SU1676748A1 - Vibratory knock-out grid - Google Patents

Abstract

The invention relates to foundry, in particular to lattices for knocking out forms. The purpose of the invention is to increase the efficiency and quality of cleaning castings and reliability of work and the expansion of technological capabilities. The knockout grill contains a frame 1 with a crossmember 4, to which a shock pulse size regulator is attached, consisting of two earrings 5, in each of which springs are coaxially arranged: one between frame 1 and exciter 8, and the other between exciter 8 and plate. The plate is mounted with the possibility of axial movement. A buffer is placed between the frame 1 and the exciter 8, which is a hollow body 12c with a shock absorber 13 and inserts 14 and 15. placed on both sides of the shock absorber 13. 1 cp f-ly, 2 ill.

Description

The invention relates to foundry, in particular to knock out grids for knocking out the molding mixture and cores from flasks and castings.

The purpose of the invention is to increase the efficiency and quality of cleaning castings and reliability and the expansion of technological capabilities.

Figure 1 shows a knocked out lattice, General view; FIG. 2 is a view A of FIG. 1.

The vibrating knockout grate contains a frame 1 with a grate blade 2. The frame 1 is supported by springs 3 and is rigidly connected to the traverse 4. To the latter is attached a shock impulse value regulator consisting of two U-shaped earrings 5, in each of which the upper and lower coaxially placed springs 6. Their ends facing each other are supported on a base plate 7 to which a vibration exciter 8 is attached with an unbalanced shaft installed in it. To preload the springs 6, plates 9 are mounted on the bottom of the earrings 5, on which the ends of the lower springs are supported 6. For axial movement of the plates 9, bolts 10 are used. The plates 9 are fixed in the required position by gaskets 11 installed between the plates 9 and the earrings 5. Between the frame 1 and a vibration exciter 8, a buffer is placed, which is a hollow body 12, along the inner perimeter of which an annular groove is made, which serves as a support for the flat shock absorber 13. The working planes of the shock absorber 13 are in contact with freely entering into the housing with 12 inserts 14 and 15, one of which (15) rests on the plate 7 of the vibration exciter 8, and the other (14) is installed with a gap relative to the beam 4 of the frame 1. · The buffer is oriented relative to the frame 1 so that its axis is located at an angle of 30 ... 45 ° to the frame and coincides with the given direction of oscillation. The housing 12 is mounted to rotate about an axis parallel to the axis of rotation of the unbalanced shaft 16 of the vibration exciter and passing through the center of symmetry of the housing located at the point of movement of its axes of symmetry. To prevent the shift of the vibration exciter 8 under the action of gravity, springs 17 are located between the vibration exciter and the bracket 18 attached to the earring 5.

The knocked out grid works as follows.

Before starting work, the vibro-shock system is set up by adjusting the magnitude of the shock pulse. For this purpose, the plates 9 are moved upward by the plates 9, compressing the springs 6. At the same time, the plate 7 with the vibration exciter 8 moves and moves the buffer leaning on it, changing the gap between the inserts 14 and the traverse. 4, which determines the magnitude of the shock pulse transmitted to the frame. Upon reaching the required gap determined by calculation, between the buffer and the frame under the plates 9, gaskets 11 are installed, fixing the position of the plates. After that, the bolts 10 can be turned out.

Turn on vibration exciter 8. When the unbalanced shaft rotates, a disturbing force is created. Under the influence of this force, the vibration exciter oscillates on the springs

6. These vibrations through the liner 15 are transmitted to the shock absorber 13, the liner 14 and lead to periodic collision of the latter with the frame 1. Since the shock absorber 13 is deformed under conditions of comprehensive compression, its normal rigidity is large and shear is small. In this regard, shock pulses of a high level are created in the normal (axial) direction, i.e. almost all the kinetic energy of the vibration exciter is transmitted in a very short period of time. This energy is transmitted to the Ti frame, respectively, to the grate and knocked out shape. There is a simultaneous movement of the form and its knocking out. At the same time, the efficiency and quality of knocking out is significantly increased with a small level of disturbing force excited by the vibration exciter. Since the shear stiffness of the buffer is insignificant (during deformation, the body rotates about an axis parallel to the axis of rotation of the unbalanced shaft 16 of the vibration exciter and passes through the center of symmetry of the body located at the intersection point of its symmetry axes), the impact forces in the direction perpendicular to the direction of oscillation of the frame are practically they are not transmitted to the frame, which ensures increased oscillations of the frame in a given direction and increased efficiency of transportation and knocking out.

The combination of shock pulses and harmonic vibrations transmitted to the frame through the elastic connections of the vibration exciter provides a wide range of acceleration on the frame and, accordingly, on the product. The components of this spectrum resonate with the individual elements of the product of different thicknesses and shapes (each at its own frequency), which improves the separation of the moldable mixture and increases the efficiency of knocking out. In this case, a low power exciter is used, the load on the bearing bearings is small and the reliability of the device is increased.

Claims (2)

Claim 1. Vibration knockout grate, containing a spring-loaded frame with a grate blade and a vibration exciter with an unbalanced shaft, connected with a frame by elastic ties, characterized in that, in order to improve the efficiency and quality of casting cleaning and reliability of work and expansion of technological capabilities, it is equipped with a shock value regulator pulse and at least one buffer mounted between the exciter and the frame coaxially with the direction of its oscillations and representing a hollow body with a shock absorber in the annular groove made on the inner surface of the housing, and two inserts placed in the cavity of the housing on both sides of the shock absorber, one of which is mounted on the vibration exciter, and the other is mounted with the possibility of periodic interaction with the frame, while the liners are mounted in the housing with axial displacement, and the body is mounted with the possibility of displacement relative to the axis parallel to the axis of rotation of the unbalanced shaft of the vibration exciter and passing through the center of symmetry of the body. 2. The lattice according to claim 1, characterized in that the regulator of the magnitude of the shock pulse is an earring with a plate in the lower part, mounted on the frame on both sides of the exciter, in each of which the upper and lower springs are coaxially placed, the upper spring being placed between the exciter and the frame, and the bottom - between the exciter and the plate. at et <? m, the plate is mounted with the possibility of axial fixed movement, and gaskets are placed between it and the lower part of the earring. Phage 2