RU67486U1 - DEVICE FOR FORMING TEES - Google Patents

Abstract

The utility model relates to the field of metal forming, in particular, to devices for forming bends on the side surface of the pipe and can be used for the manufacture of thin-walled tees from a pipe billet.

The objective of the claimed utility model is to simplify the design of the stamp and reduce its size.

The problem is solved due to the fact that in the device for forming tees, which consists of two half-matrices with a connector plane perpendicular to their longitudinal axis, two axial punches, a rigid mandrel and an elastic forming element, according to the claimed utility model, the device is equipped with a lower base on which horizontally located half-matrix. On this basis, ledges are made to prevent the opening of half-matrices. Axial punches on their non-working reverse ends have inclined bevels. The upper half of the device is equipped with two wedges having a working surface consisting of vertical and inclined planes, while the angle of inclination of the inclined working plane of the wedges is equal to the angle of inclination of the bevels of the axial punches, the geometry of the wedges provides preliminary fixation of the upper part of the half-matrix with its vertical working plane before the deformation of the workpiece . The angle of inclination of the inclined plane of the wedges is determined from the condition:

α = arctan (H _resp / (0.8-0.9) D _tr );

where N _hole - the height of the formed branch on the tee

D _Tr - the outer diameter of the original pipe billet.

1 ill.

Description

The utility model relates to the field of metal forming, in particular, to devices for forming bends on the side surface of the pipe and can be used for the manufacture of thin-walled tees from a pipe billet.

A device is known for shaping tees using fluid pressure supplied to the inner cavity of a pipe billet (see Production of complex hollow parts. Edited by Prof. Bogoyavlensky KN - L.: Mechanical Engineering, Leningrad Branch, 1979, p. 55 , Fig. 20.).

The disadvantage of this device is that to implement the process of forming parts, you need expensive specialized equipment for hydraulic stamping, which also has limited use.

The closest in technical essence to the claimed device, which is taken as a prototype, is a device according to USSR author's certificate No. 1238824 "Device for shaping hollow products with processes." Published in Bul. No. 23, dated June 23, 86

The device consists of two half-matrices having a plane of a connector, a composite forming the inner punch, representing in cross section complementary segments to the circumference of the segments, one of which is made of metal, the other of elastic material, as well as two axial punches. When the elastic element is compressed by axial punches, internal pressure is created, with the help of which the formation of the outlet on the side surface of the pipe billet is carried out.

To implement this pattern of blank preforming, the device must have two buffers - upper and lower. The efforts of these buffers provide a tight docking along the plane of the half-matrix connector

in the process of forming the workpiece, and also provides the movement of the axial punches towards each other with the same speed relative to the matrix and the deformable workpiece.

The disadvantage of this device is the complexity of the device and its bulkiness. The presence of buffers increases the height of the device and requires the use of more powerful presses with a large closed press height.

The objective of the claimed utility model is to simplify the design of the stamp and reduce its size.

The problem is solved due to the fact that in the device for forming tees, consisting of two half-matrices, the connector plane of which is perpendicular to the longitudinal axis of the half-matrices, an internal composite forming punch, consisting of a rigid insert and a deformable elastic element, and two axial punches, according to the claimed utility model , the device is equipped with a lower base on which the half-matrixes are located horizontally. On this basis, ledges are made to prevent the opening of half-matrices during the stroke. Axial punches on their non-working reverse ends have inclined bevels. The upper half of the device is equipped with two wedges having a working surface consisting of vertical and inclined planes, while the angle of inclination of the working inclined plane of the wedges is equal to the angle of inclination of the bevels of the axial punches. The geometry of the wedges provides preliminary fixation of the upper part of the half-matrix with its vertical working plane before the process of deformation of the workpiece, and the angle of inclination of the inclined plane of the wedges is determined from the condition:

α = arctan ( _Hot / (0.8-0.9) D _tr );

where N _hole - the height of the formed branch on the tee

D _Tr - the outer diameter of the original pipe billet.

The inventive device during the working stroke of the press, as a result of the presence of a vertical plane on the wedges, allows you to keep the matrix from opening during the process of forming the tee from the tube billet. The presence of an inclined plane of the wedges allows you to convert the vertical movement of the upper part of the device into the horizontal movement of the axial punches, moving them towards each other at the same speed relative to the half-matrix, with the simultaneous deformation of the tube stock and the inner elastic element. There is no need for lower and upper buffers, the design of the device is simplified, its dimensions are reduced.

The device is illustrated in the drawing,

where in figure 1, to the right of the axis shows the device in its original position, before the deformation of the workpiece, and to the left of the axis of symmetry - the device at the end of the process of forming the tee.

The device consists of half matrices 1, the surface of the connector between which is perpendicular to their longitudinal axis. Axial punches 2 are located inside the semi-dies, in their working cavity. Step ledges are made on the cylindrical surface of the axial punches, with the help of which axial compression of the deformable workpiece is carried out. A composite punch, consisting of a rigid mandrel 3 and an elastic element 4, is placed in a pipe billet 5, with which it is placed in the working cavity of the half-matrix 1. Half-matrix 1 is located horizontally on the lower base of the device 6. On the plane of the half-matrix connector, in the cavity intended for shaping of the branch, a limiter 7 is installed, restricting the movement of the bottom of the molded branch. On non-working ends of the axial punches 2 made bevels. On the upper part of the device are two wedges 8, the working inclined planes of which are parallel to the inclined planes made on the non-working ends of the axial punches 2.

The device operates as follows.

The half-matrix 1 is installed horizontally on the lower base of the device 6. The ledges on the lower base 6 prevent the lower part of the half-matrix from opening during the deformation of the workpiece 5. A pipe workpiece 5 with a rigid inner mandrel 3 and located in it is installed in the working cavity of the half-matrix 1 elastic element 4.

Axial punches 2 are installed in the working cavities of the semi-dies, positioning them so that the inclined bevels of the inactive ends of the punches are parallel to the inclined planes of the wedges 8.

The working ends of the axial punches 2 have a stepped shape of the working surface. The protruding part of the working surface of the punches compresses the elastic element 4, while the ledge of the punch fixes the position of the rigid inner insert 3.

With the working stroke of the upper part of the device down, the wedges 8 are previously included in the windows of the lower base 6, relying on them with their supporting surface. At the same time, the vertical plane of the working surface of the wedge comes into contact with the upper part of the end surface of the half-matrices 1, fixing the upper part of these half-matrices from opening during deformation of the workpiece.

Practice shows that reliable fixing of the half-matrixes from opening is carried out at the moment when the vertical working plane of the wedges 8 is engaged with the vertical plane of the half-matrixes at a distance of 5-10% of the outer diameter of the half-matrixes. The lower edge of the wedges 8 should enter the windows of the lower base of the device by about the same amount.

Throughout the entire working stroke, the upper part of the half-matrix remains fixed from breaking using the vertical section of the working surface of the wedges 8.

Then, when the downward stroke of the upper part of the device, as a result of pressing the wedges 8 on the inclined bevels of the axial punches 2, the horizontal movement of these punches towards each other begins. Axial punches 2 begin to compress the elastic element 4 with simultaneous axial compression of the workpiece 5.

Horizontal movement of the axial punches is possible if the angle of inclination of the working inclined plane of the wedge "α" and the inclined plane of the punch 2 in contact with it is related to the coefficient of friction "f" on the contacting surfaces with a known relation:

tgα≥f

where: f is the coefficient of friction on the contact surface between the inclined surfaces of the wedges and axial punches.

The most rational value of the angle of inclination of the working surface of the wedges is in the range from 15 to 25 degrees (see Romanovsky V.P. Handbook of cold stamping - L .: Engineering, 1971, p. 562, Fig. 503).

When the angle of inclination is less than 15 °, the stroke of the device increases excessively. When the angle is more than 25 °, the magnitude of the force that must be applied to implement the process of deforming the workpiece increases.

As a result of horizontal movement of the axial punches and compression of the elastic element, the internal pressure of the elastic medium is created, under the influence of which the formation of the outlet is carried out.

The manufacture of the tap on the side surface of the tubular billet in the inventive device is carried out simultaneously as a result of two processes - molding of the tap by thinning and stretching the workpiece in the deformation zone and the additional metal volume entering the deformation zone as a result of axial compression of the workpiece. For axial compression of the workpiece 5, step ledges are made on the cylindrical surfaces of the axial punches 2, which force the workpiece

move to the deformation zone during horizontal movement of the punches.

The process of deformation of the workpiece is completed at the moment when the bottom of the molded branch completely abuts against the limiter 7. The height of the branch will correspond to the requirements of the drawing H _hole .

The original pipe billet is made with beveled ends.

As a result of this, the axial compression of the workpiece is uneven. The maximum compression of the workpiece is observed from the molded branch. Axial compression decreases to zero on the opposite generatrix of the workpiece. By changing the height of the bevels at the ends of the pipe billet and their length, as well as the volume of the elastic element 4, it becomes possible to regulate the process of forming the tee in order to manufacture parts with minimal metal consumption.

The rigid mandrel 3, which is included in the composite punch, plays a dual role. Firstly, it preserves the shape of the workpiece during the formation of the branch and prevents distortion of the shape of the workpiece and its loss of stability on the opposite side of the formed branch.

Secondly, by changing the cross-sectional area of this mandrel, it becomes possible to regulate the amount of displaced volume of the elastic element entering the deformation zone during the formation of the outlet and to regulate the thinning of the workpiece.

The most rational version of the technological process will be one in which thinning in the area of the formed branch will be minimal. In this case, the length of the forming blank from the molded branch in the process of forming the blank practically does not change. From this assumption, the required value of the working stroke of the axial punches 2 is approximately determined:

H _slave = H _resp;

where N _hole ^{- the} height of the molded branch according to the drawing of the finished part.

The process of deformation of the workpiece is completed at the moment when the molded tap with its bottom is adjacent to the limiter 7 located in the cavity on the surface of the connector of the two half-matrixes 1.

The vertical movement of the wedges corresponding to such a working movement of the punches is determined from the geometry:

= H _Cl H _holes / tgα.

Practice shows that since the limiter 7 is located on the surface of the half-matrix connector, above the bottom of the formed tap, the outer diameter of the half-matrix should be equal to:

D _nar = (1.8-2) D _tr .

where: D _{tr. is the} diameter of the initial tube billet equal to the inner diameter of the working cavity of the semi-matrices.

In the process of horizontal movement of the axial punches 2 from the action of the wedges 8 there should be no distortions, increased regional pressures and increased wear. Therefore, the length of the supporting cylindrical half-matrix, where the axial punches move, it is advisable to choose from the condition:

L _cyl = (1.5-2) D _tr ;

Then the length of the half-matrix can be determined from the following relation:

L _pm = L _det / 2 + L _cyl

where: L _det - the length of the pipe part of the finished tee according to the drawing. From the triangle ABC (see figure 1), you can determine the minimum value of the angle of inclination of the inclined working plane of the wedge α.

The minimum value of the aircraft leg is equal to the axial stroke

punch H _hole A leg from geometric constructions is equal to (0.8-0.9) D _tr .

Then the minimum value of the angle α is determined:

Knowing the angle of inclination of the inclined plane of the wedge and the amount by which it should enter the working window of the lower base - (5-10%) D _nar or (10-20%) D _tr , we can tentatively determine the minimum required thickness of the lower base at which the lower the edge of the wedge does not rest against the press table:

N _DOS = D _nar / 2 = D _Tr

The upper base of the device will have the same thickness. Knowing the height of the wedge and considering the moment when it is fully

sank into the window of the lower base, you can tentatively determine

closed device height:

As an example of calculation, we consider the determination of the approximate dimensions of a device for the manufacture of an equal bore tee made of X18H10T chromium-nickel steel. The outer diameter of the pipe billet is 53 mm and its thickness is 1.5 mm. The length of the finished tee is 160 mm, the height of the formed branch on the side surface of the pipe is 15 mm.

The angle of inclination of the inclined surface of the wedges is determined from the expression (1):

α = arctan ( _Hotv / (0.8-0.9) D _tr ) = arctan (l5 / 0.85 × 53) = 18 °.

From expression (2) we obtain that the closed height of the device is approximately equal to 205 - 210 mm.

The closed height of the device adopted for the prototype for the manufacture of the same tee is 380 mm.

Claims (1)

A device for forming hollow tees by forming an outlet on the side surface of the tube stock, consisting of two half-dies, the plane of the connector of which is perpendicular to the longitudinal axis of the half-dies, a composite punch consisting of an internal rigid insert and an elastic forming element, as well as two axial punches, characterized in that it is provided with a lower base on which the half-matrices are horizontally located, on this base there are ledges to prevent the opening of the half-matrices, axial poins they have inclined bevels on their non-working back ends, the upper half of the device is equipped with two wedges having a working surface consisting of vertical and inclined planes, while the angle of inclination of the inclined working plane of the wedges is equal to the angle of inclination of the bevels of the axial punches, the geometry of the wedges provides preliminary fixation of the upper part half-matrixes with its vertical working plane before the process of deformation of the workpiece, and the angle of inclination of the inclined plane of the wedges is determined from the condition: α = arctan (H _resp / (0.8-0.9) D _tr ), where N _hole - the height of the formed branch on the tee; D _Tr - the outer diameter of the original pipe billet.