RU1809037C - Mining machine - Google Patents

Abstract

The invention relates to mining equipment for destroying a rock mass using a shock-cutting method and serves to reduce the energy intensity of the process and to reduce dust generation due to the implementation of a wide range of predetermined modes of destruction by a shock-cutting method with tool paths in the form of hypotrochoid segments. The design of the organ consists of two halves of the carrier 2A and 2B of the wave generator with rollers 1 mounted on them, an asterisk 3 of a rigid element and a flexible element ribbon

Description

ment 4, the cutting chain, with the tools fixed on it 5. The contour ring from the tape of the flexible element 4 tightly covers the protruding tooth of the sprocket 3 and all the rollers 1 of the wave generator. The halves of carrier 2A and 2B of the wave generator have, for example, a separate drive consisting of an engine 6 and a transmission system of gears 16, 13, 17, 19, 20 and 21, axles 14 and shafts 9, 10 and 18. The sprocket 3 also has , eg.

our separate drive, consisting of an engine 7 and a transmission system of gears 12, 13 and 15, axles 14 and shaft 8. We obtain the necessary parameters of the operating modes of the organ, the thickness and direction of removal of the elementary chips, by targeted selection of the ratio of the angular rotation frequency vectors of carrier 2A -2B and sprocket 3, taking into account the design and geometric dimensions of the elements of the organ of destruction. 2 ill.

FIELD OF THE INVENTION The invention relates to the field of engineering, which deals with the mechanical cutting and destruction of mainly fragile monoliths, materials and arrays, and more particularly, to working bodies for carrying out rock destruction by an impact-cutting method under the conditions of application of such devices in the mining industry.

The aim of the development of a new type of working body for a shearer is to reduce the energy intensity of the process of destruction of the rock mass and to reduce the level of dust formation due to the use of a shock-cutting destruction method in such a body.

The proposed working body according to the basic structural elements repeats the prototype, which is a flat bar working body of a cutting machine.

The principal distinguishing feature of the new organ is the presence of an additional drive located coaxially with the drive sprocket to drive the bar cutting chain. A bar housing is attached to the output shaft of this additional drive. The bar body, in our case, is freed from other connections with the machine body so that the entire bar can rotate freely around the axis of the drive sprocket of the bar in the direction of rotation opposite to that of the sprocket.

The work on the destruction of the array in the proposed body differs from the work of the bar. In such a body, the destruction of the array should be performed only by active tools, i.e. those that are on the links x of the cutting chain at the time of the destruction of the circumferential bypass element, the roller, supported. Passive instruments i.e. those tools whose links are in a straight section of the movement of the cutting chain and on the drive sprocket should not be involved in the destruction of the array. In other words, the destruction work in the proposed organ is similar to the work of the bar organ with the tools located in the area of the bypass element, the roller, in the process of cutting.

A careful examination of the kinematic scheme of the mechanism of the proposed organ allows us to conclude that this is typical

differential wave mechanism with

external arrangement of the flexible element.

In the mechanism of the proposed body

the shortened bar body acts as

drove a wave generator of wave transmission.

The enlarged drive sprocket for driving the bar chain acts as a rigid element, in this case a rotatable one. A flexible element of the mechanism is the bar chain. Reduced bypass

a bar element (passive sprocket, roller or other similar device) acts as a roller of a wave generator.

The body works as follows. With simultaneous counter rotation of the sprocket of the rigid element and the carrier of the wave generator, the generator roller moves the wave of the flexible element, the cutting chain, around the axis of rotation of the device. The wave motion of the flexible element causes the cutting edges of the instruments, supported on the surface of the roller of the wave generator, to make a complex movement along the trajectories of some kind of hyprochoid. These curves are located in the plane of rotation of the organ elements. With such movement, the array is destroyed from the inside of the cylinder sequentially by individual recesses located along an arc of a circle, implementing an economical impact-cutting method of destruction.

The proposed organ in its construction and functions is differential-wave and will be referred to as differential-wave in the description below.

organ of destruction.

An organ created on the basis of a bar of a cutting machine will be unbalanced, therefore it is proposed to make an organ in principle similar to a two-beam or even a three-beam bar, the leading sprocket of which is located on the axis of the center of rotational mass of the device, and the ribbon of the flexible element covers simultaneously protruding tooth of the sprocket of the rigid element and all the rollers wave generator. Such an arrangement is similar to a wave transmission having a two- or three-wave wave generator.

In order to obtain a spatial organ, a foot can be recruited from the planar differential wave organs of destruction.

Structurally, the differential-wave organ of destruction can be performed compactly, i.e. with rollers whose axes are located within the contour of the rigid element.

The proposed organ of destruction allows you to set the desired mode of destruction by resizing the elements of the device and / or by choosing the ratio of the vectors of rotation frequencies of the carrier wave generator and the rigid element.

If the rigid element of the differential-wave destruction organ is braked or fixed to the machine body, then in this case we will obtain the simplest destruction organ - the planetary-wave one, which kinematically repeats the usual wave transmission. When one tool is attached to each link in the chain of a flexible element, the number of recesses from individual tools on the machining circumference during the operation of such an organ is determined by the number of teeth on the rigid element, i.e. on an asterisk, and, in the end result, is equal to this quantity, because the next link taken from the drive sprocket (the wave generator roller), a chain link with a passive tool, allows you to touch and treat the surface behind another, another active tool located in the destruction zone. From this we can conclude that the thickness of the chips removed by the next next tool depends on the number of teeth on the rigid element. Therefore, the choice of destruction modes is limited and possible only by changing the geometric dimensions of the elements of the device, from which only the tool stand extension is easily changed.

In the destruction organ with a rotatable rigid element, in which on each link of the chain of the flexible element one tool is fixed, the number of recesses per

the circumference of the machining and hence the thickness of the chip will depend on the number of teeth on the rigid element and on the value of the ratio of the frequency vectors of rotation 5 of the carrier of the wave generator and the rigid element - asterisks.

T.O. the proposed differential-wave organ of destruction allows for forced regulation

0 destruction modes, both by changing the geometric dimensions of the elements, which limits the versatility of regulation, and by deliberately choosing the ratio and direction of the angular frequencies of the carrier

5 of a wave generator and, free from communication with the device body, a rigid element, which is a wider, more affordable way to control the modes of destruction of the array.

The location of the cutting (fender) tools at the step of the chain link of the flexible element should be chosen closer to the front hinge along the carrier, as in this case, the process of embedding the tool in an array

5 occurs with less effort, and upon exiting, more intense damage is observed. A similar effect is known from the theory of operation of a caterpillar of a caterpillar tractor, but in a caterpillar mover this phenomenon tends to prevent, weaken its influence.

Installation of several tools on each link of the chain of the flexible element, including on the carrier brought forward along the course

5 console link, will allow for more complete destruction for fewer passes of the rollers of the wave generator and with less energy.

On Fig, 1 shows a diagram of a device

0 differential wave organ destruction with forced control of destruction modes; in FIG. 2 is a diagram of a device of a compact differential wave organ of destruction with forced

5 by adjusting the modes of destruction of a drum type having a three-wave generator of waves.

The roller .1 of the wave generator is fixed on the carrier 2. Asterisk 3 of the rigid element and

0 the roller 1 of the wave generator covers the contour of the flexible element 4. On the outside of the flexible element 4 fixed cutting (fender) tools 5. The rotation of the carrier 2 of the wave generator is carried out from

5 of the drive 6. The rotation of the sprocket 3 .- /. Of the rigid element is carried out from the drive 7.

During operation of the body during rotation of carrier 2 of the wave generator, its roller 1 moves the wave of the flexible element 4 around the axis of rotation of the elements of the device, forcing

the edges of the tools 5 move along the trajectories of a hypotrochoid of some kind. With this movement, the massif is destroyed sequentially by separate notches located along an arc of a circle. The simultaneous rotation of the sprocket 3 of the rigid element, by purposefully selecting the frequency and direction of rotation, makes it possible to adjust the trajectories of the cutting edges of the tools, as well as the number of recesses on the machining circumference, providing the desired destruction mode.

The destruction organ consists of a rigid element - sprocket 3, mounted on the middle hollow shaft 8. At the ends of the sprocket

3 there are halves of the carrier 2A and 2B of the three-wave wave generator, of which half 2A is mounted on the internal continuous shaft 9, and half 2B is mounted on the external hollow shaft 10. On each beam of each half of the carrier of the wave generator are mounted axes 11 on which the rollers 1 of the wave generator are dressed , The beams of the halves of the carrier of the wave generator 2A and 2B should be located so that the corresponding axes 11 of the rollers 1 of the wave generator are on the same line. The outer surfaces of the rollers 1 and the protruding tooth of the sprocket 3 of the rigid element tightly surrounds the contour of the tape of the flexible.-Element 4. The tape of the flexible element

4 can be made in the form of a multi-row chain or caterpillar. Outside of the chain links (caterpillars), cutting (fender) tools 5 are fixed.

The sprocket 3 is driven from the engine 7 by means of a pinion gear 12 mounted on the output shaft of the engine 7, a series of spurious gears 13, mounted on an axis 14 and then through the pinion gear 15, which is fixed on the other end of the middle hollow shaft 8.

The halves of the carrier 2A and 2B of the wave generator are driven by the drive gear 16, which is fixed to the output shaft of the engine 6, a number of spurious gears 13, mounted on the axis 14 and then through the driven gear 17, which is fixed on the other end of the outer hollow shaft 10. Synchronous rotation of half of the carrier 2A of the wave generator is carried out from the driven gear 17 through the pinion shaft 18 by means of gears 19, 20 and 21, of which gears 19 and 20 are mounted on the shaft-closure 18, and gear 21 is on the other end of the inner all over th shaft 9.

The device operates as follows.

With simultaneous oncoming rotation of the sprocket 3 of the rigid element and the carrier

2A-2B of the wave organ of the destruction organ, its rollers 1 move the waves of the flexible member 4 around the axis of rotation of the device. The wave motion of the flexible element 4 causes the cutting edges of the tools 5, the links of which are supported on the surface of the rollers 1 of the wave generator, to make complex movement along the trajectories of the hyprochoid, the shape of which depends on the ratio of the rotation frequency vectors of the sprocket 3 of the rigid element and the carrier 2A-2B of the wave generator . In other words, the corresponding engine speeds 6 and 7, as well as gear ratios 12-15

5 of the drive of the sprocket 3 of the rigid element and, accordingly, of the pair of gears 16-17 of the drive carrier of the wave generator 2A-2B, taking into account the ratios of the geometric dimensions of the elements of the destruction organ, provide the specified parameters of the destruction modes.

In principle, any drive can be selected as adjustable, or both at the same time. Single engine can also be used.

5 drive with corresponding kinematic links through interchangeable gears, because the size and shape of the elementary chips is determined by the ratio of the angular rotational frequency vectors of the elements.

0 The proposed organ of destruction, in comparison with the screw and drum organs of destruction, as well as the cutting bar, where the shearing method is used, allows us to expect an increase in cutting speed and increase the reliability of the tool due to intermittent operation, as well as a significant reduction in energy consumption destruction, by using the impact-cutting method of destruction,

0 realizing the physics of curvilinear dependences of acceleration according to the laws of trigonometric functions and providing chip removal in the direction of previously obtained exposure.

5 The differential-wave destruction organ with the forced regulation of the destruction regimes can have a high degree of safety, since in it, without loss of working qualities, you can use very

0 low circular velocity of the flexible element and, accordingly, the tools. This feature sharply limits the possibility of injury to workers when seizing clothing or body parts with a moving tool, which is often

5 is observed during operation of the cutting drum or auger.

The use of this type of organ in the mining industry for the destruction of mineral strata during its extraction, in addition to the above indicators, allows us to expect a relatively larger chip, which should reduce dust formation, improve sanitary working conditions. Existing fracture organs using a chipping method are sources of large amounts of fine dust.

In addition to the named industry, this type of destruction organ can be used in construction on soil demolition and tamping machines, in agricultural machinery on soil cultivating machines or on cultivating machines for row crops, in municipal services on ice crust destruction or caking machines snow on the sidewalks, roads, runways of airfields, in mechanical engineering in the usual or profile processing of materials and, possibly, in optics in the manufacture of lenses with a complex aspherical profile, because the desired curvature and the pitch of the notches, in principle,

1

it is easy to obtain by changing the dimensions of the elements of the device and (or) the angular frequencies of the carrier wave generator and rigid element.

Claims (1)

The claims A mining machine including a housing in which an engine is connected, connected with a gear with the last drive sprocket of a bar working body mounted on the output shaft, having a housing with a bypass element, characterized in that, in order to reduce the energy intensity of the destruction of the rock mass, it is provided an additional adjustable engine connected by means of an additional gear transmission to the body of the bar working body, made in the form of two half-drives installed by means of output shafts additional gear transmission, and the output shafts of the two semi-driven and drive sprockets are mounted concentrically.