RU2323822C2 - Device with flexible endless operating element - Google Patents

Abstract

FIELD: mechanics, mining.

SUBSTANCE: device consists of at least one flexible endless operating element movably installed in a ring slot of drive roller and clamped around the arc of the drive roller ring slot with belt of the drive; belt drive is assembled on the side diametrically opposite to guide rollers. Drive roller is kinematically connected to the main drive of the device. Branches of the flexible endless operating element are movably installed in the ring slot of the driven roller and are supported by the guide rollers equipped with ring slots. Branches of the flexible endless operating element form an open pendent lap on the side diametrically opposite to the drive roller.

EFFECT: increase of operating element durability and decrease of power consumption of cutting operation.

9 cl, 4 dwg

Description

The invention relates to the field of extraction and processing of various solid materials by cutting using a flexible endless working body, for example, stone mining and stone processing.

Currently, machines with a flexible endless working body are widely used for the extraction and processing of various stone materials by cutting.

A known installation for rope sawing of stone, containing vertical guides connected in the upper part of the beam, on which the calipers with a displacement drive are located, pulleys mounted on the calipers, one of which is connected to an electric motor, covered by an endless cutting body in the form of a rope (copyright certificate SU 1065218 A Cl. B28D 1/08; 01/07/1984; Bull. No. 1).

In all known installations for the implementation of the technological process of cutting, it is necessary to create a certain value of the contact pressure between the flexible endless working body and the processed material. Normal contact pressure is created by tensioning a flexible endless working body, which is previously tightened on the drive pulleys to transmit to it the movement of the corresponding power. The magnitude of the pre-tensioning force is commensurate with the working force, and the stresses due to the action of these forces are inversely proportional to the cross-sectional area of the bearing part of the flexible endless working body. On the other hand, the stresses arising from the bending of a flexible endless working body on the drive pulleys are proportional to the ratio of the diameter of the cross section of the bearing part of the working body to the diameters of the drive pulleys. The task of minimizing the diameter of the bearing part of the flexible endless working body is complicated by the fact that a decrease in the values of bending stresses by increasing the diameters of the drive pulleys leads to an increase in the center distance of the transmission and for the implementation of the technological process it is necessary to increase the preliminary tension of the flexible endless working body. A significant part of the strength resources of the bearing part of the endless working body is spent on resistance to preload and bending on drive pulleys.

Given that the cutting process occurs at speeds of 30-40 m / s, diamond perlins installed periodically on the bearing part of a flexible endless working body undergo large shock loads at the entrance to the cutting zone, which negatively affects the strength of the flexible endless working body.

The inefficient use of the strength resources of a flexible endless working body leads to an increase in the diameter of the bearing part of the flexible endless working body, and the relatively long cutting zone makes it difficult to remove the products of the cutting process and creates conditions for wear of the working body.

All of the above is the reason for the unreasonably large cutting width when using these machines, a decrease in the durability of a relatively expensive working body, an increase in the energy intensity of the technological process, and an increase in the proportion of waste relative to the finished product.

The basis of the present invention is the creation of a machine for cutting various solid materials using a flexible endless working body with such a design that would eliminate the above disadvantages.

This problem is solved by creating a device comprising at least one flexible endless working body, a drive mechanism consisting of a belt drive and provided with an annular groove of the drive roller, which is kinematically connected with the main drive of the device, at least one driven roller and one pair guide rollers provided with annular grooves and a device body, characterized in that the flexible endless working body is movably mounted in the annular groove of the drive roller and pressed along the circular arc of the annular groove and a belt of a belt drive mounted on the diametrically opposite side of the guide rollers, and the branches of the flexible endless working body are movably mounted in the annular groove of the driven roller and supported by diametrically opposite mounted guide rollers, forming a hanging open loop on the diametrically opposite side of the drive roller.

The main principle of operation of the proposed device is that centrifugal inertial forces arising in a hanging open loop when the flexible infinite working body moves along a curved path serve to tension a flexible infinite working body. The hanging open loop of a flexible endless working body, under the action of centrifugal forces, acquires sufficient elastic stiffness for the implementation of the cutting process. Given that the cutting of hard rocks is carried out at high speeds (for diamond cutting up to 30 ÷ 50 m / s), using the proposed device, you can get the tension of a flexible working body, quite sufficient for the cutting process. For example, for existing flexible working bodies equipped with diamond-containing perlins with a diameter of 11 mm, at a speed of 40 m / s, the tension force of the endless working body in the cutting zone is more than 1000 N. Moreover, an increase in the depth of cutting leads to a decrease in the tension force of the flexible endless working body, which eliminates the rupture of a flexible endless working body during overloads.

To transmit movement to a flexible endless working body, a drive mechanism is used, which consists of a drive roller equipped with an annular groove and a belt drive. The belt drive is installed in the plane of the drive roller from the side diametrically opposite from the guide rollers and the outer side of the belt, wraps around a part of the circular arc of the annular groove of the drive roller. An end open loop of a flexible endless working body is installed in the annular groove of the drive roller and is pressed against the roller in the zone of contact with the belt. This design allows the flexible working body to transmit the movement of the required power with a relatively small amount of tension, and there is no need to create a preliminary tension of the flexible endless working body. To ensure the durability of the belt and ensure high speeds of the flexible endless working body, it is convenient to use a gear-belt transmission. The structural elements of a belt drive must be calculated from the condition of ensuring their strength when creating the necessary contact pressure on a flexible endless working body using a belt. The magnitude of the contact pressure is determined from the condition of contact of the flexible endless working body with the annular groove of the drive roller at a maximum speed of rotation of the drive roller. The diameter of the drive pulley is determined from the strength condition of the flexible working body when it is subjected to the tension and bending necessary for cutting along the radius of the drive roller. Using the motion transmission device of our design allows us to ensure the minimum diameter of the drive roller and regardless of the speed of the flexible endless working body to ensure the transmission of the drive power necessary for the cutting process.

The driven roller is installed between the branches of a flexible endless working body on the diametrically opposite side of the belt drive. To ensure uniform motion of both branches of a flexible endless working body, the diameter of the driven roller is selected in such a way as to ensure a partial fit of the branches of the working body along the arcs of the annular groove of the driven roller.

Guide rollers equipped with annular grooves are installed on both sides of the driven roller on the device body and are designed to maintain the direction of movement of the branches of the flexible working body. The axes of the guide rollers are offset towards the hanging open loop of the working body and are installed in such a way as to ensure contact between the branches of the flexible endless working body and the annular groove of the driven roller. Considering that the rope tension force is much smaller than in existing machines, and the bending stresses arising in a flexible endless working body are relatively small, the diameter of the guide rollers can only be selected for design reasons.

The relatively small tension of the rope and the absence of the possibility of its growth during cutting can significantly reduce the diameter of the bearing part of the flexible endless working body and thereby increase the thickness of the diamondiferous layer on the perlins or reduce the outer diameter of the perlins, which will increase the durability of the flexible working body and reduce the energy consumption of the process .

To uniformly wear diamond pearls and increase the durability of a flexible endless working body, two identical driven rollers are mounted coaxially, offset in different directions relative to the middle plane of the drive roller. Accordingly, guide rollers are also displaced and mounted in the planes of the driven rollers. In this case, the branches of a flexible endless working body in the interval between the driving and driven rollers are crossed straight lines. The angle of coverage of a flexible endless working body of both the drive roller and driven rollers is increased. The resultant of the friction forces, which acts on the cylindrical surface of the flexible working body from the side of the walls of the annular grooves of these rollers, creates a torque that allows it to be twisted relative to its geometric axis. By changing the displacement of the driven rollers, it is possible to adjust the speed of twisting of a flexible endless working body.

Having additionally installed two pairs of guide rollers equipped with annular grooves, perpendicular to the plane of the drive roller, additional rigidity can be given to a flexible endless working body in this plane.

For a deep cut, the drive mechanism can be moved relative to the guide rollers, changing the length of the hanging part of the flexible endless working body. At the beginning of the cutting process, the drive mechanism is located at a maximum distance from the guide rollers and the length of the hanging part of the flexible endless working body is minimal, which gives it maximum rigidity. In the future, the depth of cut can be set by moving the drive mechanism relative to the guide rollers. If it is necessary to carry out a change in the length of the hanging part of the flexible endless working body during the cutting process, it is better to use the scheme of two identical offset driven rollers. In this case, the rollers must be kinematically connected in such a way as to ensure their mutual rotation only at the working speeds of a flexible endless working body. For example, they can be connected using a normally closed centrifugal friction clutch.

To ensure constant contact pressure on a flexible endless working element on a belt drive of the drive mechanism to establish a lingering mechanism. The mechanism will provide the necessary contact pressure on the flexible endless working body, regardless of the magnitude of its wear.

It is possible to provide ring grooves of guide rollers with a layer of friction coating (for example, EPDM 80 plastic), which will significantly increase their durability and reduce the abrasion of diamond grains.

You can equip the device with several flexible endless working bodies, which will allow for simultaneous cutting in several parallel planes. Moreover, the total number of sets of drive mechanisms, driven and guide rollers is equal to the number of flexible working bodies used. To simplify the installation of the thickness of the cut plates, it is convenient to set the kits staggered. Moreover, in contrast to existing machines that use complex tension mechanisms, the proposed design provides almost uniform tension of a flexible endless working body.

You can equip the device with a system for supplying water to the cutting zone. This will increase the durability of the flexible endless working body.

Considering that ultrasonic vibrations favorably affect the cutting process and the design of the machine allows them to be created, it is possible to provide a motion transmission device with an apparatus for creating ultrasonic vibrations of the working body directly in the cutting zone.

For a better understanding of the invention, schematic images of the device are provided.

1 and 2 schematically depicts a device with a flexible endless working body according to the invention.

Figure 3 and 4 schematically depict a device with offset driven rollers.

The proposed device with a flexible endless working body includes a housing 1 (Fig. 1), on which a belt gear 4 is movably fixed and a drive roller 3 is mounted symmetrically to it. A flexible endless working body 2 is installed in the annular groove of the drive roller 3, which is pressed by a belt 5 transmission 4. The drive roller 8 is mounted on the axis of symmetry of the drive mechanism, and the branches of the flexible endless working body 2 mounted in its annular groove are supported by guide rollers 6. Outside the device body 1 is open hanging flexible endless loop working body on July 2.

Figure 2 shows a schematic illustration of a device that is equipped with two coaxial identical driven rollers 8 and 9, offset in different directions from the drive roller 3. The branches of the flexible endless working body 2 in the gap between the drive mechanism and the driven rollers 8, 9 are crossed. The belt drive is equipped with a tightening mechanism 11, the driven rollers 8 and 9 are kinematically connected by a normally closed centrifugal friction clutch 10.

The device operates as follows.

The main drive of the device turns on. By means of a drive mechanism, a flexible endless working body is communicated with a working movement. After reaching the contact of the endless working body with the processed material, the cutting process begins.

The present invention can be used in the extraction and processing of various stone materials.

Claims (9)

1. A device with a flexible endless working body for processing solid materials, comprising at least one flexible endless working body, a drive mechanism consisting of a belt drive and provided with an annular groove of the drive roller, which is kinematically connected with the main drive of the device, at least , one driven roller and one pair of guide rollers provided with annular grooves, and a device body, characterized in that the flexible endless working body is movably mounted in the annular groove of the drive roller and pressed along an arc of a circumference of an annular groove with a belt transmission belt mounted on the diametrically opposite side of the guide rollers, and the branches of the flexible endless working body are movably mounted in the annular groove of the driven roller and supported by diametrically opposite mounted guide rollers, forming a hanging open loop on the diametrically opposite side of drive roller. 2. The device according to claim 1, characterized in that in the planes offset relative to the plane of the drive roller, two driven rollers are installed, and the branches of the flexible endless working body, in the gap between the driving and driven rollers, are crossed straight. 3. The device according to claim 1 or 2, characterized in that the drive mechanism can move relative to the guide rollers, changing the length of the hanging part of the flexible endless working body. 4. The device according to claim 1, characterized in that the belt drive is equipped with a lingering mechanism that provides the necessary contact pressure on a flexible endless working body. 5. The device according to claim 1, characterized in that it is equipped with a guide installed in the direction of cutting, and a feed drive for cutting. 6. The device according to claim 1, characterized in that the annular grooves of the drive and guide rollers are provided with a friction coating. 7. The device according to claim 1, characterized in that it is equipped with several flexible endless working bodies. 8. The device according to claim 1, characterized in that it is equipped with a device for supplying water to the cutting zone. 9. The device according to claim 1, characterized in that the device is equipped with an apparatus for creating ultrasonic vibrations of a flexible endless working body.

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