RU85377U1 - DEVICE FOR DISTRIBUTION OF THIN-WALLED CYLINDER RINGS - Google Patents

Abstract

A device for distributing thin-walled cylindrical rings containing a pusher, a punch and a support ring, characterized in that the punch is configured to simultaneously distribute two or more thin-walled rings, and its working surface is made along a curved S-shaped generatrix.

Description

The invention relates to the field of metal forming, in particular, to devices for distributing thin-walled cylindrical rings.

Known devices for producing a conical and curved shape at the ends of pipe billets by distributing a punch with an increase in the diameter of the initial billet: Romanovsky V.P. Handbook of cold stamping. L .: Engineering, 1979; Popov E.A. Fundamentals of the theory of sheet stamping. M: Engineering. 1977; Averkiev Yu.A., Averkiev A.Yu. Cold stamping technology. M .: Engineering, 1989.

The most common in practice are devices for distributing the ends of pipe blanks with a conical punch.

The disadvantages of the known devices are the distortion of the shape of the forming blanks due to plastic bending before contact with the conical surface of the punch and at the exit of the deformed part of the workpiece from the conical surface of the punch. (Popov EA, Fundamentals of the theory of sheet stamping. M: Mechanical Engineering. 1977, p. 259; Averkiev Yu.A., Averkiev A.Yu. Cold stamping technology. M: Mechanical Engineering, 1989, p. 211). These disadvantages do not allow to obtain cylindrical rings of larger diameter without distortion of shape when distributing cylindrical rings of smaller diameter with a conical punch.

The task to which the claimed utility model is directed is to ensure continuous contact with the surface of the deformable rings over the entire working surface of the punch, which allows to obtain cylindrical rings of larger diameter with a decrease in wall thickness by distributing rings of smaller diameter without distorting the cylindrical shape along the height of the ring.

The problem is solved by the fact that in the device for distributing thin-walled cylindrical rings containing a pusher, a punch and a support ring, the punch is configured to simultaneously distribute at least two thin-walled rings, and its working surface in cross section is made S-shaped .

The utility model is illustrated by the drawing, where Fig. 1 shows a device for distributing three cylindrical rings with initial dimensions d ₀ , h ₀ , H ₀ . On the left side of the figure rings are shown at the upper position of the pusher and punch. On the right side of the figure, rings are shown at the lower position of the pusher and punch.

The device for distributing cylindrical rings contains a pusher 1, a punch 2, configured to simultaneously distribute, in this case, three rings, and with a working surface made of a curved S-shaped, as well as a support ring 3 and deformable rings 4, 5, 6. The punch has a cylindrical guide part with a diameter d ₀ for centering along the axis of the initial cylindrical ring and a calibrating girdle with a diameter d for a deformed ring coming off the punch after distribution. The pusher 1 is centered on the axis of the punch 2 with a cylindrical groove and is separated from the punch to remove the ring after distribution.

The device operates as follows.

The first ring 4 with initial dimensions d ₀ , h ₀ , H _{0 is} installed on the support ring 3 along a centering groove. The punch 2 complete with the pusher 1 is installed in the ring 4 along the guide belt with a diameter of d ₀ . When the pusher 1 and the punch 2 are moved, the ring 4 is distributed and pushed to the middle of the punch curved profile. Then, a second ring 5 and a punch 2 with a pusher 1 are mounted on the support ring 3. During the second movement of the pusher and the punch, the ring 5 occupies the position of the ring 4, which is pushed along the upper part of the punch profile with the end exit over its calibrating girdle. Then, the third ring 6 and the punch 2 with the pusher 1 are installed on the support ring 3. When the pusher and the punch are moved, the ring 6 occupies the position of the ring 5, pushed into the position of the ring 4, which collides with the calibrating belt of the punch, taking the final dimensions d, h, H. Ring 4 is removed after distribution when the pusher 1 is separated from the punch 2.

The force P applied to the pusher 1 increases at the non-stationary stage of distribution of the first two rings. When distributing the third ring, the force P takes a constant value of the stationary stage of the deformation process. When distributing a cylindrical ring with initial dimensions d ₀ , h ₀ , H ₀ into a cylindrical ring with a large diameter d, the wall thickness h and the height of the ring H after distribution are determined by the formulas

The initial and final diameters of the cylindrical ring during distribution are limited by the ultimate plastic tensile strain of the free edge of the deformable ring.

The pressure p at the interface between the punch and the deformable ring depends on the profile of the punch and is determined by the formula

where h is the variable along the profile of the punch wall thickness of the ring; σ _θ and σ _φ are the circumferential and meridional stresses; R ₁ and R ₂ are the radii of curvature of the profile in the meridional and normal to the profile sections. At a positive pressure p over the entire profile, the continuous contact of the punch with the deformable ring is maintained, and when the ring is pushed along the entire length of the punch profile, the cylindrical shape of the deformed ring after distribution is not distorted. Since the voltage in the distribution σ _θ is positive and the voltage negative σ _φ, condition positivity pressures p becomes inequality

Violation of inequality (4), leading to the separation of the ring from the punch, is possible for small negative values of R ₁ and large values of R ₂ depending on the profile of the generatrix of the punch.

The process of distributing a cylindrical ring is modeled on a computer using the momentless theory of plastic deformation of a thin-walled shell of revolution, taking into account contact friction, hardening of the material, changes in wall thickness and normal anisotropy using the quadratic plasticity condition. In the program, stresses σ _θ and σ _{φ are} calculated along the generatrix of the middle surface of the deformable ring, and the fulfillment of inequality (4) is checked for a given profile of the punch, which ensures the cylindrical shape of the ring after distribution at the exit from the punch.

Claims (1)

A device for distributing thin-walled cylindrical rings containing a pusher, a punch and a support ring, characterized in that the punch is configured to simultaneously distribute two or more thin-walled rings, and its working surface is made along a curved S-shaped generatrix.