RU105199U1 - VIBRATING MILL - Google Patents

Abstract

 Vibratory rotary mill, containing a movable frame placed on a fixed frame, on which a grinding chamber with grinding bodies is mounted in bearings that can rotate around its own axis, and a rotation drive for the grinding chamber, characterized in that the grinding chamber is made in the form of an inclined cylinder, the end surfaces of which perpendicular to the axis of its rotation, and its lateral cylindrical surface is set at an angle to the horizontal surface of the moving frame, and the angle of inclination of the side surface of qi Lindra to the horizontal surface of the movable frame is less than 45 °.

Description

The utility model relates to devices for grinding various materials, in particular to vibration devices, and can be used in mining, construction, chemical and other industries.

Known vibration mill (SU 1165464 publ. 07.07.85, IPC V02C 19/16), containing a grinding chamber mounted on cylindrical supports, equipped with a vibrator, at the ends of which pulleys of a V-belt drive with drive pulleys are mounted, as well as a housing supported on pneumoelastic elements. The disadvantage of this design is its complexity and low productivity.

Also known is the design of a vibration mill (RU 2040970, published 09.08.95, IPC В02С 9/16), which is a grinding chamber mounted on an unbalanced shaft freely and equipped with a counterweight, which in turn is supported on the frame through vibration isolators. The disadvantages of this design are the low grinding efficiency due to incomplete filling of the grinding chamber, as well as the low quality of grinding due to the inconsistent rotation of the grinding chamber.

The closest analogue (prototype) in technical essence to the proposed technical solution is a vibration mill (RU 2147931, publ. 04/27/2000, IPC V02C 17/06) containing a cylindrical drum with grinding media, the housing of which is rigidly connected with springs and an unbalanced vibration exciter located outside the drum, which is mounted in bearing bearings on a movable vibrating plate with the possibility of rotation around its own axis from a separate drive. The disadvantage of this device is its low productivity due to the increased oscillating mass, in addition, the presence of partitions creates additional stagnant zones in the grinding chamber.

The technical problem solved by the utility model is increasing mill productivity.

The stated technical problem is solved in that in a vibration mill containing a grinding chamber with grinding bodies, equipped with a device for loading and unloading material, mounted in bearing bearings on a movable frame with the possibility of rotation around its axis, located, in turn, on a fixed frame, the vibration drive and the camera rotation drive, the grinding chamber is made in the form of an inclined cylinder and is installed at an angle to the horizontal surface of the moving frame.

The grinding chamber is freely installed in the bearing supports, which allows it to rotate around its axis with the help of the drive, in turn, the support nodes are part of the movable frame, with a vibration drive fixed to it, resting on the fixed frame through vibration isolators (springs). The angle of inclination of the side surface of the cylinder to the horizontal surface of the movable chamber should be greater than the angle of repose of the mixture of material being crushed, but less than 45 °, which was experimentally determined, for example, when the angle of repose of the mixture is 18-20 °, the angle of inclination of the side surface of the cylinder will be 30 ° (α = 30 °).

If the inclination angle is 45 ° or more, additional power consumption occurs due to an increase in dynamic loads on the grinding chamber body.

Due to the shape and the proposed installation of the grinding chamber, which allows the grinding bodies to move reciprocating in the longitudinal direction during operation, the material is effectively crushed in the mode of complex circulation and vibrational movement of the grinding bodies. When using the proposed design, the mill productivity is significantly increased due to more intensive grinding of the material in the grinding chamber. An increase in mill productivity and grinding quality (due to the absence of partitions provoking the accumulation of material in the attachment points of the partitions) is also achieved by increasing the total free volume of the grinding chamber.

The essence of the proposed utility model is illustrated by graphic materials, which depict a General view of the device.

The device includes a fixed frame 1, on which the drive 2 of the grinding chamber 3 is mounted, made in the form of an inclined cylinder with end surfaces 4 and 5 and a side cylindrical surface 6. Drive 2, through an elastic coupling 7, rotates the grinding chamber 3 around a horizontal axis . The grinding chamber 3, made in the form of an inclined cylinder, is installed in bearing bearings 8 and 9, which are part of the movable frame 10 connected to the fixed frame 1 through vibration isolators (springs) 11. The end surfaces 4 and 5 of the inclined cylinder of the chamber are installed perpendicular to the axis of rotation of the chamber, and its lateral cylindrical surface 6 is placed at an angle α (α = 30 °) to the horizontal surface of the movable frame 10. A vibratory actuator 12 is mounted on the lower surface of the movable frame 10, which makes the rotating chamber oscillate tionary movement. In the lower part of the cylindrical surface of the chamber there is a loading and unloading device - loading hatch 13, with a removable grill 14 for unloading the crushed material.

The device operates as follows.

Through the loading device (loading hatch) 13, grinding bodies are loaded into the grinding chamber 3. The source material, also through the loading hatch 13, is loaded into the grinding chamber 3 and closed with a grill 14 and a lid (not shown in Fig.). The vibrator 12 creates oscillations of the grinding chamber along an elliptical path. At the same time, drive 2 rotates the grinding chamber. Grinding bodies have an impact and abrasion effect on the material being ground; continuous mixing of the material occurs due to the curved path of the grinding bodies along the generatrix of the grinding chamber. The processed material, without encountering obstacles (in the form of partitions), is intensively mixed and crushed under the shock-abrasive effect of grinding media. After a predetermined time (depending on the source material), the lid opens (not shown in Fig.), The finished product is unloaded from the grinding chamber through the loading and unloading hatch 13, equipped with a grill 14. The grill can be made with perforation of various sizes, depending on the required fineness of grinding. Vibratory rotary mill operates in a cyclic mode, the duration of the cycles is determined by the specified particle size of the crushed material.

Due to the implementation of the grinding chamber in the form of an inclined cylinder installed at an angle to the horizontal surface of the movable frame, due to the camera (grinding bodies in the chamber) moving along a complex path during operation, as well as the absence of obstacles (places of accumulation of material “stagnant zones”) inside cameras, i.e. increasing the free (working) volume of the chamber increases the productivity of the mill. This simplifies the design of the vibratory rotary mill.

Thus, the task is solved.

Claims (1)

Vibratory rotary mill, containing a movable frame placed on a fixed frame, on which a grinding chamber with grinding bodies is mounted in bearings that can rotate around its own axis, and a rotation drive for the grinding chamber, characterized in that the grinding chamber is made in the form of an inclined cylinder, the end surfaces of which perpendicular to the axis of its rotation, and its lateral cylindrical surface is set at an angle to the horizontal surface of the moving frame, and the angle of inclination of the side surface of qi Lindra to the horizontal surface of the movable frame is less than 45 °.