RU192134U1 - JACK CRUSHING MACHINE WITH INTERNAL CRUSHING CAMERA - Google Patents

Abstract

The utility model relates to machines designed for crushing materials (rocks), namely to jaw crushing machines. The technical problem solved by the proposed utility model is to increase the destructive effect on crushed material, which allows to increase crushing performance. A jaw crushing machine is proposed, comprising a three-pair drive link connected to a drive crank and a movable cheek, a three-pair balance link, articulated to a strut and a second movable cheek . The movable cheeks are pivotally connected by means of an additional three-pair link, and the three-pair drive link and the three-pair balancer link are pivotally connected to each other, and all the links together form a closed movable five-link contour, while the additional three-pair link is pivotally connected to the strut through a two-pair leash. the increase in the destructive effect that arises due to the introduction of an additional three-pair link, which allows you to remove the restrictions of change I am the volume of the closed destructive space, since the link enters the inside of the closed five-link circuit, which allows several times to increase the crushing performance inside the closed circuit. 2 ill.

Description

The utility model relates to machines designed for crushing materials (rocks), namely to jaw crushing machines.

Known jaw crusher, where two mutually movable working cheeks, a crushing cheek and a stop cheek by means of a three-pair balancer link and a three-pair drive link form a closed destructive four-link circuit (RU No. 2538108 IPC В02С 1/02, publ. 10.01.2015).

The disadvantage of such a crushing machine is the limited change in the volume of the closed destructive space, since none of the links of the four-link circuit can enter the inside of the circuit.

This technical solution is the closest and accepted by the authors for the prototype.

The technical problem solved by the proposed utility model is to increase the destructive effect on crushed material, which allows to increase the crushing performance.

The existing technical problem is solved by the fact that in the known crushing machine containing a three-pair drive link connected to the drive crank and a movable cheek, a three-pair balancer link, pivotally connected to a strut and a second movable cheek, according to a utility model, the movable cheeks are pivotally connected by an additional three-pair link and the three-pair drive link and the three-pair balancer link are pivotally interconnected, and all the links together form a closed movable five-link contour p, wherein the extra-Pair link pivotally connected to the rack via two pair leash.

The technical result obtained by using the utility model is to increase the destructive effect, which occurs due to the introduction of an additional three-pair link, which allows you to remove the restrictions on the volume change of the closed destructive space, since the link enters the inside of the closed five-link circuit, which allows to increase productivity several times crushing inside a closed loop.

The utility model is illustrated in the drawing, where in FIG. 1 shows the end position with the smallest variable volume of the crushing chamber; FIG. 2 - the largest volume of the crushing chamber.

The crushing machine consists of a drive crank 1, which is connected to a drive motor (not shown in the figure), a drive three-pair link 2, a movable cheek 3, an additional three-pair link 4, a movable cheek 5, a three-pair balancer link 6, and two pair leashes 7.

The mechanism works as follows. The processed material is placed in a crushing chamber, which is a five-link closed loop formed by three three-pair and two two pair links. The drive crank 1, making a complete revolution, sets in motion the drive three-pair link 2, which brings together the movable cheeks 3 and 5, forcing them to grind the processed material. The efficiency of the proposed mechanism is proved by the well-known formula of Chebyshev P.L. (Krainev A.F. Dictionary of Mechanisms. - M.: Mechanical Engineering, 1987, p. 518)

W = 3n-2p5,

where W is the mobility of the mechanism, n is the number of movable links, p5 is the number of one-motion kinematic pairs.

In the proposed mechanism, n = 7, p5 = 10, therefore, W = 3⋅7-2⋅10 = 1, i.e. for a given crank movement, all other links will move quite definitely.

The use in the proposed utility model of three three-pair movable links allows you to direct all the pressure experienced by the moving cheeks in favor of a destructive effect.

Claims (1)

A jaw crusher with an internal crushing chamber, comprising a three-pair drive link connected to a drive crank and a movable cheek, a three-pair balancer link, pivotally connected to a strut and a second movable cheek, characterized in that the movable cheeks are pivotally connected by an additional three-pair link, and a three-pair drive the link and the three-pair balancing link are pivotally interconnected, and all the links together form a closed movable five-link contour, with an additional three The extrapar link is pivotally connected to the strut through a two-pair leash.

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