SU741970A1 - Tube helical-rolling method - Google Patents

Description

one

The invention relates to the manufacture of pipes and can be used in pipe rolling shops of metallurgical plants. Mainly for the production of thin-walled pipes of large 5 diameter.

The pipe expander is of a kosovalkov type, containing a two-roll working cage with a drive and mandrels with rods. The bed is stationary, About two rolls are located at an angle to the axis of rolling. The mandrel and the rod are installed moving and rotate around its axis together with the pipe 1.15.

The disadvantages of this pipe expander are the unstable gripping of the billet-pipe by rolls, since before the task of the pipe to the mill, the mandrel with the rod is rotated, reducing at the same time the number of turns of the rolls to the minimum value; large inertial masses of the mandrel and rod, which violate the conditions of rotation, as a result of which the pipe often wedges in the rolls; 25 eliminating the possibility of increasing the expansion ratio in one pass without replacing the mandrel. These drawbacks reduce the performance and quality of the pipes (increased 30

cha raznesennost, helix, ovality, etc.).

Most closely related to the technical essence of the invention is a helical rolling mill for pipes containing a frame, sets of rolls, their drive, a rod carrying several mandrels, each of which corresponds to one set of rolls.

A feature of this mill is that in one pass it is intended to produce pipes with an increased expansion coefficient on a stepped mandrel, while the mandrel with the rods and the pipe rotate around their axes 23.

The drawbacks of the mill are the unreliability of gripping the billet-tube and wedging the tube in the rolls. A change in the roll diameters of the rolls during the deformation process causes a difference in the rotational speeds of the tube and rolls, which leads to slippage and, consequently, the appearance of twisting and heightened screw-shape of the tube. In addition, irregularities in the form of roughness appear on the outer surface of the pipe due to the inconsistency of the volume of metal passing per unit time in the deformation zones.

The speed of rotation of the rolls depends on the stiffness of the rolled pipe. Installing the steps of the mandrels on each movable telescopic rod and adjusting them relative to the respective sets of rolls installed in the frame, greatly complicate the design of the equipment

The expansion and exit sides of the pipe expander both limit the range of pipe production in thickness and diameters, and also make it difficult to reliably ensure the supply of lubrication and cooling to the mandrels and rods during the rolling-expansion process. Moreover, the design of such a mill-expander and the process at. Increasing the continuous roll sets in the frame is even more complicated. These drawbacks do not allow to increase productivity, increase the total expansion coefficient in a single pass, and also limit the production of pipes with a thin wall.

The purpose of the invention is to increase productivity, save metal by producing thinner pipes and reducing scrap rates, as well as increasing the total expansion coefficient in a single pass.

The goal is achieved by the fact that a mill for helical rolling of tubes containing a frame, sets of rolls, their drive, a rod carrying several mandrels, each of which corresponds to one set of rolls, is equipped with a drive for reciprocally moving the frame along the rod and collars that have a rotational drive relative to the frame in which are located in a circle rolls sets, and the mandrel mounted on the rod can be rotated relative to each other and the rod. Between the cages placed inductors. The rolls of one set are kinematically connected and their drive is made common. With an individual drive of the rolls, the mill is equipped with cassettes with a mechanism for turning it in a cage.

The expansion of the pipe is carried out without rotating it. The pipe has only axial movement, so it is possible to increase the speed of rotation of the rolls, eliminate the operation of unwinding the pipe before its task into rolls or reduce the speed of the rolls before seizing. The conditions of gripping the pipe by rolls due to the absence of the need to unwind it and the mandrel with rollers are more favorable, which reduces the reject rate during rolling. Since the tube does not rotate during rolling, it is possible to place a tensioning device at the outlet of the mill, which creates forward tension and provides more

thin-walled pipes. In addition, the use of a multi-roll system allows rolling with a small single roll reduction per roll, but with a large total reduction per roll turn, i.e. pipe wall thickness Zools down more intensively.

It is possible to increase the total expansion ratio of the pipe in one pass by treating the pipe simultaneously in several sets of rolls, i.e. carry on the continuous process of expanding the pipe to a predetermined diameter. Since the tube and, therefore, the mandrel and the rod do not rotate during expansion, the bed with the roll set is mounted on the guides with the possibility of reciprocating movement along the axis of the rod, for example, from a hydraulic drive, and the movement of the bed movement is electrically connected through the block diagram. control systems for moving the bed with a pipe tension sensor.

The rotational speed of the rolls and the yoke and the position of the bed with the roll set are regulated only with respect to non-rotating tubes, mandrels and rods, therefore installing additional roll sets to expand the tube to a larger diameter, without disrupting the work of the existing roll sets, contributes to an increase in the total expansion coefficient and ensures continuity of the process. A more stable operation is ensured by the placement of rolls of indudstor between the clips for the heating of the pipe.

Figure 1 shows the mill with a common drive of the rolls, a longitudinal section; figure 2 - section aa in figure 1; on fig.Z - mill with an individual drive of the rolls, a longitudinal section; figure 4 - section bB in fig.Z on fig.Z - section bb In figure 4.

Claims (2)

The helical rolling mill tube includes a frame 1, its drive reciprocating movement, for example from a hydraulic cylinder (not shown) along the guides 2, the casing 3 with the rollers 4, the drive rotation of the cage relative to the bed from the shaft 5 through gear 6, the wheel 7 mounted on the holder, the drive of rotation of the rolls, either individual 8 (Fig. 3) or common (Fig. 1) from the shaft 9, on which gear 10 is fixed, meshes with the wheel 11 through a fixed wheel 12, gear 13 mounted on roll axis, inductors 14, located ezhdu collars with set valks1mi preheating the pipe, the rod 15 carrying several mandrels 16, mounted in grooves shank rod rotatably about the rod. Sensors 17 are placed in the groove between the rod and the shank of the mandrel. There is a block diagram 18 of the system for controlling the rotational speeds of the cage and rolls. For individual drive of the rolls, the rolls are installed in cages 19 (FIG. 3) placed in the radial bores of the cage so as to rotate around the axle 20, for example, using a screw 21 and a wheel 22. To monitor the condition of the outer surface of the pipe, tension sensors 23 and a block diagram 24 of the bed motion control system are installed at the exit of each set of rolls. The camp works as follows. The billet-tube, heated to the rolling temperature, is fed to the mill and is set in the first set of rolls 4, rotating together with the sleeve 3, is pressed between the mandrel 16 and the rolls forcibly rotating around the tube and its axes. If the speed of the points of the rolling diameters of the rolls that are in contact with the pipe at a given time is not zero, then the pipe and mandrel are rotated relative to the fixed rod. The shank of the mandrel acts on the sensor 17 associated with the block diagram 18 of the system of controlling the rotational speeds of the cage and work rolls, on a signal which changes the ratio of the rotational speeds of the cage and work rolls, and thereby returns the pipe and the mandrel to its original position, eliminating the occurrence of pipe twisting. When the tube leaves the rolls, it enters the zone of action of the sensor 23 associated with the block diagram 24 of the bed motion control system, and when defects appear on the outer surface of the tube in the form of tuberosity, a signal is received to change the reduction (by moving the bed along the mandrel bar For example, from hydraulic drive). This kinematics of the rolling-expansion process of the pipes occurs both in a separate set and during the rolling of a pipe at the same time in all sets of rolls. After the exit of the rear end of the pipe, the next billet pipe is set, the finished pipe is cleaned on the output side of the mill, i.e. the process is not interrupted. During rolling-expansion of the pipe through the rod, a process lubricant is continuously supplied to improve the quality of the inner surface of the pipe and facilitates the passage of the pipe. In addition, when rolling tubes of a certain range and steel grades, devices for heating pipes, such as inductors, are installed between the rolls of some assortment and steel grades. The proposed structural design of the mill allows to increase productivity, increase rolling speed, reduce the time for auxiliary operations and reduce scrap, besides, it provides pipes of better quality and metal savings. Claim 1. A helical rolling mill containing a frame, roll sets, their drive, a rod carrying several mandrels, each of which corresponds to one set of rolls, characterized in that, in order to increase productivity by ensuring the production of thin-walled tubes, it is equipped with a drive reciprocating movement of the bed along the rod and the sleeves having a rotational drive relative to the bed in which the rolls of sets are arranged in a circle, and the mandrels are mounted on the rod with possibly Tew rotation relative to each other and the rod. 2. Stan POP.1, characterized in that, in order to increase the expansion coefficient of the pipes, it is provided with inductors placed between the yokes. 3. Stan POP.1, characterized in that it is provided for each roll with a cassette with a reversing mechanism in the cage, wherein the drive of the rolls is drilled individually. 4. Stan POP.1, characterized in that the rolls of one set are kinematically connected and their drive is made common. Sources of information taken into account when examining 1. Production of pipes in the AI.Chermetinformation, 1974. 2. The US patent is 2,528,651, class 72-97, 1950. 3 1 1 1 / / I J b / // B (& IG / -A: vL but ( 2, gz Fa g. A 5 And / 5 / tg l I V 6 s Step.E r as i e-fl Phage. five