RU64113U1 - SURFACE ACTIVATION DEVICE AND CLEANING WIRE OR ROUND RENT - Google Patents

Abstract

The utility model relates to metallurgy and can be used, in particular, when activating and cleaning the surface when preparing the product for coating, or when cleaning the surface from scale during wire or round production. The utility model can also be used in any other areas of mechanical engineering. The device for activating the surface and cleaning the wire or round rolling comprises a rotation drive mounted on the base of a hollow shaft with an axial hole for passage of the workpiece and at least one working unit, and a washer fluid supply and removal device connected to the hollow shaft, a rotation drive made in the form of a pulley mounted on a hollow shaft, and bevel gears, one of which is fixedly mounted on the base, and the other - rotating - are connected to the cleaning elements, the hollow shaft is installed n with the possibility of rotation inside a fixed bevel gear, is equipped with means for installing a working unit with cleaning elements perpendicular to the axis of the hollow shaft and is made with expansion in the middle part for working unit elements interacting with the workpiece, the cleaning elements of the working unit are installed with the possibility of rotational and translational , while the device is equipped with eccentric levers mounted on the pulley with the ability to move when the pulley rotates around its axis under the action of centrifugal forces in such a way as to exert pressure on the cleaning elements. The technical result of using the utility model is to ensure intensive activation of the surface of the product and effective cleaning in a wide range of modes.

Description

The utility model relates to metallurgy and can be used, in particular, when activating and cleaning the surface, carried out during preparation of the product for coating, or when cleaning the surface from scale during the production of wire or round rolled products. In addition, the utility model can be used in any other areas of mechanical engineering.

Various wire cleaning devices are known in the art (DE 2536605, SU 1572724, SU 1831395). It is known, in particular, a device for cleaning the wire from scale, comprising at least two rollers mounted on axles with the possibility of rotation and located in mutually perpendicular planes, one of the rollers being mounted on the axis eccentrically (USSR author's certificate No. 764762, 21 V 45/04, 1980).

This device provides descaling, but is not intended to activate the surface of the product.

The closest analogue is a device for cleaning wire or round rolled products, including a working chamber filled with a liquid medium, into which a cleaning mechanism is immersed, configured to pass through it in the horizontal direction of the wire to be cleaned or rolled round, while the cleaning mechanism is made in the form of a cylinder mounted with the possibility of rotation and consisting of at least two segments in which elements of abrasive material are installed located on an elastic substrate, which both sintering the pressing of abrasive material to the surface to be cleaned (patent RU 2201304, B 21 C 43/04, 2003).

The closest analogue does not have good operational properties, due to the fact that when it is used in a continuous technological cycle in the cleaning zone, processing products accumulate. The flushing provided by the liquid pumped through the treatment zone cannot be intensified, since the volume of the pumped liquid and the pumping speed are limited. In addition, the device does not provide intensive activation of the surface of the product due to the fact that abrasive particles act on the surface in mutually perpendicular directions: translationally (moving the workpiece) and around the circumference of the product.

The objective of the utility model is to ensure intensive activation of the surface of the product and effective cleaning in a wide range of modes.

The problem is solved due to the fact that the device for surface activation and cleaning of wire or round products contains a rotation drive mounted on the base of the hollow shaft with an axial hole for the passage of the workpiece and at least one working unit, and the device is connected to the hollow shaft supply and removal of washer fluid, the rotation drive is made in the form of a pulley mounted on a hollow shaft, and bevel gears, one of which is fixedly mounted on the base, and the other is rotating, connected data with cleaning elements, the hollow shaft is mounted for rotation inside a fixed bevel gear, equipped with means for installing the working unit with cleaning elements perpendicular to the axis of the hollow shaft and is made with expansion in the middle part for working unit elements interacting with the workpiece, cleaning elements of the working unit installed with the possibility of rotational and translational movement, while the device is equipped with levers, levers, eccentrics, representing

levers of the first kind with weighting (weight) at one end, and each lever is mounted to rotate relative to its own axis of rotation, providing due to the difference in centrifugal forces acting on the ends of the lever during rotation of the pulley, lifting one end of the lever with a weight and creating pressure on rod of the cleaning element at the other end of the lever without a weight.

The hollow shaft is made with shanks for installation in bearings, with one bearing mounted directly on the base, and the housing of the second bearing is the tail of the fixed bevel gear.

The expansion in the middle part of the shaft is made with two mutually parallel milled planes for landing and fixing the half shafts in which the rods of the cleaning elements are installed, while an opening for the rotating cleaning elements is formed inside the expansion of the hollow shaft, the axis of which is perpendicular to the axis of the shaft.

On the outer surface of each shaft axis of the cleaning element, one (or two, or more) rotation bearings are mounted on which a rotating bevel gear is fixed, sliding bearings are installed in the inner hole of the axle shafts, and the hubs are fixed to the end surfaces of said gear wheels so that they have the possibility of rotation together with gears in sliding bearings inside the axle shafts, and rods rotating together with the hubs are mounted inside the hubs, on which the abra are fixed active disks, and the rods are mounted with the possibility of axial movement. In the tail parts of the rods there are thrust bearings, providing transmission of the pressing force from the eccentric levers through the rods to the abrasive discs (cleaning elements) that affect the machined

surface. Rods with abrasive disks (cleaning elements) are spring-loaded to divert the disks from the work surface when the rotation drive is disconnected.

The technical result of using the utility model is to ensure intensive activation of the surface of the product and effective cleaning in a wide range of modes. The proposed implementation of the drive device in combination with the location and execution of the work node allows you to effectively act on the surface to be worked, to work in a wide range of modes. This is due to the fact that the amount of force to compress the abrasive disks to the surface to be treated is easily adjustable, since it is determined by the speed of rotation of the pulley and the centrifugal force depending on it acting on the weights of the eccentric levers, which, in turn, ensures the creation of a force compressing the abrasive disks to the processed surface. Provided by the claimed device combination of different speeds of rotation of the pulley and speeds of movement of the wire or round rolled through the axial hole of the hollow shaft, it is possible to achieve high quality surface cleaning and, if necessary, high surface activation efficiency.

The utility model is illustrated in the drawing, on which the elements of the device are marked with positions: 1 - base; 2 - bearing housing; 3 - hollow shaft bearing; 4 - jet; 5 - camera feed removal; 6 - a sealant; 7 - a hollow shaft; 8 - a half shaft representing the rod body of the cleaning element; 9 - a sealant; 10 - plain bearing; 11 - a sealant; 12 - a nave; 13 - a pulley; 14 - a casing; 15 - clutch lever; 16 - axis of the lever-clown; 17 - thrust bearing; 18 - coupling; 19 - finger; 20 - adjustable spring; 21 - a stock; 22 - rotating bevel gear; 23 - bearings of a movable gear; 24 - abrasive disk (cleaning element); 25 - fixed bevel gear; 26 - clamping spring.

The device according to the claimed utility model comprises a rotating hollow shaft 7 mounted on the base 1, on which at least one working unit is mounted. The working unit rotates around its axis in a cylindrical opening, the axis of which is perpendicular to the axis of rotation of the shaft 7. The shaft 7 is rotated using a belt drive inside a stationary bevel gear 25. The bevel gear 22 engaged with it, worn on the axis of the cleaning element with an abrasive disk 24, when the shaft 7 is rotated, the abrasive discs are driven. The pulley 13 is mounted on the shaft 7 so that the eccentric levers 15 located on the wheel, when it rotates with its working surface (the end of the lever without a weight), abut against the tail of the cleaning element with the abrasive disk 24. With an increase in the speed of rotation of the shaft 7, the centrifugal force increases, acting on the weights in the radial direction (perpendicular to the axis of rotation), and accordingly increases the pressure of the abrasive discs 24 to the surface being cleaned due to the centrifugal forces mentioned. In this case, the pressing force of each of the abrasive disks 24 to the surface to be cleaned is the same and depends on the speed of rotation of the shaft and the mass of the weight of the lever-clown 15.

The presented variant of the concrete implementation of the utility model has one working unit.

On the base 1, a bearing housing 2 is fixed from one end of the shaft 3, a fixed bevel gear 25 is fixed at the opposite end, the tail of which is the housing of the second shaft bearing 7. In the bearings of the hollow shaft 7, the hollow shaft 7 rotates inside the fixed bevel gear 25. due to the coupling of the movable bevel gears 22 and the stationary bevel gear 25, torque is transmitted from the shaft 7

on cleaning elements — abrasive disks that simultaneously activate the surface being cleaned.

The hollow shaft 7 has shanks for planting the shaft in the bearings 3 and securing the pulley 13, and the inner cavity of the shaft 7 is made with expansion in its middle part. The internal cavity of the shaft 7 in the expansion zone has two mutually parallel milled planes for seating and fixing the axle shafts 8. Inside the expansion of the internal cavity of the shaft 7, a cylindrical hole is formed, the axis of which is perpendicular to the axis of the hollow shaft 7, cleaning elements rotate inside this hole. To freely remove the washer fluid from the cleaning zone, a groove (not shown) is made that increases the cross section of the formed channel.

Working nodes are made as follows. Axles 8 are mounted on the hollow shaft 7, toothed wheels 22 are mounted on them in bearings 23 and rotate 22. With the help of fingers 19, hubs 12 are fixed on the end surfaces of gears 22, and so that they rotate together with gears 22 in sliding bearings 10 inside the axle shafts 8.

Seals 9 prevent the washer fluid from entering the channel inside the shaft into the area of the sliding bearing 10.

Inside the hubs 12, rods 21 are placed on which abrasive disks are fixed 24. The rods 21 with abrasive disks 24 are rotated together with the hubs 12, the movement is transmitted using the fingers 19 and couplings 18. The design of the coupling 18 allows the rod 21 to move along its axis and, thus, to press the abrasive discs 24 to the work surface. Seals 11 prevent washer fluid from escaping. In the rear parts of the rods 21 are thrust bearings 17, with which the force is transmitted

from the eccentric levers 15 through the rods 21, while the abrasive discs are pressed against the work surface.

The eccentric levers 15 are mounted on the pulley 13 in such a way that when the pulley rotates, they can move around the axis 16 under the action of centrifugal forces so as to exert pressure on the thrust bearing 17. The pulley 13 is mounted on the shaft 7 and rotates it using a belt drive.

After stopping the shaft 7, the spring 20 spreads the abrasive discs 24, this makes it possible to freely enter the product being cleaned into the device. The spring 26, in this case, presses the cam part of the eccentric lever 15 to the thrust bearing 17.

The moving parts of the device are closed by a casing 14.

To supply and remove washer fluid from the zone of waterjet cleaning to the bearing housing 2 and to the rear of the stationary gear wheel 25 hermetically connected camera feed and remove washer fluid. These chambers are a housing 5 with a nozzle for supplying or removing washer fluid and a nozzle 4, inside which the wire moves. The seal 6 protects the bearing 3 from the ingress of washing fluid. The inner diameter of the nozzle is slightly larger than the diameter of the workpiece, which makes it difficult for the washer fluid to exit through the inlet and outlet of the cleaning device.

Claims (7)

1. A device for activating the surface and cleaning the wire or round rolled, comprising a rotation drive mounted on the base of a hollow shaft with an axial hole for passage of the workpiece and at least one working unit with cleaning elements, and a feed device is connected to the hollow shaft and washer fluid removal, characterized in that the rotation drive is made in the form of a pulley mounted on a hollow shaft, and bevel gears, one of which is fixedly mounted on the base, and the other rotating with They are equipped with cleaning elements, which are abrasive disks, cleaning elements are mounted on rods installed in the working unit with the possibility of rotational and translational movement, while the device is equipped with a means of regulating the pressing of the cleaning elements to the work surface, made in the form of eccentric levers fixed with the possibility of rotation around its axis under the action of centrifugal forces so as to exert pressure on the rod of the cleaning element. 2. The device according to claim 1, characterized in that the hollow shaft is mounted to rotate inside a fixed bevel gear, is equipped with means for installing a working unit with cleaning elements perpendicular to the axis of the hollow shaft, and the axial hole of the hollow shaft is made with expansion in the middle part for placement of elements of the work node, including interacting with the workpiece. 3. The device according to claim 2, characterized in that the hollow shaft is made with shanks for installation in bearings, wherein one bearing is mounted directly on the base, and the housing of the second bearing is the tail of the fixed bevel gear. 4. The device according to claim 2 or 3, characterized in that the expansion in the middle part of the shaft is made with two mutually parallel milled planes for landing and fixing the half shafts in which the rods of the cleaning elements are installed, while a hole for rotating cleaning is formed inside the expansion of the hollow shaft elements whose axis is perpendicular to the axis of the shaft. 5. The device according to claim 4, characterized in that on the outer surface of the half shafts of the rods of the cleaning elements are mounted rotation bearings on which a rotating bevel gear is fixed, sliding bearings are installed in the inner hole of the half shafts, while the hubs are fixed on the end surfaces of said gears so that they can rotate together with gears in sliding bearings inside the axle shafts, moreover, rods rotating together with the hubs are placed inside the hubs, on which CREPLA abrasive wheels, the rods are mounted for axial movement. 6. The device according to claim 5, characterized in that in the rear parts of the rods there are thrust bearings that provide transmission of the pressing force from the eccentric levers through the rods to the abrasive disks acting on the workpiece surface. 7. The device according to claim 4 or 5, characterized in that the rods with abrasive disks are spring-loaded to divert the disks from the machined surface when the rotation drive is turned off.