RU2101109C1 - Drawing die - Google Patents

Abstract

FIELD: plastic metal working, namely production of tubes and shapes. SUBSTANCE: drawing die includes body, hard-alloy inserts pressed-in to said body and one-piece sleeve. Said body is made of two yokes mutually opposite pressed one to another. Said hard-alloy inserts are in the form of sectors. One-piece sleeve is made of material with less hardness than that of hard-alloy inserts. Drawing hole of tool has reducing portion whose length is equal to width of said sleeve and squeezing portion. Members of drawing die made of different-hardness materials are arranged according to differential distribution of specific pressure of tubular blank upon tool at drawing process. EFFECT: enhanced wearability of drawing die due to lowered volume of hard-alloy inserts, decreased consumption of hard alloy material. 2 dwg

Description

 The invention relates to the processing of metals by pressure and can be used in the manufacture of pipes and profiles.

 Known drawer containing a housing with grooves in which carbide inserts are installed (prototype). The surfaces of the liners and the housing, facing the axis of the die, form a drawing channel, consisting of the input, crimp, gauge and output sections. Carbide inserts are in the form of plates, the width of which is less than the diameter of the calibrating section of the drawing channel, and the length corresponds to the length of the housing. The body is made of a material of lower hardness than the plate.

 This drawing is intended for the manufacture of wire through a rotating fiber.

 The manufacture of pipes from alloys that are prone to sticking, for example, titanium, by drawing, requires the use of a non-rotating die. However, when using the known die, rapid uneven wear of the die channel will occur, which eliminates the production of pipes of circular cross section.

 The aim of the invention is to increase the wear resistance of the die by using high-quality carbide inserts by reducing the volume of the liner, as well as reducing the consumption of carbide tools by placing component elements of the die made of a material of different density (hardness), respectively, the differential distribution of the specific pressure of the tube billet on the tool her through the drag.

 The goal is achieved in that the die comprises a housing with carbide inserts installed therein, forming a crimp portion of the drawing channel. The hardness of the liner material exceeds the hardness of the body material. Unlike the prototype, in the proposed die, the casing is made of two cages pressed against one another, carbide inserts are made in the form of sectors and pressed into the inner cage, and the drawing channel has a preceding crimping reducing section made in the form of a monolithic sleeve. The hardness of the material of the monolithic sleeve is less than the hardness of the material of the liners. The length of the reducing section of the drawing channel is equal to the width of the monolithic sleeve.

 Due to the presence of these signs, during the process of drawing, the tube billet undergoes different deformation stages in different components of the die: at the beginning of the drawing, the tube billet is deposited without compression along the wall in the reducing section formed by the monolithic sleeve, then it is crimped along the wall in the crimping section formed by carbide sectors.

 The monolithic sleeve is less loaded, since the specific pressure during reduction is an order of magnitude lower than when compressing along the wall. Therefore, even made of a material of lower hardness, it has high wear resistance. Carbide sectors perceive very large specific pressures. Due to the fact that the sectors made by the powder metallurgy method have a small mass and therefore are qualitatively pressed and have a high density, they have high wear resistance at high loads.

 A housing made of two holders with thickened ends closes the internal elements of the die and provides a stable size of the channel of the die, i.e. allows you to get pipes with constant sizes.

 The width of the monolithic sleeve, as well as the size and number of carbide sectors are determined for each route, depending on the size of the pipe billet and finished pipe and are the "know-how" of the invention.

 Comparison of the proposed die with the known shows compliance with the inventive criterion of novelty.

 The proposed set of essential features, considered relative to the current level of technology, shows compliance with the criterion of inventive step.

 In FIG. 1 shows a drawing device, a view from the output end and a section AA of FIG. 2; figure 2 axial section of the die.

 The die contains a housing consisting of an outer cage 1, pressed onto the inner casing 2. Carbide sectors 4 and a monolithic sleeve 5 are pressed into the inner casing 2. The casing clips and the monolithic sleeve are made of tool steel or high-strength heat-conducting alloys, the hardness of which is less than hardness (density ) carbide liners.

 The clips 1 and 2 of the body have thickened ends 6 and 7, respectively.

The axial holes of the monolithic sleeve 5 and section 3 formed by carbide sectors form a drawing channel consisting of an input reducing section, the length of which is equal to the width L _{1 of the} sleeve 5, and a crimping section, the length of which is equal to the width L _{2 of the} sector 4.

 Woloka works as follows.

 The tube preform 8 is inserted into the die by the front chained end forming the gripper 9 so that the gripper extends beyond the die. Then the mandrel 10 is introduced. The gripper moves along the axis, and with this begins the drawing process, which ends when the entire workpiece 8 passes through the entire draw, forming a pipe 11.

In the process of drawing, the workpiece 8 in the reducing section L _{1 of the} drawing channel formed by the monolithic sleeve 5 is deposited in diameter without crimping along the wall, and then in the crimping section L _{2 of the} channel formed by carbide sectors 4, is crimped along the wall.

 The proposed die can be used for a matrix when pressing hard-to-deform materials, such as stainless steels, alloys of titanium, zirconium, etc.

 The above confirms the conformity of the proposed technical solution to the inventive criterion of industrial applicability.

Claims (1)

 A wire containing a housing with carbide inserts installed in it, the hardness of the material exceeding the hardness of the housing material, forming a crimp section of the drawing channel, characterized in that the housing is made in the form of two clips pressed against one another, carbide inserts are made in the form of sectors and pressed into the inner sleeve, the drawing channel has a preceding crimp reducing section made in the form of a monolithic sleeve of material of lower hardness than the material ial liners, while the length of the reducing section is equal to the width of the monolithic sleeve.

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