RU2050614C1 - Device for removing burrs from ends of split strip-wound magnetic circuits - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: device is, essentially, carriage mounted in guides and displacing in plane perpendicular to that of magnetic circuit feed. L-shaped lever is provided which is set in rotary motion and mounted for swinging movement in carriage plane. Cutting tools of device are abrasive wheels with flat or shaped working surface secured on shaft by means of flexible members and mounted for swinging in respect to shaft. EFFECT: improved design. 4 dwg

Description

 The invention relates to technological equipment for the manufacture of twisted tape magnetic circuits and can be used in the electrical and radio engineering industries.

 A device for deburring (ed. St. USSR N 1363314, class. H 01 F 41/02, 1988), made in the form of an annular bath with ferromagnetic powder, mounted in the housing with the possibility of rotation and equipped with electromagnets, and feeding and clamping mechanisms half rings of the magnetic circuit.

 The disadvantage of this device is that not only the side faces of the ends of the half rings of the magnetic cores are subjected to mechanical treatment with ferromagnetic powder, but also the ends themselves, which worsens their flatness, and hence the electromagnetic parameters of the magnetic circuit, i.e. its quality.

 Known devices for deburring, the main design feature of which is the use as a tool of flexible abrasive wheels (for example, Machinery and Eguipment, 1989, 21, N 110, S. 24-27).

 These devices use the adaptive properties of these circles (flexibility) when removing burrs from parts, but at the same time they have the following disadvantages: low resistance and high cost of flexible circles, the difficulty of adjusting the clamping forces, and hence the size of the bevels formed when removing burrs.

 There is also a device for deburring (ed. St. USSR N 1743875, class H 01 F 41/02, 1992), consisting of a locking mechanism with a support platform, deburring mechanisms with a drive for its reciprocating movement.

 This device is the closest in terms of functions and technical principle to the device described in the invention. It allows you to eliminate the burrs that occur when cutting the magnetic circuit on the side faces of the ends, without affecting the surfaces of the ends themselves.

 However, when deburring this device, a rather large technological effort arises from the cutting forces, which lead to the appearance of secondary burrs on the ends of the magnetic circuits (approximately an order of magnitude smaller than the removed ones), as well as when the cutting tool becomes dull to the edges and delays the extreme turns. Due to the appearance of secondary burrs, it becomes necessary to grind the ends of the magnetic cores. The large forces arising from the deburring do not allow the use of this device for processing magnetic cores from a thin tape (0.08.0.15 mm), which limits its scope.

 The aim of the invention is to improve the quality of the magnetic cores and expand the scope.

 The goal is achieved by the fact that the deburring mechanism is made in the form of a shaft having the possibility of rotation, swinging and reciprocating longitudinal movement, on which abrasive wheels with a flat working surface are fixed with the possibility of swinging relative to the shaft axis using elastic elements that transmit torque. In addition, the device is equipped with stops and drives of rotational and rocking motion.

 In order to simplify the design of the device, abrasive wheels can have a shaped working surface, in this case the swing drive is excluded.

 Figure 1, 2 and 3, 4 depict variants of a device for deburring from the ends of the magnetic circuit.

 The device of FIG. 1 and 2 includes a locking mechanism 1, a support bar 2, an emphasis 3, a carriage 4 located on the guides 5, a drive 6, a platform 7 mounted on the carriage 4 with a possibility of swinging on the axis 8, the drive 9. On the platform 7 are installed with rotation of the ball bearings on the shaft 10 and the motor 11, which are interconnected by a V-belt drive 12. On the shaft 10 with the help of elastic elements 13 are mounted with the possibility of swinging relative to the axis of the shaft 10 abrasive wheels 14, 15, 16 with a flat working surface.

 The embodiment of the device of FIG. 3 and 4 includes a locking mechanism 1, a support bar 2, an abutment 3, a carriage 4 mounted on guides 5, a drive 6. A shaft 10 and an electric motor 11 are installed on the carriage 4, which are interconnected by a V-belt drive 12. On the shaft 10 s using elastic elements 13, abrasive wheels 17 are fixed with a shaped (conical) working surface.

 The device according to figures 1 and 2 works as follows.

 The electric motor 11 through the V-belt drive 12 rotates the shaft 10 with abrasive wheels 14, 15, 16. The half ring of the magnetic circuit 18 (hereinafter the magnetic circuit) by the locking mechanism 1 moves along the support bar 2 and is pressed with its ends against the stops 3, then the actuator 6 is actuated and moves the carriage 4 from the middle position to the extreme working (left). Rotating abrasive wheels 14, 15 with lateral working surfaces are pressed against the magnetic circuit 18 and rotated due to the bending of the elastic elements by a certain angle, which, like the pressing force, depends on the stroke of the carriage 4. At the same time, the actuator 9, which swings on the axis 8, is turned on pad 7 together with the shaft 10 and abrasive wheels 14, 15, 16. The elastic clamping and rocking of the abrasive wheels allow you to process each face of the magnetic circuit along the entire length in the presence of mutual non-parallelism of the faces of the magnetic circuit and the working oskosti abrasive wheels, which can result from manufacturing errors or bazirovki magnetic circuit.

 At the end of the cycle of processing the left faces, the drive 6 moves the carriage 4 to another (right) extreme position, the other faces of the magnetic circuit 18 are processed in circles 15, 16. Then, the drive 6 moves the carriage 4 to the middle position, after which the locking mechanism 1 returns to its original position.

 The device according to figure 3 and 4 works as follows.

 The magnetic circuit 18 is pressed against the stops 3 by the locking mechanism 1, after which the drive 6 lowers the carriage 4 with the shaft 10 and abrasive wheels 17 down. The abrasive wheels 17 with their working conical surface touch the faces of the magnetic circuit and rotate by some angle due to the bending of the elastic elements 13. Moreover, each abrasive circle has a point contact with the face of the magnetic circuit, which ensures the processing of the magnetic circuit faces along the entire length, regardless of the errors of the magnetic core or its geometric deviations sizes.

 Thus, the proposed device allows you to remove burrs from the side faces of the magnetic cores, to regulate the efforts of the clamping circles to the magnetic cores and, providing the ability to select any bundles of abrasive circles, to perform efficient deburring with little technological effort. This ensures high quality magnetic circuits without cracks and delamination of the extreme turns, reducing secondary burrs. In some cases, the secondary burrs resulting from this are so insignificant that additional processing of the ends is not required.

 Small technological efforts allow the use of this device to remove burrs from magnetic cores made of thin tapes 0.05-0.15 mm thick, which significantly expands the scope of its application.

 The large adaptive capabilities provided by the selection of the stiffness of the elastic elements make it possible to effectively perform multi-place processing simultaneously in one position, which, in turn, allows to reduce the overall dimensions of the deburring device.

Claims (1)

 A DEVICE FOR REMOVING ADHESTERS FROM THE ENDS OF CUTTING TAPE MAGNETIC WIRES, including a magnetic core fixing mechanism, a support platform with bevels, stops and cutting tools, characterized in that it is made in the form of a carriage mounted on guides with the possibility of reciprocating movement in a plane perpendicular to the supply plane of the magnetic cores, L-shaped lever, on one end of which there is a shaft with a drive for its rotation, and the other mounted on a carriage with the possibility of return Atomic-vibrational movement in the plane of movement of the carriage, while the cutting tools are made in the form of abrasive wheels with a flat or shaped working surface and are fixed to the said shaft by means of elastic elements with the possibility of swinging relative to the axis of the shaft.

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