SU1540929A1 - Vibration moulding machine - Google Patents

Abstract

The invention relates to foundry, in particular, to machines for the manufacture of foundry molds. The purpose of the invention is the expansion of technological capabilities, increasing the load capacity, improving the reliability and durability of the structure. The molding machine consists of a bed with the upper 1 and lower 2 crossbars, fastened together by columns 3. Independent hydro-pulse drives of hydraulic motors 4 and 5 of torsional and vertical oscillations of the desktop, respectively, are located between the upper 1 and lower 2 crossbars. The hydraulic motors 4 and 5 are fixed on the upper crossbar 1, their plungers with intersecting axes are located respectively in the vertical and horizontal planes. The plungers with spherical convex ends interact with the working table by means of sliding supports, the sliding bearing of the plunger of the vertical vibration motor being rigidly fixed on the working table, and the support 23 is seated freely on the vertical axis 27 of the bracket 28 fixed on the working table. The returning of the working table to the initial position is carried out by spring mechanisms pivotally connected, respectively, with the upper cross member 1 by the working table. The clamp bearing 23 to the end of the plunger of smaller diameter. Compliance with the regulated value of the angle of inclination of the generatrix of the conical surfaces of the workpiece provides increased accuracy of the geometric dimensions of the steps of the package. 5 dwg., 1 tbl.i.malayt.szubkova621.73.73 technological capabilities by reducing the force of deformation during the design of the protrusion, reducing the complexity and metal consumption in the manufacture of the workpiece. Placing s

Description

drives of hydraulic engines of 4 and 5 torsional and vertical oscillations pa--; The boar table, respectively, are located between the upper 1 and lower 2 crossbars. The hydraulic motors 4 and 5 are fixed on the upper crossbar 1, their plungers with intersecting axes are located respectively in the vertical and horizontal planes. The plungers with spherical convex ends interact with the working table by means of sliding bearings, the sliding bearing of the plunger of the vertical motor hydraulic motor being rigidly fixed on the working table, and the bearing 23 is seated freely on the vertical axis 27 of the bracket 28 fixed on the working table. The return to the initial position is carried out by spring mechanisms, which are hingedly connected, respectively, with the upper crossbar 1 by the working table. The clamp support 23 to the end of the plunger 22 provides a T-shaped lever 24, to the arms of which are connected spring mechanisms.

The fixing of the flasks on the desktop is provided by conical mounting sleeves 21, in the axial hole of which the piston rods with flat clamping jaws are missed. The angular rotation of the rods is provided by curved grooves in the guide sleeves 19 and the pins 20 fixed on the rods, 3 hp. f-ly, 4 ill.

The invention relates to foundry, in particular, to machines for the manufacture of foundry molds.

The purpose of the invention is to expand the technological capabilities, increase the load capacity, increase the reliability and durability of the structure.

On the fit, 1 shows the proposed car, front view; in fig. 2 - the same, top view; in fig. 3 shows section A-A in FIG. 2; in fig. 4 is a section BB in FIG. 3

On the frame (Fig. 1), consisting of the upper cross member 1 and the lower cross member 2, interconnected by columns 3, hydro pulse drives are mounted. On the upper cross member 1, a case of hydraulic motors 4 (hydraulic cylinders) of torsion and a case of a hydraulic engine 5 of vertical oscillations are fixed, and a pump station of a hydro-pulse drive of torsional vibrations is mounted. The pump station of the hydro-pulse drive of vertical oscillations is mounted on the lower crossbar 2, both independent pumping stations consisting of electric motors 6, couplings 7 and pumps 8, are located between the upper and lower crossbars 1 and 2 of the station.

Generators 9 pulses of pressure of a liquid by means of transitional plates 10 in a plug-in design are installed on the ends of hydraulic motors (Fig. 3).

five

0

five

0

five

0

five

The work table 11 is also mounted on a frame and pivotally connected to the upper crossbar 1 by spring mechanisms 12 with an adjustable amount of pressing force, evenly distributed around the perimeter of the table. In the central part of the table 11 along its axis, the slide bearing 13 is rigidly fixed, which, with its concave spherical surface, rests on the convex spherical surface of the plunger 14 end face of the vertical oscillation hydraulic motor. The guides of the working table are made in the form of cylindrical rings mounted in a telescoped manner: the inner ring 15 and the outer ring 16, the first of which is rigidly fixed on the upper crossbar 1, and the second on the working table 11.

On the work table 11, from the side of the upper cross member, the bodies of piston hydraulic motors 17 of the clamps of the flasks are fixed, and their rods are passed through the table apertures and equipped with flat cams 18. The guide sleeves 19 are provided with side curvilinear grooves through which the pins 20 mounted in the radial holes rod hydraulic motors 17 clamps clamps. The placement of the hydraulic motors on the surface of the working table 11 and their number n are set depending on the configurations of the windows and the conditions of its attachment. The guide sleeves 19 are fastened to

five

the outer surface of the table 11 by means of conical installation vlok 21. Spherical end of the plunger

22 hydraulic motor of torsional vibrations is in contact with the spherical surface of the slide support 23

(Fig. 4) and is pressed against it by means of a T-shaped lever 24, which swings relative to the support 23, slides on the axis 25 and is pivotally connected to the torsional vibration motor housing 4 symmetrically arranged (relative to the axis of the plunger 22) by spring mechanisms 26 with adjustable force clamping. Support

23 is freely slid on the vertical axis 27 of the bracket 28.

The machine works as follows.

The parameters of torsional and vertical oscillations of the desktop are pre-set. Parameters are set experimentally or calculated according to the given physical and mechanical shape characteristics at the initial and final moments of compaction. The adjustment for this mode is ensured by means of appropriate generators 9 pulses of fluid pressure (choice of frequency and amplitude of oscillations) and adjustment of the tension force of spring mechanisms 12 (amplitude of vertical oscillations and acceleration of the table) and 26 (angle of rotation of the working table and angular acceleration).

On the work table 11, a flask (not shown), which is self-mounted on conical mounting sleeves 21, is placed. By providing a supply of fluid under pressure into the rod cavity of the hydraulic motors 17 of the flask clamps, axial movement with angular rotation causes movement of the hydraulic motors, which are fixed and pressed by cams 18 a worktop to a work table 11. The angular rotation of the rods is provided by curved grooves on the guide sleeves 19, which include pins 20 rigidly fixed in the radial holes on the rods. Then, in accordance with the requirements of the compaction process, the molding sand is turned on (simultaneously or sequentially) the electric motors 6 hydropulse drives of torsional and vertical vibration hydraulic motors. As a result

0

five

0

five

with

0

five

0

0

five

In order to supply the working fluid in the cavities of the hydraulic motors, the plungers 14 and 22 move by a certain amount (the plunger stroke) overcoming the opposition of the spring force of the spring mechanisms 12 and 26, the friction force, and the gravity force (plunger 14). The stroke of the plungers 14 and 22 is set respectively by the maximum pressure Pv max, Rcmax R cavities of vertical and torsional vibration hydraulic motors, determined by the setting of the response of the generators 9 liquid pressure pulses, at which the cavities of the hydraulic engines 9 are connected to the drain by means of the generators 9. The pressure in the systems of hydropulse drives of hydraulic motors 5 and 4 of vertical and torsional vibrations drops, respectively, to the value of RVmin, PKMW) and the plungers 14 and 22 under the action of spring mechanisms 12 and 26 move to their original position. Repeated operation of the generators 9 pulses of fluid pressure occurs automatically after disconnecting the cavities of the hydraulic motors 4 and 5 from the drain and when pressure is set to the value of p P

- I il vr t V

8 max g K Alaks

Vertical oscillations of the desktop 11.

At the moment of the working stroke, the plunger 14 with its spherical convex end part interacts with the concave surface of the slide bearing 13, which under the action of axial force moves in the inner ring 15 of the cylindrical guide fixed rigidly on the upper crossbar 1. This causes the vertical movement of the working table 11, fixed on the shoulder support 13 slip. The table 11 is pressed against the slide support 13 (in addition to the force of gravity) by the elastic forces of the springs of the spring mechanisms 12 hinged at one end on the upper crossbar 1 of the bed and on the other end on the table 11. Possible distortions of the work table 11 relative to the vertical axis are compensated by the spherical conjugation of the end a plunger 14 and a slide bearing 13. The vertical movement (oscillation) of the work table 11 is provided by the outer ring 16 of the cylindrical guide, which is fixed to the work table. The implementation of the support 13 slip in the form

The bronze plug is determined by the antifriction properties of this material and the conditions of its loading during the operation of the molding machine.

Torsional vibrations of the desktop 11.

The plunger 22 under the action of the torsional oscillations of the pressure pulses generated by the hydraulic pulse drive of the hydraulic motor 4, produces a fluid that performs periodic reciprocating movements in the horizontal plane. The plunger 22 is driven forward by increasing the pressure in the system of the hydroimpulse hydraulic engine 4 torsional vibrations (at the moment of the generator 9 and the connection of the cavity of the hydraulic engine 4 with the drain). The angular displacement of the table 11 is eliminated by means of spring mechanisms 26, which return to their original position (reverse stroke) and plunger 22. Periodic angular displacements of the desktop 1.1 are obtained by periodically activating the generator 9.

As the shape is compacted, the torsional and vertical vibration motors turn off simultaneously or in the sequence determined by the requirements of the process.

The use in the proposed technical solution of independent hydro-pulse drives of vertical and torsional oscillations hydraulic motors with individual generators of fluid pressure pulses allows to significantly expand the limits of adjusting the parameters of vertical and torsional oscillations of the working table by the chamber. Independently adjust, for example, the frequencies of vertical and torsional vibrations, their amplitudes, accelerations, use only torsional vibrations or only vertical vibrations. Such a wide choice of possible combinations of multidirectional oscillations makes it possible to significantly intensify the process of mold compaction, regardless of the complexity of the model configuration.

The use in the proposed construction of independent adjustable spring plunger mechanisms of the hydraulic motor for torsional oscillations of the table allows to adjust its angular accelerations, which contributes to the process

five

0

five

0

compaction of the form, increasing its strength and uniform strength.

The use of hydraulic slide supports with spherical mating surfaces as axial force transmitting plungers eliminates the influence of table skews and the possibility of plungers jamming, which significantly increases the working capacity of the vibrating molding machine.

Exclusion from kinematic chains

vibration molding machine bearing ball bearing units, allows to increase the reliability and durability of the structure, working in conditions of intense dynamic loads.

Making clamps of the flasks of the vibrating molding machine in the form of piston hydraulic motors, the rods of which are passed through the conical mounting sleeves and have the possibility of angular rotation at a given clamping angle, allows to ensure the reliability of the machine as a whole and to exclude the possibility of the mold breaking when the flask is detached.

Claims (4)

1. A vibratory molding machine primarily for the manufacture of casting molds, comprising a frame on which a working table is mounted, hinged to the frame by means of spring mechanisms and having locking clips for the tooling, directing the working table, hydraulic motors of vertical and torsional vibrations with plungers having sliding supports , characterized in that, in order to expand the technological capabilities, increase the load capacity, increase the reliability and durability of the design, it is equipped with a vertical a rigid bracket fixed on the bottom of the worktable than the table, and the vertical and torsional oscillation motors are connected to individual pressure pulse systems, while the ends of the hydraulic actuator plungers are made in the form of convex spherical bearing surfaces and are arranged in spherical cavities made in slide bearings, and The desktop features are telescopically mounted. cylindrical rings, the outer ring of which is rigidly connected with. and the inner one with a bed; the slide support of the vertical hydraulic motor is rigidly fixed in the central part of the work table and placed in the inner guide ring, and the slide of the hydraulic motor of the torsional vibration freely mounted on the axis of the vertical bracket. 2. The machine according to claim 1, characterized in that the slide bearing support of the vertical vibration motor is made in the form of a bronze plug. 3. The machine according to claim 1, characterized with — that the slide is 11 3 The rotation of the torsional vibration hydraulic motor plunger is connected to the vibration hydraulic motor housing by means of a T-shaped swing arm and spring mechanisms. 4. The machine pop, 1, is different, so that each clamp The Q tooling consists of a piston hydraulic drive mounted on the underside of the worktable, the rod of which is passed through the worktable and has a flat cam at its end and The buy-in mechanism is in the form of a pin mounted perpendicular to the rod and placed in an inclined groove of the housing mounted on the desktop. 21 .fig. g