RU196194U1 - SINGLE DRILL CRUSHER ROTOR - Google Patents

Abstract

The invention relates to a technique used for crushing materials in metallurgy, namely, sinter cake in sinter production. To increase the efficiency of crushing and reduce energy costs in the rotor of a single-roll gear crusher containing a shaft and gear sprockets fixed to it, sprockets along the center to the edges the rotors are turned in the opposite direction from the direction of rotation of the crusher relative to the previous one so that the same angle between the axes of the teeth of adjacent sprockets on the entire rotor is provided, while one the angular angle is provided between the axes of the teeth of adjacent sprockets on the entire rotor, determined for an odd number of stars: where N is the number of stars on the rotor; for an even number of stars: the angle between the axis of the central sprocket (or central pair of sprockets) and a certain asterisk on the shaft is determined by the formula: α = iα, where i is the serial number of the asterisk in the direction from the center to the edges of the rotor.

Description

The utility model relates to the technique used for crushing materials in metallurgy, namely, sinter cake for its further use as raw materials for blast furnaces.

Known rotor single roll gear crusher containing a shaft and gear sprockets mounted on it [Machines and assemblies of metallurgical plants. In 3 volumes. T. 1. Machines for blast furnaces. Textbook for high schools / Tselikov A.I. [et al.] second ed., rev. and add. - M .: Metallurgy, 1987. - 440 p.].

A disadvantage of the known rotor is the relatively low crushing efficiency and stuck energy costs due to the contact interaction of all the teeth of the rotor with crushed material, in which the material is destroyed due to crushing, which also leads to an increased content of the fine fraction in the crushed product.

The technical task of the utility model is to improve the rotor of a single-roll gear crusher, in which, thanks to a new arrangement of sprocket teeth on the shaft, including one based on mathematical dependence, an increase in crushing efficiency and a reduction in energy costs are achieved.

This object is achieved by the fact that on the rotor of a single-roll gear crusher containing a shaft and gear sprockets fixed to it, according to the invention, the sprockets are turned in the opposite direction from the direction of rotation of the crusher relative to the previous one so that the same angle between the axes is provided the teeth of adjacent sprockets on the entire rotor, while the same angle is provided between the axes of the teeth of neighboring sprockets on the entire rotor, determined for an odd number of stars:

where N is the number of stars on the rotor; for an even number of stars:

the angle between the axis of the central sprocket (or the central pair of sprockets) and a specific sprocket on the shaft is determined by the formula:

α _i = iα ₀ ,

where i is the serial number of the asterisk along the path from the center to the edges of the rotor.

In FIG. 1 shows the rotor of a single-roll gear crusher with a chevron sprocket teeth arrangement on the shaft, FIG. 2 - sprocket of a rotor with different fragility of rotation about an axis.

The rotor of the hammer mill contains a shaft 1 and sprockets 2 with teeth 3 that are mounted on the shaft 1. In addition, the teeth of the sprockets 2 are located relative to the central sprocket 4 in such a way that the same angle between the axes of the teeth of the neighboring sprockets on the entire rotor is ensured and, as a result, during rotation of the rotor, two teeth symmetrically located relative to the central sprocket (or central pair of sprockets) of teeth or teeth of the central and extreme sprockets of the next row come into contact with the crushed material.

The teeth of the sprockets 2 are arranged in such a way that when the rotor rotates, two teeth symmetrically located relative to the central sprocket (or the central pair of sprockets) of teeth come into contact with the crushed material, or the teeth of the central and extreme sprockets of the next row. In this case, the sprockets located downstream from the center to the edges of the rotor are rotated in the opposite direction from the direction of rotation of the crusher relative to the previous one so that the same angle between the axes of the teeth of adjacent sprockets on the entire rotor is determined by the formulas:

- for rotors of crushers with an odd number of stars:

where N is the number of stars on the rotor;

- for crusher rotors with an even number of stars:

In both cases, the angle between the axis of the central sprocket (or the central pair of sprockets) and a specific sprocket on the shaft is determined by the formula:

α _i = iα ₀ ,

where i is the serial number of the asterisk along the path from the center to the edges of the rotor.

The rotor of a single-roll gear crusher operates as follows.

The material to be crushed enters the working space of the teeth of the rotor of the crusher, where it enters into the simultaneous contact interaction with the teeth of the sprockets in an amount of not more than three, due to which the contact area of the teeth with the material decreases. With this method of contact loading, the material is destroyed mainly due to a kink relative to the outer faces of the grates, and not crushing on their surface.

The same angle between the axes of the teeth of adjacent sprockets on the entire rotor, determined by the formulas:

- for rotors of crushers with an odd number of stars:

where N is the number of stars on the rotor;

- for crusher rotors with an even number of stars:

contributes to the impact on the sinter cake not all of the teeth of the stars at once simultaneously, but only a few of them. In view of this, the predominant role in the destruction of crushed material is ensured by bending (kink), which leads to cracking of the sinter cake in the least sintered (defective) places, since they have the least mechanical strength. Consequently, individual grains of material are freed in the non-sintered sections of the sinter cake, which reduces the formation of a dusty fraction in the subsequent stages of reloading the sinter material to blast furnaces, since the destruction of most defective structures was already carried out in the working chamber of a single-roll gear crusher.

For uniform operation of the sprocket teeth along the entire length of the rotor, the angle between the axis of the central sprocket (or the central pair of sprockets) and a specific sprocket on the shaft is determined by the formula:

α _i = iα ₀ ,

where i is the serial number of the asterisk along the path from the center to the edges of the rotor. This allows the individual teeth of the sprockets located at different sites and ends of the shaft to uniformly act on the sinter cake across its entire width.

As a result of this, the efficiency of the crushing process increases, the fines content in the crushed product decreases due to a decrease in the fraction of crushed raw materials during crushing, and energy costs are reduced, since the loads in the process of fracture of the material during fracture are much smaller than during compression.

The proposed rotor of a single-roll gear crusher can increase the efficiency of the crushing process and reduce energy costs for the destruction of materials.

Claims (9)

1. The rotor of a single-roll gear crusher, containing a shaft and gear sprockets fixed to it, characterized in that the sprockets in the direction from the center to the edges of the rotor are turned in the opposite direction from the direction of rotation of the crusher relative to the previous one so that the same angle between the axes of the teeth of adjacent sprockets on all rotor. 2. The rotor of a single-roll gear crusher according to claim 1, comprising a shaft and gear sprockets fixed to it, characterized in that the same angle is provided between the axes of the teeth of adjacent sprockets on the entire rotor, determined for an odd number of sprockets:

where N is the number of stars on the rotor; for an even number of stars:

the angle between the axis of the central sprocket or the central pair of sprockets and a specific sprocket on the shaft is determined by the formula: α _i = iα ₀ , where i is the serial number of the asterisk along the path from the center to the edges of the rotor.

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