RU2618691C1 - Disintegrator - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: disintegrator comprises a cylindrical casing 1 with axial loading and tangential unloading devices. The body has a possibility of counter-rotating wheels 4 and 5 are rigidly attached to the impact elements in rows 6 and 7, each of which is disposed between the opposing rows of impact elements disc. Disks 4 and 5 are arranged vertically. The axial loading device is in the form of two hollow horizontal screw shafts 2, fixedly connected to the disks 4 and 5. To the working surface of each disc 4, 5, the corresponding hollow cylinders 8 and 9 are coaxially and rigidly fixed. Inside the hollow cylinders 8 and 9, the radial accelerating blades 10 are rigidly fixed to the working surface of the discs 4 and 5. The distance between the ends of the hollow cylinders 8 and 9 is greater than 2d_Max, where d_Max - maximum size of crushed particles.

EFFECT: higher efficiency of grinding and productivity of the finished class of grinded material.

2 dwg

Description

The invention relates to devices for grinding various materials and can be used in the production of building materials, as well as in other industries.

The design of the disintegrator is known (USSR author's certificate for the invention No. 1572694, В02С 13/22, 1990), containing a cylindrical body, inside of which are two rotors rotating in opposite directions in the form of disks with shock elements in the form of blades and rotated at an angle in adjacent concentric rows .

A disintegrator is also known (USSR author's certificate for the invention No. 908383, В02С 13/22, 1979), the last row of shock elements of which is made in the form of fingers. The outlet pipe is located tangentially to the cage body.

The disadvantages of the known designs is the low efficiency of the grinding process and low fineness of grinding.

The closest technical solution (USSR author's certificate for the invention No. 1694211, В02С 13/22, 1989) to the proposed one is a disintegrator containing a housing in which disks containing percussion elements mounted on the sides of the squares with a common center are coaxially placed.

The following features of the prototype coincide with the essential features of the claimed invention: a cylindrical body with axial loading and tangential unloading devices and with disks mounted in a cylindrical body with the possibility of counter rotation with shock elements fixed along concentric circles, each of which is located between the shock elements of the opposite disk.

However, this device is characterized by low efficiency of the grinding process. This is due to the absence of collisions between the particles of the material before they hit the first inner row of impact elements.

The invention is aimed at improving the efficiency of the grinding process due to additional collisions of material particles in the oncoming streams emerging from vertically arranged hollow cylinders.

This is achieved by the fact that the disintegrator comprises a cylindrical body with axial loading and tangential unloading devices. In the housing, counter-rotating discs are arranged with rows of shock elements rigidly fixed on them, each of which is located between the rows of shock elements of the opposing disk. In the proposed solution, the disks are arranged vertically. The axial loading device is made in the form of two hollow horizontal screw shafts rigidly connected to the disks. Corresponding hollow cylinders are coaxially and rigidly attached to the working surface of each disk, inside of which radial accelerating blades are rigidly fixed on the working surface of the disks. The distance between the ends of the hollow cylinders is more than 2d _max , where d _max is the maximum size of the crushed particles.

The invention is illustrated by graphic materials, where in FIG. 1 is a longitudinal section of a grinding chamber (section BB in FIG. 2), FIG. 2 is a cross section of the grinding chamber (section AA in FIG. 1).

The disintegrator comprises a cylindrical housing 1 with an axial loading device made in the form of two oppositely arranged hollow horizontal screw shafts 2 located coaxially with each other, and a tangential unloading device 3. In the cylindrical housing 1, the disks 4 and 5 are rigidly vertically rotated in the opposite direction fixed on them, for example, by welding, by the rows of shock elements 6 and 7, respectively. Each of the shock elements 7 of the disk 5 is located between the rows of the shock elements 6 of the disk 4. All of the shock elements 6 and 7 are arranged in concentric circles.

Each of the two hollow horizontal screw shafts 2 is rigidly connected, for example, by welding, with a vertical disk 4 and 5, respectively.

To the working surface of each disk 4, 5 the corresponding hollow cylinders 8 and 9 are coaxially and rigidly attached, for example, by welding, inside of which on the working surface of the disks 4, 5 radial accelerating blades 10 are rigidly fixed, for example, by welding.

The distance between the ends of the hollow cylinders 8 and 9 is greater than 2d _max , where d _max is the maximum size of the crushed particles. To prevent clogging with the material of the space between the hollow cylinders 8 and 9 and the shock elements 6 of the inner row, fenders 11 are fixed on the outer surface of the hollow cylinders 8 and 9.

The disintegrator works as follows. The crushed material, for example, limestone, with a moisture content of up to 4%, is fed into two oppositely positioned hollow horizontal screw shafts 2, by means of which it is guided into oppositely located hollow cylinders 8 and 9. Since the hollow cylinders 8 and 9 are attached to the disks 4, 5 and are located on the same horizontal axis, then the particles of the crushed material, captured by the accelerating blades 10, fly out from the opposite hollow cylinders 8 and 9 towards each other and collide with each other, as well as with the accelerating blades 10 of the opposite disk 4 or 5, then the pre-crushed material is sent through the centrifugal force into the gap between the ends of the hollow cylinders 8 and 9 to the first inner row of shock elements 6. The chippers 11 create a ventilation effect and prevent the material from filling the space between the hollow cylinders 8 and 9 and the shock elements 6. Having passed the first inner row of shock elements 6, the material falls on the next row 7, where it is subjected to intense shock and abrasion loads. The finished product flies from the casing 1 of the disintegrator through the tangential unloading device 3.

To avoid jamming of the material between the hollow cylinders 8 and 9, the distance between the ends of the hollow cylinders 8 and 9 is greater than 2d _max , where d _max is the maximum size of the crushed particles.

The use of a disintegrator with a loading device in the form of two oppositely positioned hollow horizontal screw shafts, with hollow cylinders rigidly fixed to the working surface of each vertical disk and accelerating blades radially mounted on the working surface of each vertical disk, can significantly increase the efficiency of the grinding process and increase productivity by the finished class of crushed material due to additional collisions of the particles of material between themselves, as well as with accelerating blades of the opposite disk.

Claims (1)

A disintegrator comprising a cylindrical body with axial loading and tangential unloading devices, disks placed in the body with the possibility of counter rotation, rows of shock elements rigidly fixed to them, each of which is located between the rows of shock elements of the opposing disk, characterized in that the disks are arranged vertically, and the axial loading device is made in the form of two hollow horizontal screw shafts rigidly connected to the disks, to the working surface of each disk coaxially and the corresponding hollow cylinders are tightly attached, inside of which radial accelerating blades are rigidly fixed on the working surface of the disk, while the distance between the ends of the hollow cylinders is more than 2d _max , where d _max is the maximum size of the crushed particles.

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