RU2009790C1 - Pipe cutting device - Google Patents

Abstract

FIELD: cutting of thin-walled pipes. SUBSTANCE: rolled pipes cutting device has hollow spindle, cutting tool and interconnected mechanisms for radial displacement and rotation of tool. Device includes also multiplier hooked up to electric motor. From one side multiplier is connected with rotating mechanism and from the other with mechanism of radial displacement of tool. Tool is made in the form of ring mounted eccentrically to spindle axis and provided with internal toothed thread and two flanges fastened to end faces of ring. Mechanisms of rotation and radial displacement of tool are associated through two screw-and-nut pairs with screw of each pair being freely located in spindle and on crank and nut is mounted movably along screw and is connected with cutting tool. Mechanism of tool rotation contains a pair diametrically positioned cranks connected with spindle and provided with longitudinal grooves for nuts of screw-and-nut pairs. Mechanism of radial displacement of tool has flanged bushing connected with multiplier trough gear drive, tapered gear mounted coaxially with flanged bushing and engaged with two tapered gears each of them being secured on screw of screw-and-nut pair. EFFECT: enhanced efficiency. 2 cl, 6 dwg

Description

 The invention relates to the processing of metals by cutting, in particular to devices for cutting pipes, and can be used for cutting cold rolled thin-walled pipes.

 A device is known for cutting pipes, including a bed on which a housing is mounted with a spindle mounted on it and connected to an electric motor through a V-belt drive. A countersink is mounted on the spindle for removing internal chamfers and a cutting tool made in the form of an abrasive wheel [1].

 The disadvantage of this device is the low quality of the processing of the ends of thin-walled pipes. This is due to the fact that when cutting pipes at their ends, burrs appear both inside and outside. The burrs on the ends of the pipes are manually removed first inside and then outside by applying the ends of the inclined pipe to the drill. Due to the fact that the pipe is inclined to the core drill, the axis of rotation of the core drill does not coincide with the longitudinal axis of the pipe, as a result of which the ends of the pipes are processed unevenly, which affects the quality of the processing of the ends of the pipes. Along with this, in some cases, jitter of the pipes occurs, which further impairs the quality of processing of their ends. In addition, when cutting a large amount of harmful dust is released, worsening the working conditions of workers.

 The closest in technical essence to the invention is a device for cutting pipes, including a bed, a housing placed on it, a hollow spindle mounted inside it on bearing bearings, a cutting tool connected to it in the form of a pair of cutters installed in calipers, which are connected with a profile ring to mechanisms of their rotation and radial movement [2].

 The rotation of the calipers with cutters is provided from the engine through a V-belt drive, a gear transmission, a spline shaft with a block of gears, gears interacting with it, mounted on the spindle of the profile ring connected to the calipers carrying the cutters.

 The radial movement of the cutters is provided by the movement of the profile ring relative to the calipers with the cutters due to the mismatch of the speeds of the gears associated with the profile ring and the gear associated with the calipers of the bearing cutter.

 The disadvantage of the prototype is that the cut is carried out on a short section of the perimeter of the pipe due to the small cutting surface of the cutter. As a result, when cutting, there is a drain chip, to remove which it is necessary to stop the device after each cut, which leads to a decrease in the productivity of the device.

 In addition, the presence of a profile ring allows you to cut pipes of a strictly defined assortment due to the lack of the possibility of automatic radial adjustment of the cutting tool in relatively small limits, i.e. it does not allow the cutting of thin-walled pipes with a wall thickness of 0.05-1.5 mm. This is due to the fact that the thickness of the cut is determined by a given profile of the ring, which leads to lower productivity and to limit the technological capabilities of the known device.

 The presence of a V-belt drive and a splined shaft in this device does not ensure smooth cutting of the cutting tool during the cutting process and its return to its original position, which will negatively affect the quality of the cut and productivity due to slippage of belts and pulleys requiring stopping of the device to replace them.

 The aim of the invention is to increase productivity in the processing of thin-walled pipes and the expansion of technological capabilities by increasing the assortment of processed pipes.

 This is achieved by the fact that the device for cutting rolled products contains a bed with a housing placed on it, a hollow spindle mounted inside the housing, a cutting tool with mechanisms of its rotation and radial movement, kinematically connected to each other, and a drive in the form of an electric motor.

 The proposed device is equipped with a gear multiplier connected to the motor shaft with a piston control system, connected through the main gear and the spindle to the rotation mechanism of the cutting tool and by means of an additional gear transmission, to the radial movement mechanism of the cutting tool, while the cutting tool is made in the form of a ring with a cutting part on the inner surface and the ends of the flanges wrapping around it, and the kinematic connection of the mechanisms of rotation and radial displacement Nia cutting tool is formed as a two screw pairs, screws are made with opposite threaded nut and mounted for reciprocating movement along the respective screw and are fixed to the flanges of the cutting ring.

 In addition, the rotation mechanism of the cutting tool is made in the form of two levers mounted diametrically opposite on the same axis on the spindle, each of which is made with a longitudinal guide groove for the screw pair nut and an end protrusion with a hole for its screw, and the cutting tool radial movement mechanism in the form of a sleeve freely mounted on the housing with a flange kinematically connected with an additional gear, a bevel pinion gear mounted coaxially in the said sleeve, and two followers x bevel gears, each of which is mounted on the screw of the corresponding helical pair with the possibility of interaction in the leading bevel gear.

 In FIG. 1 shows a kinematic diagram of a device; in FIG. 2 - device, General view in longitudinal section; in FIG. 3 is a section AA in FIG. 2; in FIG. 4 is a section BB in FIG. 3; in FIG. 5 - the relative position of the ring and pipe at the time of cut; in FIG. 6 - kinematic diagram of the multiplier.

 The proposed device comprises a frame 1, a housing 2 placed thereon, a hollow spindle 3 mounted in the housing on bearing bearings 4, a cutting tool in the form of a ring 5 and flanges 6 and 7, covering its ends, and a drive motor 8.

 The ring is made with a cutting part on the inner surface and is installed relative to the longitudinal axis of the spindle with an eccentricity E.

 The ring with its ends is connected to the flanges by bolts 9 and has mechanisms of its rotation and radial movement, which are kinematically connected by two screw pairs, the screws 10 and 11 of which have opposite threads, and the nuts 12 and 13 are mounted with the possibility of reciprocating movement along the corresponding screws and mounted on the flanges 6 and 7 of the cutting tool with bolts 14 and 15.

 The rotation mechanism of the cutting tool is made in the form of two levers 16 and 17 mounted diametrically opposite on the same axis on the spindle 3, each of the levers has a longitudinal guide groove for the nut 12 or 13 of the screw pair, and the end protrusions of the levers have holes for the screws 10 and 11 of these nuts.

 The radial movement of the cutting tool is made in the form of a sleeve 18 with a flange mounted coaxially on the drive bevel gear 19 and two driven bevel gears 20 and 21, each of which is mounted on the screw 10, 11 of the corresponding screw pair with the possibility of interaction with pinion gear 19.

 To drive the rotation mechanism and radial movement, the device is equipped with a gear multiplier 23 connected to the shaft 22 of the electric motor 8, having a piston control system 24.

 The multiplier comprises a shaft 25, coaxial with the motor shaft 22, on which the bevel gear 26 and the bevel gear 28 mounted through the bearing 27 are rigidly mounted. The bevel gear 30 and the carrier 31, 32 are mounted on the same shaft through the bearing supports 29, on which the bevel gears are freely mounted 33 and 34, installed in cooperation with gears 26, 28, respectively. The spur gear 30 cooperates with a rack 35 connected to the piston rod 36 of the control system.

 The multiplier through the main gear 37 and the spindle 3 is connected with the rotation mechanism of the cutting tool, and through an additional gear 38 - with the radial movement mechanism.

 To clamp the pipe 39 from the input and output sides of the device, collet clips 40 and 41 are installed.

 The device operates as follows.

 Before starting the device into operation, it is necessary to manually put the pipe 39 with the previously marked cut location in the groove (not shown in the drawing) and install it coaxially with the longitudinal axis of the spindle 3 by vertically moving the groove using, for example, a screw pair (not shown in the drawing). Then the pipe is moved manually inside the spindle and set it so that the marked place of the cut touches the cutting part of the ring 5. After that, the pipe is clamped with two collet clips 40 and 41.

 They include an electric motor 8, continuous counterclockwise rotation from which is transmitted through the shaft 25 of the main gear 37 to the bevel gears of the multiplier 26, 33, 34 and the additional gear 38. In this case, the gear of the multiplier 30 with the carriers 31, 32 is kept from rotating around the shaft 25 rail 35.

 The main gear transmission rotates the hollow spindle 3, then to two levers 16 and 17, movable nuts 12 and 13, and with them the ring 5 with flanges 6 and 7.

 An additional gear 38 transmits the rotation of the flange sleeve 18 and the bevel gear 19 with a speed equal to the speed of rotation of the levers 16 and 17 and, respectively, of the driven bevel gears 20, 21.

 For pipe cutting using a piston control system 24 of the multiplier rail 35, a longitudinal upward movement is reported. When this is transmitted rotation around the shaft 25 of the gear 30, the carrier 31, 32 with gears 33, 34 and gear 28, which reduces the speed of rotation of the additional gear 38. As a result, the speed of rotation of the flange sleeve and the bevel gear 19 is reduced.

 Reducing the speed of rotation of this gear leads to a mismatch of the speeds of rotation of it and the levers 16 and 17, which causes the rotation of the driven bevel gears 20, 21 and, respectively, of the screws 10 and 11. The screw 10 with the right thread, rotating, moves up the nut 12 respectively along the longitudinal groove the lever together with two flanges 6 and 7 and the ring 5. The screw 11 with the left-hand thread, rotating, moves up the nut 13, respectively, along the longitudinal groove of the lever together with the same flanges 6 and 7 and the ring 5. This joint movement of the nuts 12 and 13 provides ivaet corresponding displacement of the horizontal axis of the ring relative to the longitudinal axis of the spindle 3 and thus the pipe axis 39, increasing the magnitude of E ekstsentrisisteta ring 5.

 Therefore, the ring simultaneously with continuous rotation around the pipe for each revolution also continuously receives the offset of the axis of rotation of the ring relative to the longitudinal axis of the spindle. As a result of such simultaneous movement and circular rotation of the ring, its cutting part with the inside, continuously touching the perimeter of the pipe in an arc, cuts into its body, sequentially cutting sections of the pipe perimeter tangentially to its circumference.

 The specified process of cutting the pipe is carried out until it is completely cut. Then, the electric motor is turned off, the pipe is released from the collet clips 40 and 41, the cut pipe parts are manually removed from the hollow spindle. Both parts are placed in the receiving pocket.

 In order to return the cutting tool to its original position and thereby reduce its eccentricity, an electric motor is turned on, from which continuous rotation of the gears 37 and 38 is transmitted through the multiplier 23 with the rack 35 moving downward. The main gear 37 through the spindle, levers 16 and 17 and nuts 12 and 13 transmit the rotation of the ring 5 counterclockwise. Accordingly, the same rotation is transmitted from the nuts 12 and 13 through the screws 10, 11 to the driven bevel gears 20 and 21. With a speed equal to the speed of rotation of these gears, counterclockwise rotation from the additional gear 38 is transmitted to the flange sleeve 18 with the bevel gear 19.

 Then, by acting on the multiplier by the control system 24, the rotation speed of the main gear 37 is reduced. As a result, the rotation speed of the spindle 3, and therefore the nuts 12 and 13, the screws 10 and 11 and the driven bevel gears 20 and 21, which begin to receive rotation from their mismatch, is reduced speeds with the speed of rotation of the driving gear 19. From the bevel gears 20 and 21, the screws 10 and 11, rotating, impart a progressive movement to the nuts along the longitudinal grooves of the levers, reducing the amount of eccentricity to a value equal to its original discharge value, and then shut off the motor. When cutting another pipe, all operations are repeated in the same sequence.

 As that part of the perimeter of the cutting side of the ring wears out, the bolts fastening the nuts and the ring with flanges are unscrewed and the ring is turned so that its next part of the perimeter and cutting side is in contact with the pipe surface.

 The introduction of a controlled gear multiplier into the claimed device allows automatic mismatch of the speeds of rotation of the flange sleeve with a bevel gear and gears fixed on the turns, and thereby ensure the rotation of the screws at a strictly defined point in time without stopping the device both during cutting and at the time of cutting tool retraction in the starting position, which leads to increased productivity.

 The connection of the multiplier with the levers and the flange sleeve through a screw pair provides a smooth automatic increase during cutting and a decrease when the eccentricity of the axis of the ring with respect to the axis of the spindle returns to its original position, and this leads to a smooth cutting of the tool into the pipe and smooth regulation of the eccentricity of the axis of the ring and spindle without stopping the device when switching to cutting pipes of another assortment. This makes it possible to expand the technological capabilities of the device.

 The implementation of the cutting tool in the form of a ring with a cutting part on the inner surface ensures its contact with the pipe along an arc of a circle, which eliminates the appearance of burrs on the pipes, increases the resistance of the ring due to the introduction of levers that exclude its distortions, which also affects the increase in productivity.

 The proposed device can improve productivity, expand the range of rolled pipes, increase the smoothness of the device and thereby improve the quality of the cut and get crushed chips, easily removed during operation of the device. (56) 1. Bisk, M. B. et al. Cold deformation of steel pipes. Sverdlovsk: Middle Ural Book Publishing House, part 2, 1977, p. 158-159.

 2. Koff Z. A. et al. Cold rolling of pipes. Sverdlovsk: Metallurgy, 1962, p. 137-141.

Claims (2)

 1. DEVICE FOR PIPE CUTTING, containing a frame with a housing housed on it, a hollow spindle mounted inside the housing, a cutting tool with its rotation and radial movement mechanisms kinematically connected to each other, and a drive in the form of an electric drive, increasing productivity in the processing of thin-walled tubes and expanding technological capabilities by increasing the range of processed tubes, it is equipped with a gear multiplier connected to the shaft of the electric motor with a piston system second control, connected by means of the main gear and spindle with the mechanism of rotation of the cutting tool and by means of the mechanism of the radial movement of the cutting tool, while the cutting tool is made in the form of a ring with a cutting part of the inside and the inside thereof the connection of the rotation mechanisms and the radial movement of the cutting tool is made in the form of two screw pairs, the screws of which are made with opposite cuts, and the nuts are installed s chance vozvpatno translational motions are along the respective screws and zakpepleny pezhuschego flange ring.  2. The device according to p. 1, characterized in that the rotary mechanism of the cutting tool is made in the form of two levers mounted diametrically opposite on one axis on the spindle, each of which is made with a longitudinal guide groove under the screw pair nut and an end protrusion under it from screw, and the mechanism of radial movement of the cutting tool is made in the form of a sleeve freely mounted on the housing with a flange kinematically connected with an additional gear drive, a bevel gear mounted coaxially mounted in the aforementioned the bushing, and two driven bevel gears, each of which is mounted on the screw of the corresponding screw pair with the possibility of interaction with the drive bevel gear.

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