose of mounting wounds of parasitic angular oscillations of the electrode-tool 13 is placed in a ball direction

00

SCRATCHES14. On the bark 11, an elastic flat spring 17 of the unloading mechanism with a lever 18, a pusher 19 and a pressure screw 20 is mounted on the bark 11 with tg 15 and 16. The actuating mechanism 4 consists of a housing 21 in which a nut 22 is mounted with a sliding bearing 23 and with the possibility of rotational movement thrust bearings 24. A nut 22 is kinematically connected to an electric drive 5 by a gear 25. A screw 26 with a splined section having a spherical end surface is placed inside the nut 22. The slotted portion of the screw 26 is located in the slotted hole of the guide sleeve 27 fixed in the housing 21, and the spherical surface of the screw has the ability to interact with the lever 18. On the electromagnetic vibrator 3 a device for controlling the center of oscillation of the system oscillations is installed — an instument electrode (Fig. 3-5 ). The movable element of the device is mounted on the m 16 and consists of a coupling 28 and a plate 29, rigidly interconnected. The measuring equipment of the device is mounted on the housing 6 of the electromagnetic vibrator 3 by means of a bracket 30 and consists of a housing 31 and a sensor 32 of linear displacements mounted on the bracket 30. The housing has two coaxially arranged openings extending into a cutout made on one of the walls and two perpendicular To them are holes that terminate with threads. Measuring rods 33 and 34 are rigidly mounted in the axial holes, rigidly connected respectively to the arms Зь and 36. The levers have longitudinal grooves in which they are placed in Int 37 with a nut 38, Measuring rods 33 m 34, rigidly interconnected through levers 35 and 36 q with the help of a screw 37 and nuts 38, constitute a single measuring element. Measuring rods 33 and 3 are elastically pressed against body 31 by friction linings 34 by means of spring 40 and gland screws 41 placed in openings of body 31. The movable element and measuring equipment of the device are mounted on vibrator 3 so that the plate 29 is placed in the cut-out of the body 31, between the measuring rods 33 and 34, the sensor 32-linear displacement is fixed on the plate 42, with which it is mounted. Ruetts on the bracket 30 with the ability to adjust the contact force of the measuring tip of the sensor 32 with the measuring rod 33. The output of the sensor j2 linear displacement is connected to the input

block 5 control actuator actuator 4.

The device works as follows.

A device for monitoring the magnitude of the displacement of the center of oscillation of the system (electrode tool) is preset. To do this, loosen the screw 37 to release the levers 35 and 36. The vibrator 3 is put into operation. In this case, the movable part of the vibrator (koryu .11, the electric holder 12, the electrode tool 13, t d

15 and 16) oscillatory movement with an operating frequency and amplitude is reported. Clutch 28 with plate 29 is also associated with oscillatory movement. Plate 29 pushes the measuring rods 33 and 34 in different directions, together with them moving forward. This process continues until the measuring rods 33 and 34 are at a distance of the magnitude of the oscillation amplitude from the contact. the plate 25 surfaces that mate with them. 29. After that, the translational movement of the rods 33 and 34 is stopped, and their position is fixed and held by spring-loaded friction lining 39. The position of the rods 33 and 34 corresponds to the extreme positions of the contacting surfaces of the plate 29 in its oscillatory movement, In this position, the measuring rods 33 and 34 are rigidly connected into a single measuring element with the help of a screw 37 and a nut 38, the linear displacement sensor 32 is set to the neutral position, when Oromo electric NRHODITSYA 5 in the off position. When the machine 40 is turned on, the carriage 2 of the feed drive 1 with the electromagnetic vibrator 3 fixed to it with the electrode tool 13 is pushed towards the workpiece. The working fluid supplied to the interelectrode gap 45 creates a force Q acting on the electrode tool 13. This force displaces due to the deformation of the elastic membranes 9 and 10 the center of oscillation of the moving part of the vibrator (core 50 11 of the electrode holder 12, electrode tool 13, t 1 -15 and 16, the plates 29 with the coupling 28) in the direction of the magnetic circuit 7, At the same time, oscillating from the plate 29, the center of oscillation of which is shifted in the direction of the measuring rod 33, acting on it, progressively moves it along with the rod 34 towards sensor 32. Yes 1pc 32 under the influence of the rod 33 comes out of the neutral position and issues a command signal to the flea control drive 5

actuator 4; Electric drive 5 is activated. Movement from the electric drive 5 through the gear 25, the nut 22 is transmitted to the screw 26, which in the splined guide bushing 27 moves towards the lever 18, is affected by a spherical end surface. Lever 18 rotates. When this push the screw 20 through the plunger 19 transmits the force P on the flat spring 17 of the discharge mechanism and deforms it by the value b. Through the deformation of the flat spring 17, the force P is transmitted through the pulls 15 and 16 to the moving part of the vibrator. The operation of the electric drive 5 and, consequently, the movement of the screw 26 towards the lever 18 continues: until the force P, depending on the magnitude of the deformation, becomes equal to the force Q from the electrolyte pressure, and the oscillating center moves the vibrator part to the initial position. At the same time, the oscillation center of the plate 29 is now returning to the side of the measuring rod 34. Under the influence of the oscillating plate 29, the measuring rod 34 begins to move progressively towards the sender 32, and the measuring rod 33 is also carried along. The rod 33 follows the rod 33. sensor tip 32. Sensor 32 returns to the neutral position and issues a signal command to turn off the actuator 5. Plastic 29 performs oscillatory movements with a working amplitude the gap h between the rods 33 and 34. At the same time, the rods 33 and 34 (measuring element) remain at rest, With a further increase in the force Q acting on the electrode tool, depending on the increase in the machining area (for example, when machining conical holes) or an increase in electrolyte pressure, everything repeats in the same order. In case of electrolyte pressure drop in the interelectrode gap a (Fig. 2), the force Q on the electrode tool 13 decreases, and the force P of the deformed spring 17 remains the same. Therefore, under the action of the force P () of the flat spring 17, the deformation of the membranes 9 and 10 occurs in a different direction. The center of oscillation of the moving vibrator shifts in the opposite direction from the magnetic circuit 7. The plate 29 simultaneously with oscillatory movement moves progressively towards the measuring rod 34. Under the oscillation plate 29, the measuring rod 34 and the fixed rod 33 fixed with it are progressively removed The transmitter 32. The latter issues a signal command to the drive control unit 5. 5 The actuator 5 is activated in the reverse direction. The screw 26 from the actuator 5 receives a reverse movement, moving away from the lever 18. The magnitude (5 of the deformation of the flat spring 17 decreases due to

10 which also reduces the counterbalancing force R. Under the influence of the elastic forces of the deformed membranes 9 and 10, the center of oscillation of the moving part of the vibrator a returns in the direction of the magnetic conductor 7.

15 This process continues until such time as the force P becomes equal to the force Q and the oscillation center of the moving part of the vibrator returns to its original equilibrium position. During this period, the plate 29, acting on the measuring rod 33, returns it with the rod 34 to its original position, approaching the sensor 32, which returns to the neutral position and issues a trip command signal

5 drive 5. The same happens at the end of processing. With respect to this equilibrium position, oscillatory displacements occur with a constant amplitude of the tool electrode. With

0 this, the membranes 9 and 10 are not deformed, the air gap I between the stationary magnetic core 7 and the core 11 retains the original value, the position of the tool electrode is stabilized, the oscillation center of the tool electrode and the interelectrode gap a are stabilized. Figs 6 and 7 show a second embodiment of the proposed device for monitoring the displacement of the center of oscillation of the system.

0 (electrode tool), consisting of parts that perform the same function as the first option, although some of them are structurally different from each other. They are denoted by the same positions. The device according to the second embodiment consists of a housing 31, in the slot of which is installed by means of an axis 43 the levers 35 and 36 with measuring lugs 33 and 34. The levers 35 and 36 have grooves in which a screw 37 with a nut is placed

0 38. The lever 33 is in contact with the sensor 32. The levers 35 and 36 are resiliently pressed against the body-31 by the friction linings 39 with the help of springs 40 and gland screws 41. Between the measuring :: 1 protrusions 33 and 34 there is a lolsea plate 29.

The device according to the second variant works similarly to the first one. By loosening the screw 37, the levers 35 and 36 are released. The vibrator 3 is turned on. The vibrating plate 29, which is rigidly connected with the bark 11, acts on the measuring protrusions 33 and 34, pushes the levers 35 and 36 in different directions relative to the axis 43 by the amount of oscillation of the plate 29, until the movement of the levers 35 and 36 stops. The position of the levers 35 and 36 is fixed and held by spring-loaded pads 39. In this position, the levers 35 and 36 are rigidly connected by a screw 37 and a nut 38. When the center of oscillation of the system is shifted, plate 29 acts on one of the measuring protrusions 33 or 34 and rotates about the axis 43 in one direction or another, the measuring element consisting of rigidly connected levers 35 and 36 with measuring protrusions 33 and 34. In this case, the sensor 32 is triggered. The use of this device allows the feedback method to provide reliable stability zatsiyu oscillation center electrode - as in tool change processing area and when changing the pressure of the electrolyte, and conduct processing different sizes of parts without changeover device.

Ф о р м. Ула и 3 о б рёт and 1. Device for dimensional electrical processing, containing a drive for feeding an electrode-instrument, an electromagnetic vibrator rigidly mounted on a carriage

supply, stabilization center of oscillations of the movable part of the vibrator carrying the electrode-tool, an unloading mechanism made in the form of an elastic element connected with the movable part of the vibrator and the stabilization system, characterized in that the purpose of improving the performance of the device by reducing its time

the adjustment, the displacement center of the oscillation center of the moving part of the vibrator is installed on the feed drive carriage, and the stabilization system is made in the form of a drive, the output link of which is associated with the unloading mechanism, the stabilization system associated with the displacement magnitude control system.

2. The device pop. 1, is different from the fact that the control system consists of

body, sliding bracket, elastically podzhOTOf to the body and made in the form of two

elements installed with the possibility

adjustment mutual movement. indicator plate mounted on the movable part of the vibrator with the ability to interact with the elements of the sliding bracket, and the sensor linear displacements installed with the ability to interact with the elements of the sliding bracket.

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Claims (2)

Claim 1. Device for dimensional electrical processing, comprising a feed drive for an electrode-tool, an electromagnetic vibrator, rigidly fixed to a feed drive carriage, a system for stabilizing the center of oscillation of the moving part of the vibrator carrying the electrode-tool, a discharge mechanism made in the form of an elastic element connected with a movable part of the vibrator and the stabilization system, characterized in that, in order to increase the performance of the device by reducing the setup time, a con Rola magnitude oscillation center bias the movable part of the vibrator mounted on the carriage drive system and the stabilization system is configured as a drive output member which is connected with a discharge mechanism, wherein the stabilization system is associated with the displacement of the control system. 2. The device according to claim 1, with the fact that the control system consists of a housing, a sliding bracket, elastically pressed to the housing and made in the form of two elements installed with the possibility of mutual adjustment, an indicator plate mounted on the movable part of the vibrator with the possibility of interaction with the elements of the sliding bracket, and a linear displacement sensor installed with the possibility of interaction with the elements of the sliding bracket. Fiyo. 1 A Aa Fig. G See See See 'Ch Οι view 6 b Phys. 4 AT 8 6 39 FIG. 5