SU1708414A1 - Mills - Google Patents

Abstract

The invention relates to equipment for the grinding of various materials and can be used in the mining, chemical, construction and other industries. The purpose of the invention is to expand the technological capabilities of the mill by adjusting the amplitude-6-dy circular oscillations of the grinding chamber. The main components of the mill are mounted on a bed fixed on the foundation either rigidly or by means of pneumatic shock absorbers. Four columns of the bed are equipped with bearing supports, in which four main shafts 9 are placed in pairs. The external ends of the shafts are connected via a synchronizer and couplings to the drive motor 7. At the inner ends of the shafts, kinematic pairs consisting of cylindrical guides 13 and sliders are rigidly fixed. 14. Sliders 14 have the ability to move along the guides 13 within the kinematic pair. On the sliders, the axes 1 of the cheeks 4 are rigidly fixed, which by means of the bearings 5 are connected with the cheeks 4. A grinding chamber is fixed in the center of the cheeks. The ability to adjust the oscillation amplitude allows you to influence the efficiency of the grinding process in the mill. 1 hp F-ly, 5, or .6 I will beat ^ oSYVIO 004 ^

Description

The invention relates to equipment for grinding various materials, 8 particularly to laboratory mills, and can be used in the mining, chemical, construction and other industries.

The purpose of the invention is to expand the technological capabilities of the mill by adjusting the amplitude of oscillations of the grinding chamber.

FIG. 1 shows a laboratory mill, front view; in fig. 2 - the same, top view; in fig. 3 shows section A-A in FIG. one; in fig. 4 shows section A-A in FIG. 1 (version with rubber hinge); in fig. 5 is a section BB in FIG. one

The laboratory mill contains parallel axes 1, a frame 2 with bearing supports 3, cheeks 4 with mounted bearings 5 on the axes 1. grinding chamber 6 and a drive consisting of engine 7 and synchronizing mechanical transmission 8, four main shafts 914 kinematic pairs 10, counterweight 11 and adjusting screws 12. Main shafts 9 of ustaiovlenm on frame 2 are mounted in pairs in bearing supports 3. Moreover, pairs of coaxially mounted main shafts are parallel to each other and each main shaft 9 is rigidly connected to the kinematic pair 10, sos The slitting of the cylindrical guide 13 and the slider 14 (FIG. 3) mounted on them is displaceable relative to the main shaft and connected with the axis 1, on which the bearings 5 are mounted in the cheeks 5. Each slider 14 consists of two Shops 15 and 16, forming a terminal connection with cylindrical guides 13, the tightening of which is provided by clamping bolts 17. One of the shoes 1 & is conjugated by means of a keyed joint and landing with a pull at the end of axis 1 (Fig. 3).

At least one of the sliders 14 may be connected to the axis 1 by means of a rubber-metal hinge 18.

The mill works as follows.

The motor 7, driving the rotation of the drive shaft of the synchronizing transmission 8, provides synchronous and in-phase rotation of the main shafts 9 on the drive side (Fig. 2). Indigenous ramparts 9 involve

rotational motion kinematic pairs 10 with sliders 14 and axes 1 associated with them (Fig. 1). The frontal projections of axes 1 will describe circles whose radii are equal to the distance I between axes 1 and 9 (eccentricity) set the same for each of the four single-motion kinematic pairs 10. Axis 1, turning in

bearings 5 relative to the cheeks 4 and describing their axes synchronously and in phase with the same circumference (Fig. 1), will engage the cheeks 4 together with the grinding chamber 6 in a plane-parallel movement with circular paths of radius I.

The counterweights 11 provide compensation for the inertial loads transmitted to the bearing supports 3 and the frame 2.

With an amplitude of oscillation comparable to the diameter of the grinding chamber, the grinding bodies loaded into it intensively move relative to the walls of the grinding chamber and each other. In the event of collisions of the loading particles, contact stresses occur at the points of contact, leading to effective destruction of the particles of the material being processed.

Claims (2)

1. Laboratory mill, including parallel shafts, frame with bearing supports, cheeks with built-in bearings mounted on the axles, grinding chamber and drive, so as to expand the technological capabilities of the mill by providing adjustment of the oscillation amplitude of grinding chambers, the mill is equipped with four main shafts mounted in bearing supports on the bed in pairs coaxially, with a pair of shafts parallel to each other and each main shaft has a rigidly connected with it kine an attic pair consisting of cylindrical guides and a slider mounted on them with the possibility of movement relative to the main shaft and connected with the axis on which the cheeks are hinged with the grinding chamber. 2. A mill according to claim 1, in that at least one of the sliders is connected to the axis by means of a rubber-metal hinge. S FTEh z. L Xx fi w1. + t. I gii Phage. 2 w FIG.