RU2539520C2 - Multidie machine for billets trimming - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to metallurgy. Proposed multidie comprises frame with load-bearing pipes secured thereat, at least two traction drums to run in pipes in bearings driven by engine with step-down reduction gearbox and gear-box, and drawing tools. Said frame represents a truck frame while the drive of drums is composed of assembly units and parts of automotive transmission. Note here that step-down reduction gearbox is composed by truck transmission main gear with 1^st and 2^nd axles making the step-down reduction gear output shafts. Gear-box represents the truck gear-box. Note also that 1^st traction drum is engaged with 1^st axle while 2nd traction drum is engaged with 2^nd axle by links to make axles transmit torque and equal torques at traction drum shafts by means of the truck transmission differential mechanism. Besides, bypass roller is arranged between traction drums to set wire path from 1^st drum to drawing tool arranged ahead of 2^nd traction drum. Transmission elements are welded to aforesaid frame. Bearing pipes are fitted at load-bearing branch pipes to transfer working loads from said drum to said frame.

EFFECT: better drawing characteristics plus possibility of mill manufacture and operation at small-scale enterprises at low costs.

3 cl, 2 dwg

Description

The invention relates to drawing and calibration production, in particular to drawing mills and related equipment for wire drawing and calibration of long cylindrical products.

Known "In-line drawing mill" (RF Patent No. 2144854, IPC ⁷ B21C 1/08 from 01/27/2000, bull. No. 3), including sequential dies and corresponding to them, traction drawing drums, working surfaces mounted on parallel two-support drive shafts which are made in the form of truncated cones, each die placed in the plane of the larger base of the conical working surface of the traction drum corresponding to it, and the working surfaces of even and odd broaching wires of traction drawing wires arabans are made with mutually inverse tapers.

Although this design of a direct-flow drawing mill allows to improve the quality of the metal of the processed wire by reducing the degree of strain hardening due to the exclusion of other bending deformations of the wire, in addition to the necessary winding on the traction drums.

The disadvantages of such a direct-flow mill include the inability of its design to manufacture, assemble, set up and configure in a small enterprise. For example, the two-bearing drive shafts of the drums are load-bearing, that is, they receive the traction load on each drum, and they (and their bearings) must be specially reinforced.

In addition, for the drive of each traction drawing drum of such a mill, only a direct current electric motor should be used, since a necessary condition for designing a drawing mill of precisely a direct-flow type is an equal distribution of torques along the drive shafts of the drums, and their excess is redistributed across all drive shafts through counter-tension each die. This is usually achieved by sequentially connecting the drive motors to the DC source circuit, that is, a step-down transformer with a semiconductor rectifier with a thyristor control circuit, which in combination is complex and currently very expensive.

Also known is the "Differential" [Petrov GG, Udler E.I. Car transmission (structural analysis, calculation basics): a training manual. - Tomsk: publishing house Tom. state arch-build. University, 2008, 256 p., p. 201].

Differential - a transmission mechanism that provides the distribution of the supplied torque between the output shafts and allows the driven shafts to rotate with different angular speeds.

Differential, therefore, in contrast to the aforementioned drive electric motors in a direct current circuit (step-down transformer, semiconductor rectifier, thyristor control circuit), which contribute to the achievement of simple, affordable and cheap means of the goal - a necessary condition for the design of a direct-flow drawing mill - equal distribution of torques along the drive shafts of the drums and the redistribution of their surplus over all the drive shafts of the traction drums by means of anti-tension.

The disadvantages of the differential transmission of torques and angular speeds of rotation is its use, as a rule, in the construction of transmissions of drives of automobile vehicles. In addition, the use of differential transmission is possible only between two drawing drums, as a result of which the drawing mill will turn out only 2-fold, no more, since differential transmission is applicable only between the semi-axles of the driving (rear) wheels of the car.

Also known "Transfer case with differential drive" [Petrov GG, Udler E.I. Car transmission (structural analysis, calculation basics): a training manual. - Tomsk: publishing house Tom. state arch-build. Univ., 2008, 256 p., p.143]. The transfer case is designed for transmission and distribution of torques between the drive axles of multi-drive vehicles. By the nature of the division of the power flow, the transfer boxes can be: with a locked drive, with a differential drive, with a mixed drive (used with 3 driven shafts).

This analogue, when used along with the differential between the axles of the drive axle, can be placed between the drive axles, if there are several of them and can eliminate the second drawback: combine pairwise drawing drums kinematically into a single direct-flow chain. As a result of this, after eliminating the first drawback regarding the field of application, we obtain a multiple straight-line drawing mill.

The closest in technical essence the device (prototype) is “Traction device of the drawing mill” [RF Patent No. 2029643, IPC B21C 1/14, 02/27/1995, B.I. No. 6, S. A. Kuznetsov, E. A. Garber, A. A. Kazantsev, K. E. Garber]. The traction device of the drawing mill includes a frame mounted in a frame on bearings of the drive shaft, a drawing drum having a profiled working surface with a fillet is rigidly fixed to its cantilever end. The frame is equipped with a hollow pipe covering the drive shaft, and the drum is equipped with an additional support mounted on this pipe using a pair of bearings symmetrically placed on both sides of the axis of the drum fillet.

Indeed, the main distinguishing feature of this known invention is the separation of the characteristic functions of the main element of the drive mechanism of the drawing mill - the spindle of the drum. Its 1st function is to transmit to the drum torque and angular velocity for its rotation, that is, a function due to which the spindle is an element of the drum rotation drive. The 2nd function is the carrier, that is, the spindle also receives the power load from the wire tension.

Thus, according to this known invention, the drive function of the spindle is played by the drive shaft, and the bearing by the hollow pipe with an additional drum support. Due to this separation of functions, both elements (shaft and pipe) are made with less material consumption due to the simplification of the nature of the transmitted and perceived loads. Thus, the drive shaft of the drawing mill cannot be called a spindle, since it transmits only torque, and the support pipe plays only a bearing function, similar to the function of the housing or frame.

The disadvantages of the "Drawbar traction device" are as follows:

- not enough good technological parameters of the drawing process;

- the unsuitability of the design of the drive of the drawing mill for manufacturing and operation in a small enterprise;

- high costs for the manufacture of drawing mill due to the use of non-standard components and machine parts.

The objectives of the invention involve the rejection of these disadvantages, that is, the adaptation of the design of the drive of the drawing mill to the study of the technology of drawing and improving this process, namely:

- improvement of technological parameters of the drawing process;

- adaptation of the design of the drive of the drawing mill to its manufacture and operation in a small enterprise;

- reducing the cost of manufacturing a drawing mill through the use of ready-made standard mechanisms, components and machine parts.

The objectives of the invention are performed by the fact that in a multiple direct-flow drawing mill for calibrating workpieces, including a frame, a support pipe fixed to it, a traction drum mounted on a pipe between bearings, a reduction gearbox connected to the drive motor through the gearbox, a gearbox output shaft connected to the traction drum, according to the invention, the car frame is used as the frame, the main gear of the automobile transmission is used as the reduction gear, as the output The axle shaft of the vehicle’s transmission was used on the shaft of the reduction gear, the gearbox of the vehicle was used as the gearbox, the 1st traction drum was connected to the 1st semi-axis of the automobile transmission, the 2nd traction drum was connected to the 2nd semi-axis of the automobile transmission, as an element that sets the path of the wire after leaving the 1st drum to the drawing tool in front of the 2nd traction drum, a roller with a diameter equal to the gauge of the car is used, the roller is installed with the possibility of it freely of rotation, as an element that ensures equal torques on the shafts of the reels, applied differential of an automobile transmission.

In addition, as an element ensuring equal torque on each pair of differentiated drums, a transfer case with a differential drive from the vehicle’s transmission can be used.

In addition, the traction drum can be made stepwise with differential coupling between the steps.

In addition, the suspension elements of the car frame on the car transmission can be replaced with more rigid elements.

In addition, a set of individual supports can be used as an automobile frame.

Multiple direct-flow drawing mill for calibrating workpieces is illustrated in figure 1, 2.

Figure 1 shows a 2-time straight-type drawing mill, available for manufacture on its own in a small enterprise, the elastic elements of the suspension of the automobile frame on the transmission are replaced by more rigid elements, the drive axles of the drawing drums are connected by a differential gear.

Figure 2 shows a 4-time straight-through drawing mill, available for manufacture in a small enterprise, with differential gears between the pairs of axle shafts of the drums and with a differential transfer box between the differentials of the pairs of drawing drums.

In the figures, the direction of broaching the workpiece is indicated by contour arrows.

The multiple direct-flow drawing mill for calibrating workpieces is made in such a way that:

- A support pipe is fixed on the frame, a drum is mounted on the pipe between the bearings, it is connected to the drive motor through the gearbox and the reduction gear, the output shaft of the gear is connected to the traction drums through their axle shafts and the differential between them, and the car frame is used as the frame, The main transmission of the vehicle’s transmission was used as a reduction gear, the semi-axis of the vehicle’s transmission was used as the output shaft of the reduction gear, and the gearbox was used and the box of the car changes gear, as part of ensuring the equality of the torques on the shafts of traction drums, applied differential of an automobile transmission.

Indeed, the listed structural features of the drawing mill allow it to be performed from a set of interconnected parts, components and mechanisms of the automobile transmission, standard and ready for use as components of the drive of the drawing mill drums, not subject to manufacture ["Combination of wire mill descaling and drawing processes wire in a single technological line ”, study guide. - Cherepovets: ChGII, 1996, S. A. Kuznetsov, E. A. Garber, p.40].

- At the same time, since the transmission differential of the car is used as an element ensuring the equality of torques on the shafts of the drums, the drawing mill with this drive design is obtained at least 2 times with the direct principle.

Indeed, if the torques on the shafts of the drums are equal, then, provided that the diameters of the drums are equal, the drawing forces of both drums are also equal, and excesses of these forces will be distributed between the draws of these drums as anti-tension during drawing.

- As an element that sets the equality of transmitted torques on the differential pairs of drums, a transfer case with a differential from a car transmission can be used.

Indeed, at the same time, the direct-flow principle is also fulfilled and the drawing mill with such a drive will turn out to be at least 4-fold.

- In addition, the traction drum can be made stepwise with differential coupling between the steps.

Indeed, in this case, the multiplicity of the drawing mill will increase by 1 with the addition of each step and can be brought to any desired. In this case, the direct-flow principle will also be fulfilled, since the connection between the steps is differential and the moments between the drums are distributed equally.

- The suspension elements of the car frame on the car transmission can be replaced with more rigid elements.

Indeed, at the same time, during the operation of the frame suspension on the elements of the drive of the drawing drums, the shock-absorbing effect of the automobile suspension will cause only inconvenience and will be unnecessary, since the working conditions of the drawing mill, unlike the operating conditions of the car, are stationary.

- As a car frame, a set of individual supports can be used.

Indeed, when the design of the drawing mill is not connected by the frame of the car, its connecting places for suspension of the automobile chassis and other important parameters of the frame - for example, a set of reinforced concrete ledges of the foundation will have rigidity and strength.

A multiple once-through drawing mill for calibrating workpieces is arranged as follows.

In the case when the direct-flow drawing mill for calibrating workpieces is 4-fold (Fig. 1), in its device (receiving and intermediate drawing tools 1 with its lubricating baths 2, receiving and intermediate drawing drums 3, bypass roller 4, finishing drawing tool 5 also with a soap box and a fine drawing drum 6, the initial billet (wire rod) 7 is filled, which between the 1st and 2nd dies is a conversion billet 8, and after the finishing dies it is a finished wire 9. The drum drive is a car transmission, including connected to the electric motor 10 gearbox 11, which is a gearbox, driveshaft 12, transfer case 13 with differential gear, reduction gearboxes 15, which are the main gears, differentials 16 and axle shafts 77, and to the axle via a hinge 18 (figure 2 ), which transmits only torque, a drawing drum is attached. The entire automobile transmission is fixed to the automobile frame 19 by means of, for example, welding seams 20, that is, more rigidly than by means of shock absorbing elements of a conventional car suspension. Through these welds, the technological forces (drag and counter-tension forces) applied to the drums through the support pipes 21 are transferred to the frame. Torque from the semiaxis is transmitted to the drum through the pipe 22 installed in the support pipe on the bearings 23, and the axles are thus unloaded and do not absorb technological loads. The gearbox has a gear shift lever 24. The bypass roller is mounted on the frame through the axis 25 with the possibility of its free rotation on this axis.

If the direct-flow drawing mill 2-fold (figure 2), the transmission of torques on the half-axis of the drums and the connection between the half-axes is also carried out by means of a differential mechanism 16.

For ease of operation of the mill, under various conditions of the room, the frame 19 can be installed obliquely so that the bypass roller 4 will be located horizontally; in addition, the frame 19 can be located vertically, and the axis of the drums 3, 6 can occupy, for example, a horizontal or inclined position.

A multiple once-through drawing mill for calibrating workpieces operates as follows.

An initial billet (wire rod) 7 is fed into the drawing mill (Fig. 1); Further, the workpiece is sent to the 1st drawing unit, consisting, for example, of a composite die 1 with a hydrodynamic supply of technological lubricant to the deformation zone, and a lubricant bath 2; then the workpiece falls on the receiving drawing drum 3; after 3-4 turns, sufficient to ensure the drawing force due to friction against the drum, the conversion blank 8 enters the 2nd intermediate drawing assembly, also consisting of a lubricating bath (soap box) 2 and a drawing tool 7 installed in the fiber holder; Further, the workpiece goes around a bypass roller 4, freely rotating on axis 25, whose diameter is equal to the gauge; then, the conversion blank 8 passes through the 3rd intermediate drawing tool 1 with a soap box 2 in the same way and goes around the 3rd intermediate drum 3, then the conversion blank 8 passes the final calibrating wire 5 with the soap box 2 and becomes a finished calibrated article 9 (wire) having exact diameter, high surface quality and mechanical properties of a given level. Next, the finished wire 9 can accumulate on the finishing drum 6 or sent to a winding machine (not shown). In this case, all the power necessary for drawing the wire is transmitted from the electric motor 10 through the car gearbox 11 (using the lever 24, the desired gear, depending on the required drawing speed, is set in advance) and the driveshaft 12 to the transfer case 13, which includes a differential a mechanism due to which the torques are distributed equally between the drive axles, consisting of the drive axles 17 of the receiving 3 drive and the final 6 drums (lower bridge), as well as the drive axle axis 17 3 month old reel (upper bridge). In this case, the axles 77 through the hinges 18 (Fig. 2) transmit only the torques to the drums 3, 6, which unloads the axles 17. The technological loads on the drums 3, 6 are transmitted to the frame 19, bypassing the axles 17 through the support tubes 22, bearings 23 and support pipes 21 and rigid welds 20.

Thus, it becomes possible to create, on your own or in a small enterprise, for example, a problem laboratory at a university, a multiple drawing mill, moreover, it is a direct-flow mill, that is, one that can provide the most technological conditions for the drawing process - drawing with a set and controlled anti-tension.

At the receiving and intermediate transitions, the anti-tension will provide, for example, using a dies with hydrodynamic supply of technological lubricant into the deformation zone by the gaps of the pressure section and with internal anti-tension between the crimping dies of the working section. This will provide compression close to the limit while maintaining the microrelief of the surface of the billet, which effectively captures and carries the lubricant into the deformation zone.

At a finishing transition, a direct-flow type drawing mill will ensure a sufficiently high surface finish of the finished wire, minimal strain hardening of the metal, and accurate shape and size of its cross section.

The mill is straight-through, and the working surface of the drum is only a fillet. Only 4-5 turns are wound on it, no more, and this saves metal on the manufacture of a drum and the high compactness of such a mill. At the same time, the drum fillet is located symmetrically to the thrust bearings 23, and the technological loads on them are reduced, since they are distributed equally.

Thus, the proposed invention in its entirety of design features based on advanced technologies will increase energy saving by a more efficient and economical drawing process.

In addition, the claimed scheme of multiple once-through drawing mill for calibration of long cylindrical workpieces will allow the customer to manufacture and use it in a small enterprise.

In addition, this will allow conducting research work in a small enterprise to study, improve and test new technologies and equipment for their implementation in conditions close to industrial ones.

Claims (3)

1. Multiple direct-flow drawing mill for calibrating workpieces, including a frame, support pipes mounted on it, mounted on nozzles in bearings of at least two traction drums driven by an engine with a reduction gear and gearbox and drawing tools in front of them, characterized in that the car’s frame was used as the frame, and the parts, components and mechanisms of the automobile transmission, which are interconnected, are used as the drive of the drums, while lowering the gearbox used the main transmission of the vehicle’s transmission, the 1st and 2nd semiaxes of which are the output shafts of the reduction gear, and the gearbox is made in the form of a gearbox for the vehicle’s gears, while the 1st traction drum is connected to the 1st semi-axis, and the 2- th traction drum - with the 2nd semi-axis by means of hinges, with the possibility of transmitting semi-axes of torque and ensuring equal torques on the shafts of the traction drums by means of the differential transmission mechanism of the car, and between the traction a bypass roller is installed with the possibility of free rotation, defining the path of the wire from the 1st traction drum to the drawing tool located in front of the 2nd traction drum, transmission elements are fixed on the frame by welded joints, and support tubes are installed on the support pipes to transfer technological loads from drums on the frame.           2. The drawing mill according to claim 1, characterized in that it contains several pairs of traction drums to ensure equal torques on each pair by means of a transfer case with a differential drive from an automobile transmission. 3. The drawing mill according to claim 1, characterized in that the traction drums are made stepwise with differential coupling between the steps.

Images