RU171856U1 - CONE CRUSHER - Google Patents

Abstract

The utility model relates to construction and mining equipment, and in particular to means for crushing building materials and minerals. The objective of the claimed utility model is to increase the efficiency of crushing and reduce the metal consumption of the structure due to the implementation of the counter force impact of crushing elements on the material. A cone crusher comprising a casing, a crushing cone, rigidly connected to the casing, a hollow cone freely suspended on elastic elements between the casing and the crushing cone and forming the upper crushing chamber with the casing, and with the crushing cone, the lower crushing chamber, while the hollow cone is equipped with a drive reciprocating movement, while the housing is equipped with a reciprocating drive and mounted using spring supports on the base, which, in turn, is mounted on the foundation using shock absorbers. 1 ill.

Description

The utility model relates to construction and mining equipment, and in particular to means for crushing building materials and minerals.

A cone crusher is known, including a casing, crushing cone, reciprocating drive and a hollow cone freely hanging between the casing and the crushing cone, forming the upper crushing chamber with the casing, and the lower crushing chamber with the crushing cone (see ed. Certificate of the USSR No. 612693, published on 06/30/1978, IPC V02S 2/10). A disadvantage of the known cone crusher is that the destruction of the material in this crusher occurs only when the crushing and hollow cones move upward, and as a result, the energy capabilities of the reciprocating drive are not sufficiently used.

The closest analogue to the claimed utility model is a cone crusher comprising a casing crushing cone, a reciprocating drive and a hollow cone freely hanging between the casing and the crushing cone, forming the upper crushing chamber with the casing, and the lower crushing chamber with the crushing cone, this crushing cone is rigidly connected to the housing, and the hollow cone is connected to the reciprocating drive (see RF patent No. 164598, publ. 09/10/2016, IPC V02C 2/02).

Equipping the hollow cone with a reciprocating drive allows the material to be crushed when it moves up and down, i.e. with a full cycle of motion of the hollow cone. In addition, the material is loaded into two crushing chambers at the same time, which leads to increased efficiency and increased crushing performance.

With equal masses of passive and movable elements of the cone crusher, a large amount of energy is consumed by the reciprocating drive to swing the passive elements. In this case, the passive elements of the cone crusher are the body and the crushing cone, and the movable one is the hollow cone. The resulting vibrations of the passive elements are damped by the shock absorbers on which the crusher body is mounted in order to maintain the foundation on which the cone crusher is mounted. Thus, a significant part of the generated energy is not spent on crushing the material, but is damped by shock absorbers, which reduces the efficiency of the cone crusher according to the prototype. To increase the efficiency of the crusher, it is necessary to significantly increase the mass of the stationary elements of the prototype in comparison with the mass of the movable hollow cone, which is achieved by increasing the metal consumption of the structure.

The objective of the claimed utility model is to increase the efficiency of crushing and reduce the metal consumption of the structure due to the implementation of the counter force impact of crushing elements on the material.

The problem is solved due to the fact that in the inventive cone crusher containing a housing, a crushing cone, rigidly connected to the housing, a hollow cone freely suspended on elastic elements between the housing and the crushing cone and forming the upper crushing chamber with the housing, and with the crushing cone - lower crushing chamber, while the hollow cone is equipped with a reciprocating drive, in contrast to the prototype, the housing is equipped with a reciprocating drive and is mounted using spring supports on the base, cat Roe in turn, mounted on the foundation by means of shock absorbers.

Equipping the casing with a reciprocating drive, operating in antiphase with a reciprocating drive on a hollow cone, allows counter force action of the casing and crushing cone on crushed material, which allows to increase the crushing efficiency by increasing the amount of energy spent on material destruction when reducing the amount of energy extinguished by shock absorbers.

The utility model is illustrated in the drawing, which schematically shows a cone crusher.

The cone crusher comprises a housing 1, a crushing cone 2, a reciprocating drive 3 connected to the upper part of the hollow cone 4 freely suspended between the housing 1 and the crushing cone 2, a reciprocating drive 5 mounted on the housing 1. Hollow cone 4 suspended by means of elastic elements 6. The hollow cone 4 forms the upper crushing chamber 7 with the housing 1, and the lower crushing chamber 8 with the crushing cone 2. The housing 1 is rigidly connected to the crushing cone 2, and the crushing cone 2 has discharge windows 9. Drives 3 and 5 return MTF work in antiphase. The housing 1 together with the crushing cone 2 is fixed on the base 10 using spring supports 11. The base 10 is mounted on the foundation by means of shock absorbers 12.

Cone crusher works as follows.

Drives 3 and 5 are started, as a result of which the hollow cone 4 and the housing 1 together with the crushing cone 2 begin to make relative vertical reciprocating movements. Drives 3 and 5 are synchronized and operate in antiphase. Then, the starting material for crushing is simultaneously loaded into the upper 7 and lower 8 crushing chambers. When the hollow cone 4 moves up, the housing 1 and the crushing cone 2 are lowered down, while the width of the upper crushing chamber 7 is reduced and the material in it is destroyed under the action of a compressive load. Simultaneously with the narrowing of the upper crushing chamber 7, the width of the lower crushing chamber 8 increases, and the material from the chamber 8 under the action of gravity enters the discharge windows 9. When the hollow cone 4 moves down, the housing 1 and the crushing cone 2 move up, while the width of the upper crushing 2 chamber 7 increases and the material under the action of gravity enters the discharge windows 9. Simultaneously with the increase in the width of the upper crushing chamber 7, the width of the lower crushing chamber 8 decreases, and the material in the chamber 8 is destroyed under the action of compressing n Booting. Then, under the action of gravity, the crushed material from the chamber 8 enters the discharge windows 9, after which the crushed material is removed from the crusher.

Thus, the proposed design of the cone crusher allows crushing of the material when the force of the hollow cone and the body with the crushing cone are counter-acting, which leads to a decrease in the metal consumption of the crusher and an increase in crushing efficiency.

Claims (1)

A cone crusher comprising a casing, a crushing cone, rigidly connected to the casing, a hollow cone freely suspended on elastic elements between the casing and the crushing cone and forming the upper crushing chamber with the casing, and with the crushing cone, the lower crushing chamber, while the hollow cone is equipped with a drive reciprocating movement, characterized in that the housing is equipped with a reciprocating drive and mounted using spring bearings on the base, which, in turn, is mounted on the foundation with amor izatorov.

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