CN220591442U - Horizontal steel pipe upsetting split type forming device - Google Patents
Horizontal steel pipe upsetting split type forming device Download PDFInfo
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- CN220591442U CN220591442U CN202321889568.4U CN202321889568U CN220591442U CN 220591442 U CN220591442 U CN 220591442U CN 202321889568 U CN202321889568 U CN 202321889568U CN 220591442 U CN220591442 U CN 220591442U
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- 229910000831 Steel Inorganic materials 0.000 title claims abstract description 82
- 239000010959 steel Substances 0.000 title claims abstract description 82
- 238000003825 pressing Methods 0.000 claims abstract description 36
- 238000000034 method Methods 0.000 claims abstract description 24
- 238000000465 moulding Methods 0.000 claims description 16
- 230000007704 transition Effects 0.000 claims description 8
- 238000009434 installation Methods 0.000 claims description 4
- 210000001503 joint Anatomy 0.000 claims description 3
- 238000005242 forging Methods 0.000 abstract description 13
- 238000004519 manufacturing process Methods 0.000 abstract description 9
- 239000000463 material Substances 0.000 abstract description 6
- 238000001192 hot extrusion Methods 0.000 abstract description 5
- 238000007514 turning Methods 0.000 abstract description 4
- 238000010438 heat treatment Methods 0.000 description 8
- 238000003754 machining Methods 0.000 description 2
- 239000011159 matrix material Substances 0.000 description 2
- 238000010791 quenching Methods 0.000 description 2
- 230000000171 quenching effect Effects 0.000 description 2
- 239000002918 waste heat Substances 0.000 description 2
- 229910000851 Alloy steel Inorganic materials 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000000052 comparative effect Effects 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 230000013011 mating Effects 0.000 description 1
- 239000002184 metal Substances 0.000 description 1
- 239000007769 metal material Substances 0.000 description 1
- 229910052755 nonmetal Inorganic materials 0.000 description 1
- 238000002360 preparation method Methods 0.000 description 1
- 239000002699 waste material Substances 0.000 description 1
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Abstract
The utility model provides a horizontal steel pipe upsetting split forming device, which comprises a lower die bottom plate structure and an upper die bottom plate structure, wherein die holder structures which are arranged in parallel are respectively and correspondingly arranged on the lower die bottom plate structure and the upper die bottom plate structure, a clamp die sleeve for clamping a steel pipe is arranged in one group of die holder structures, and a combined forming die structure for upsetting is fixed at the top end of the other group of die holder structures; the internal mold structure is matched with the combined forming mold structure. The split upsetting die is adopted, a hot extrusion forging mode is adopted, and a method of repeatedly pressing the steel pipe in a reverse direction is adopted, so that the blank is finally locally forged and pressed to a specific shape and then is subjected to turning, the problem of forging straightness is solved, the final straightness is reduced, the material processing amount and the processing period are reduced, and the manufacturing cost is reduced.
Description
Technical Field
The utility model belongs to the field of steel hot forging manufacturing devices, and particularly relates to a horizontal steel pipe upsetting split forming device, in particular to advanced preparation and processing forming technology of metal and non-metal materials.
Background
The middle cylinder is used as a part of the engineering machinery oil cylinder, and has the advantages of complex shape, large processing amount, long processing period, large material loss and high production cost in the traditional processing mode. The blank is locally forged to a specific shape by adopting a hot extrusion forging mode and then is lathed, so that the processing amount and the processing period of materials can be reduced. In the forging and pressing process of the steel pipe, the upper half clamp and the lower half clamp are fixed on forging and pressing equipment. When the inner die is pushed inwards to increase the wall thickness of the steel pipe, the upper half clamp is fixed by the hydraulic piston rod, and finally a small section of rebound occurs, so that the forged steel pipe is tilted upwards at a certain position. The test meter is placed on a lathe to test the straightness, and the test meter is found to jump to 5-8mm, so that the machining allowance of the test meter needs to be increased, and the manufacturing cost of phase change is increased. In order to solve the problem of forging straightness, the final straightness of the steel pipe is reduced by a method of repeatedly pressing the steel pipe in a reverse direction, so that the manufacturing cost is greatly reduced.
Disclosure of Invention
In order to solve the technical problems, the utility model provides a horizontal steel pipe upsetting split-type forming device, which adopts a split-type upsetting die and adopts a hot extrusion forging mode, and finally locally forges a blank to a specific shape by a method of reversely repeatedly pressing the steel pipe, and then carries out turning, thereby improving the problem of forging straightness, reducing the final straightness, reducing the processing amount and the processing period of materials and reducing the manufacturing cost.
In order to achieve the technical characteristics, the aim of the utility model is realized in the following way: a horizontal steel pipe upsetting split forming device comprises a lower die bottom plate structure and an upper die bottom plate structure, wherein die holder structures which are arranged in parallel are correspondingly arranged on the lower die bottom plate structure and the upper die bottom plate structure respectively, clamp die sleeves used for clamping steel pipes are arranged in one group of die holder structures, and a combined forming die structure used for upsetting is fixed at the top end of the other group of die holder structures;
the internal mold structure is matched with the combined forming mold structure.
In the forming process, the paired die holder structures on the lower die bottom plate structure and the upper die bottom plate structure are matched with each other in a positioning way through positioning blocks arranged on the side walls.
The lower die bottom plate structure comprises a lower die bottom plate, the top of the lower die bottom plate is provided with a mounting boss, a plurality of groups of lower die fixing grooves are symmetrically arranged on the two sides of the long side of the lower die bottom plate, a plurality of groups of first stepped holes are symmetrically arranged on the mounting boss, a first rectangular groove is symmetrically arranged at the bottom end of the lower die bottom plate, and a second rectangular groove is formed in the center of the top end of the mounting boss.
The upper die bottom plate structure comprises an upper die bottom plate, a plurality of groups of upper die fixing grooves are symmetrically arranged on two sides of the long edge of the upper die bottom plate, a plurality of groups of second stepped holes which are symmetrically arranged are symmetrically processed on the upper die bottom plate, and a third rectangular groove which is symmetrically arranged is processed on the top end of the upper die bottom plate.
The center part processing of die holder structure has arc positioning groove, and the top symmetry processing of arc positioning groove has the first ladder screw hole of multiunit, and the bottom center processing of die holder structure has the fourth rectangular channel, and the processing of the long limit outer wall middle part of die holder structure has the lateral wall recess, and the lateral wall recess is used for installing the locating piece, and processing has the side direction screw hole on the inside wall of lateral wall recess, and the bottom processing of die holder structure has the screw blind hole that is used for with lower mould bottom plate structure or go up mould bottom plate structure matched with.
The clamp die sleeve is of a semicircular arc sleeve structure, a deep groove structure for being meshed with the outer wall of the steel pipe is processed on the inner arc wall of the semicircular arc sleeve structure, and a clamp die sleeve positioning step is processed on the outer arc wall of the semicircular arc sleeve structure and matched with an arc positioning groove of the die holder structure.
The combined forming die structure comprises a die sleeve matched with the die holder structure, and a first die core and a second die core matched with the upsetting part of the steel pipe are installed in the die sleeve in a pressing mode through a pressing plate.
A first arc-shaped step for positioning the first mold core is processed on the inner arc-shaped wall of the mold sleeve, a first arc-shaped supporting step for being matched with the first mold core is arranged on the other side of the first arc-shaped step, a second arc-shaped step for being matched with the second mold core is arranged on the other side of the first arc-shaped supporting step, a second arc-shaped supporting step for being matched with the second mold core is arranged on the other side of the second arc-shaped step, a mold sleeve positioning step for being matched with a mold base structure is processed in the middle of the outer wall of the mold sleeve, and a pressing plate threaded hole for being matched with a pressing plate is processed at the top end of the mold sleeve;
the end of the first mold core is provided with a first mold core positioning step matched with the first arc-shaped step, the interior of the first mold core is provided with a first inner molding mold cavity, the tail end of the first inner molding mold cavity is provided with a transition step, and two sides of the top end of the first mold core are provided with first pressing plate mounting grooves matched with the pressing plates;
the end processing of second mold core has the second mold core location ladder that is used for with second arc ladder matched with, and the inside processing of second mold core has the second internal molding die cavity, and the one end and the transition ladder transition butt joint of second internal molding die cavity, and the top both sides processing of second mold core have the second clamp plate mounting groove that is used for with clamp plate matched with, and the second internal molding die cavity cooperatees with the size of steel pipe upsetting section.
The internal mold structure comprises an internal mold, the internal mold is fixedly connected with the top plate and the first flange through long bolts, the other end of the first flange is connected with the connecting rod through the second flange, and a third flange is arranged at the other end of the connecting rod.
A method for upsetting and forming a steel pipe by adopting a horizontal steel pipe upsetting split forming device comprises the following steps:
firstly, placing one end of a steel pipe to be upsetted into a high-frequency electric furnace for local heating;
secondly, placing the heated steel pipe to be upsetted in the clamp die sleeve and the combined forming die structure, and ensuring that a heating end is placed in a second die core of the combined forming die structure;
step three, pressing down the clamp die sleeve and the upper part of the combined forming die structure until the steel pipe to be upsetted is completely fixed;
pushing the inner die structure into an inner hole of an upsetting end of the steel pipe to be upsetted from the right end, and pushing a top disc of the inner die structure into a second inner molding die cavity of a second die core until the inner die structure cannot be pushed; at the moment, the upsetting end of the steel pipe to be upsetted gradually increases to the size of the second inner forming die cavity at the inner and outer diameters of the second inner forming die cavity, and the inner diameter is reduced to the inner die size;
step five, the internal mold is pulled out of the upsetting end, and the structural part of the bottom plate of the upper mold is lifted up to obtain a forged middle cylinder, but the straightness is poor at the moment, and reverse pressing is needed;
and step six, rotating the preliminarily formed steel pipe to be upset by 180 degrees, further enabling the steel pipe to be upset to turn up and down by 180 degrees in the die, pressing the steel pipe downwards through an upper hydraulic piston rod while the waste heat of a steel pipe heating section is still, repeatedly pressing and rotating for 3-5 times, and keeping time for 10-15 seconds each time.
The utility model has the following beneficial effects:
1. the split upsetting die is adopted, a hot extrusion forging mode is adopted, and a method of repeatedly pressing the steel pipe in a reverse direction is adopted, so that the blank is finally locally forged and pressed to a specific shape and then is subjected to turning, the problem of forging straightness is solved, the final straightness is reduced, the material processing amount and the processing period are reduced, and the manufacturing cost is reduced.
2. The positioning precision of the upper die and the lower die after pressing is guaranteed through the positioning blocks, and further the dimensional precision of the steel pipe to be upsetted in the follow-up upsetting process is guaranteed.
3. The lower die bottom plate structure can be used for fixedly mounting corresponding die holder structures, and the fixed mounting between the lower die bottom plate structure and the workbench is guaranteed.
The upper die bottom plate structure can be used for fixedly mounting the corresponding die holder structure, and the upper die bottom plate structure is connected with the upper hydraulic piston rod, so that the pressing force is provided, and the reliable pressing of the steel pipe to be upsetted is ensured.
4. The die holder structure can be used for fixedly mounting the clamp die sleeve and the combined forming die structure. The positioning precision of the clamp die sleeve and the combined forming die structure is guaranteed through the arc-shaped positioning grooves.
5. The clamp die sleeve can be used for reliably clamping the steel pipe to be upsetted, so that the follow-up upsetting writing process is facilitated, and the steel pipe to be upsetted is prevented from moving in the upsetting process. The clamping force is ensured through the deep groove structure.
6. The upsetting process of the upsetting end of the steel pipe to be upsetted is realized in the upsetting process through the combined forming die structure. And adopt multistage combination formula structure, for whole mould, the mould adopts split type design, can make full use of the high temperature and high pressure resistant and the high toughness's of outer lane part characteristic of inner circle part, not only can make the mould be convenient for process, can also increase mould life and product size precision.
7. The second mold core adopts heat-resistant steel, the heat treatment state is a quenching state, and the hardness of the matrix is higher, so that the high temperature resistance and the wear resistance of the mold core are ensured.
8. The internal mold structure can be used for being matched with the upsetting end of the steel pipe to be upsetted. And further forming of upsetting ends is realized.
9. The straightness of the steel pipe re-pressed by the method can be controlled within 3mm, and the machining allowance is greatly reduced, so that the manufacturing cost is reduced.
Drawings
The utility model is further described below with reference to the drawings and examples.
FIG. 1 is a three-dimensional view of the overall structure of the present utility model.
Fig. 2 is a front view of the bottom plate structure of the lower die of the present utility model.
FIG. 3 is a view of the bottom plate structure A-A of the lower die of FIG. 2 according to the present utility model
Fig. 4 is a three-dimensional view of the bottom plate structure of the lower die of the present utility model.
Fig. 5 is a front view of the top die bottom plate structure of the present utility model.
Fig. 6 is a view of the bottom plate structure B-B of the upper die of fig. 5 in accordance with the present utility model.
FIG. 7 is a three-dimensional view of the upper die bottom plate structure of the present utility model.
Fig. 8 is a front view of the die holder structure of the present utility model.
Fig. 9 is a view of the die holder structure C-C of fig. 8 in accordance with the present utility model.
Fig. 10 is a half cross-sectional view of the die holder structure of fig. 8 in accordance with the present utility model.
FIG. 11 is a three-dimensional view of a die holder structure according to the present utility model.
Fig. 12 is a front view of the clamp sleeve of the present utility model.
Fig. 13 is a side view of a clamp sleeve of the present utility model.
Fig. 14 (a) (b) is a comparison of pre-upset and post-upset of the present utility model.
Fig. 15 (a) (b) is a comparative view of the steel tube to be upset of the present utility model before and after upsetting.
FIG. 16 is a block diagram of a combined clamp sleeve and combined forming die structure of the present utility model.
Fig. 17 is a front view of the die sleeve of the present utility model.
Fig. 18 is a side view of a die sleeve of the present utility model.
Fig. 19 is a front view of a first mold core of the present utility model.
FIG. 20 is a side view of a first mold core of the present utility model.
FIG. 21 is a front view of a second mold core of the present utility model.
FIG. 22 is a side view of a second mold core of the present utility model.
In the figure: the die comprises a lower die bottom plate structure 1, an upper die bottom plate structure 2, a die holder structure 3, a positioning block 4, a clamp die sleeve 5, a combined forming die structure 6, a first die core 7, a pressing plate 8, a die sleeve 9, a second die core 10, an inner die 11, a top disc 12, a long bolt 13, a first flange 14, a second flange 15, a connecting rod 16, a third flange 17 and a steel pipe 18 to be upsetted;
a lower die bottom plate 101, a lower die fixing groove 102, a mounting boss 103, a first stepped hole 104, a first rectangular groove 105, a second rectangular groove 106;
an upper die bottom plate 201, an upper die fixing groove 202, a second stepped hole 203 and a third rectangular groove 204;
a first stepped threaded hole 301, an arc-shaped positioning groove 302, a side wall groove 303, a threaded blind hole 304, a fourth rectangular groove 305 and a lateral threaded hole 306;
deep groove structure 501, clamp die sleeve positioning step 502;
a first core positioning step 701, a first platen mounting groove 702, and a first inner molding cavity 703;
a first arcuate step 901, a first arcuate support step 902, a platen threaded hole 903, a die sleeve positioning step 904, a second arcuate step 905, and a second arcuate support step 906;
a second core positioning step 1001, a second platen mounting groove 1002, and a second inner molding cavity 1003.
Detailed Description
Embodiments of the present utility model will be further described with reference to the accompanying drawings.
Example 1:
referring to fig. 1-22, a horizontal steel pipe upsetting split forming device comprises a lower die bottom plate structure 1 and an upper die bottom plate structure 2, wherein die holder structures 3 which are arranged in parallel are correspondingly arranged on the lower die bottom plate structure 1 and the upper die bottom plate structure 2 respectively, a clamp die sleeve 5 used for clamping a steel pipe is arranged in one group of die holder structures 3, and a combined forming die structure 6 used for upsetting is fixed at the top end of the other group of die holder structures 3; and also includes an internal mold structure for mating with the modular forming mold structure 6. The split upsetting die is adopted, a hot extrusion forging mode is adopted, and a method of repeatedly pressing the steel pipe in a reverse direction is adopted, so that the blank is finally locally forged and pressed to a specific shape and then is subjected to turning, the problem of forging straightness is solved, the final straightness is reduced, the material processing amount and the processing period are reduced, and the manufacturing cost is reduced.
Further, in the molding process, the lower die bottom plate structure 1 and the upper die bottom plate structure 2 are matched with each other in a positioning way through positioning blocks 4 arranged on the side walls. The positioning accuracy of the upper die and the lower die after pressing is guaranteed through the positioning block 4, and further the dimensional accuracy of the steel tube 18 to be upsetted in the follow-up upsetting process is guaranteed.
Further, the lower die bottom plate structure 1 includes a lower die bottom plate 101, a mounting boss 103 is provided at the top of the lower die bottom plate 101, a plurality of groups of lower die fixing grooves 102 are symmetrically provided at two sides of a long side of the lower die bottom plate 101, a plurality of groups of first stepped holes 104 are symmetrically arranged on the mounting boss 103, a first rectangular groove 105 is symmetrically arranged at the bottom of the lower die bottom plate 101, and a second rectangular groove 106 is arranged at the center of the top of the mounting boss 103. The lower die bottom plate structure 1 can be used for fixedly mounting the corresponding die holder structure 3, and the fixed mounting between the lower die bottom plate structure 1 and a workbench is ensured.
Further, the upper die bottom plate structure 2 includes an upper die bottom plate 201, a plurality of groups of upper die fixing grooves 202 are symmetrically disposed on two sides of a long side of the upper die bottom plate 201, a plurality of groups of second stepped holes 203 are symmetrically disposed on the upper die bottom plate 201, and a third rectangular groove 204 is disposed on a top end of the upper die bottom plate 201. The upper die bottom plate structure 2 can be used for fixedly mounting the corresponding die holder structure 3, and the upper die bottom plate structure 2 is connected with an upper hydraulic piston rod, so that a pressing force is provided, and the steel tube 18 to be upsetted is reliably pressed.
Further, an arc positioning groove 302 is machined in the central part of the die holder structure 3, a plurality of groups of first stepped threaded holes 301 are symmetrically machined in the top end of the arc positioning groove 302, a fourth rectangular groove 305 is machined in the center of the bottom end of the die holder structure 3, a side wall groove 303 is machined in the middle part of the outer wall of the long side of the die holder structure 3, the side wall groove 303 is used for installing the positioning block 4, a lateral threaded hole 306 is machined in the inner wall of the side wall groove 303, and a threaded blind hole 304 matched with the lower die bottom plate structure 1 or the upper die bottom plate structure 2 is machined in the bottom end of the die holder structure 3. The die holder structure 3 can be used for fixedly mounting the clamp die sleeve 5 and the combined forming die structure 6. The positioning accuracy of the clamp die sleeve 5 and the combined forming die structure 6 is ensured by the arc-shaped positioning groove 302. The fourth rectangular groove 305 ensures reliable positioning and installation of the subsequent die holder structure 3 with the lower die bottom plate structure 1 and the upper die bottom plate structure 2.
Further, the clamp die sleeve 5 adopts a semicircular arc sleeve structure, a deep groove structure 501 for being meshed with the outer wall of the steel pipe is processed on the inner arc wall of the semicircular arc sleeve structure, a clamp die sleeve positioning step 502 is processed on the outer arc wall of the semicircular arc sleeve structure, and the clamp die sleeve positioning step 502 is matched with the arc positioning groove 302 of the die holder structure 3. The clamp die sleeve 5 can be used for reliably clamping the steel pipe 18 to be upsetted, so that the follow-up upsetting writing process is facilitated, and the steel pipe is prevented from moving in the upsetting process. The clamping force is ensured by the deep groove structure 501.
Further, the combined forming die structure 6 comprises a die sleeve 9 matched with the die holder structure 3, and a first die core 7 and a second die core 10 matched with the steel pipe upsetting part are installed inside the die sleeve 9 in a pressing mode through a pressing plate 8. The upsetting process of the upsetting end of the steel pipe 18 to be upsetted is realized in the upsetting process by the combined forming die structure 6. And adopt multistage combination formula structure, for whole mould, the mould adopts split type design, can make full use of the high temperature and high pressure resistant and the high toughness's of outer lane part characteristic of inner circle part, not only can make the mould be convenient for process, can also increase mould life and product size precision. Meanwhile, as the two parts of the split die are thinner than the integral wall thickness, the shorter length is convenient for die sleeve processing by adopting the steel pipe tailing, and waste utilization is realized.
The first mold core 7 and the second mold core 10 are different in diameter, and further adopt a two-section structure.
Further, a first arc-shaped step 901 for positioning the first mold core 7 is processed on the inner arc-shaped wall of the mold sleeve 9, a first arc-shaped supporting step 902 for being matched with the first mold core 7 is arranged on the other side of the first arc-shaped step 901, a second arc-shaped step 905 for being matched with the second mold core 10 is arranged on the other side of the first arc-shaped supporting step 902, a second arc-shaped supporting step 906 for being matched with the second mold core 10 is arranged on the other side of the second arc-shaped step 905, a mold sleeve positioning step 904 for being matched with the mold base structure 3 is processed on the middle part of the outer wall of the mold sleeve 9, and a pressing plate threaded hole 903 for being matched with the pressing plate 8 is processed on the top end of the mold sleeve 9. The overall appearance structure of the die sleeve 9 is a cylinder with steps, the outer circle is provided with an assembly step, and the inner circle is matched with the outer circles of the first die core 7 and the second die core 10.
Further, a first mold core positioning step 701 for matching with the first arc-shaped step 901 is machined at the end of the first mold core 7, a first inner molding cavity 703 is machined in the first mold core 7, a transition step 704 is arranged at the tail end of the first inner molding cavity 703, and first press plate mounting grooves 702 for matching with the press plates 8 are machined at two sides of the top end of the first mold core 7. Alloy steel is adopted by matching the first mold core 7 with the steel pipe 18 to be upset close to the upsetting end.
Further, a second mold core positioning step 1001 for matching with a second arc-shaped step 905 is machined at the end of the second mold core 10, a second inner forming cavity 1003 is machined in the second mold core 10, one end of the second inner forming cavity 1003 is in transitional butt joint with the transition step 704, second press plate mounting grooves 1002 for matching with the press plates 8 are machined at two sides of the top end of the second mold core 10, and the second inner forming cavity 1003 is matched with the size of the upsetting section of the steel pipe. The second mold core 10 adopts heat-resistant steel, the heat treatment state is a quenching state, and the hardness of the matrix is high, so that the high temperature resistance and the wear resistance of the mold core are ensured.
Further, the internal mold structure comprises an internal mold 11, the internal mold 11 is fixedly connected with the top plate 12 and the first flange 14 through long bolts 13, the other end of the first flange 14 is connected with a connecting rod 16 through a second flange 15, and a third flange 17 is arranged at the other end of the connecting rod 16. Can be used in conjunction with the upset end of the steel pipe 18 to be upset by the internal mold structure described above. And further forming of upsetting ends is realized.
Example 2:
a method for upsetting and forming a steel pipe by adopting a horizontal steel pipe upsetting split forming device comprises the following steps:
firstly, placing one end of a steel pipe 18 to be upset in a high-frequency electric furnace for local heating;
secondly, placing the heated steel pipe 18 to be upsetted inside the clamp die sleeve 5 and the combined forming die structure 6, and ensuring that a heating end is placed inside the second die core 10 of the combined forming die structure 6;
step three, pressing down the clamp die sleeve 5 and the upper part of the combined forming die structure 6 until the steel pipe 18 to be upsetted is completely fixed;
pushing the inner die structure into an inner hole of an upsetting end of the steel pipe 18 to be upsetted from the right end, and pushing the top disc 12 of the inner die structure into the second inner forming die 1003 of the second die core 10 until pushing cannot be performed; at this time, the upsetting end of the steel pipe 18 to be upset gradually increases to the size of the second inner forming cavity 1003 in the inner and outer diameters of the second inner forming cavity 1003, and the inner diameter is reduced to the size of the inner die 11;
step five, the inner die is pulled out of the upsetting end, and the part of the bottom plate structure 2 of the upper die is lifted up to obtain a forged middle cylinder, but the straightness is poor at the moment, and reverse pressing is needed;
step six, the preliminarily formed steel pipe 18 to be upset is rotated 180 degrees, the steel pipe 18 to be upset is turned up and down by 180 degrees in the die, the steel pipe is pressed down by an upper hydraulic piston rod while the waste heat of a steel pipe heating section is still, the steel pipe is repeatedly pressed and rotated for 3-5 times, and the pressing residence time is 10-15 seconds each time.
Claims (10)
1. A horizontal steel pipe upsetting split type forming device is characterized in that: the die comprises a lower die bottom plate structure (1) and an upper die bottom plate structure (2), wherein die holder structures (3) which are arranged in parallel are correspondingly arranged on the lower die bottom plate structure (1) and the upper die bottom plate structure (2) respectively, a clamp die sleeve (5) for clamping a steel pipe is arranged in one group of die holder structures (3), and a combined forming die structure (6) for upsetting forming is fixed at the top end of the other group of die holder structures (3);
the mold structure is matched with the combined forming mold structure (6).
2. The horizontal steel pipe upsetting split forming device as recited in claim 1, wherein: in the forming process, the lower die bottom plate structure (1) and the upper die bottom plate structure (2) are matched with each other in a positioning way through positioning blocks (4) arranged on the side walls, wherein the paired die holder structures (3) are arranged on the upper die bottom plate structure (2).
3. A horizontal steel tube upsetting split forming device as recited in claim 2, wherein: the lower die bottom plate structure (1) comprises a lower die bottom plate (101), wherein an installation boss (103) is arranged at the top of the lower die bottom plate (101), a plurality of groups of lower die fixing grooves (102) are symmetrically arranged on two sides of the long side of the lower die bottom plate (101), a plurality of groups of first stepped holes (104) are symmetrically arranged on the installation boss (103) in a processing mode, a first rectangular groove (105) is symmetrically arranged at the bottom end of the lower die bottom plate (101), and a second rectangular groove (106) is formed in the center of the top end of the installation boss (103).
4. A horizontal steel tube upsetting split forming device as recited in claim 2, wherein: the upper die bottom plate structure (2) comprises an upper die bottom plate (201), a plurality of groups of upper die fixing grooves (202) are symmetrically arranged on two sides of the long side of the upper die bottom plate (201), a plurality of groups of second stepped holes (203) which are symmetrically arranged are symmetrically machined on the upper die bottom plate (201), and a third rectangular groove (204) which is symmetrically arranged is machined on the top end of the upper die bottom plate (201).
5. A horizontal steel tube upsetting split forming device as recited in claim 2, wherein: the novel die holder is characterized in that an arc-shaped positioning groove (302) is formed in the central part of the die holder structure (3), a plurality of groups of first stepped threaded holes (301) are symmetrically formed in the top end of the arc-shaped positioning groove (302), a fourth rectangular groove (305) is formed in the center of the bottom end of the die holder structure (3), a side wall groove (303) is formed in the middle part of the outer wall of the long side of the die holder structure (3), a positioning block (4) is arranged in the side wall groove (303), a lateral threaded hole (306) is formed in the inner wall of the side wall groove (303), and a threaded blind hole (304) matched with the lower die bottom plate structure (1) or the upper die bottom plate structure (2) is formed in the bottom end of the die holder structure (3).
6. A horizontal steel tube upsetting split forming device as recited in claim 2, wherein: the clamp die sleeve (5) adopts a semicircular arc sleeve structure, a deep groove structure (501) for being meshed with the outer wall of the steel pipe is processed on the inner arc wall of the semicircular arc sleeve structure, a clamp die sleeve positioning step (502) is processed on the outer arc wall of the semicircular arc sleeve structure, and the clamp die sleeve positioning step (502) is matched with the arc positioning groove (302) of the die holder structure (3).
7. A horizontal steel tube upsetting split forming device as recited in claim 2, wherein: the combined forming die structure (6) comprises a die sleeve (9) matched with the die holder structure (3), and a first die core (7) and a second die core (10) matched with the steel pipe upsetting part are installed in the die sleeve (9) in a pressing mode through a pressing plate (8).
8. The horizontal steel tube upsetting split forming device as recited in claim 7, wherein: the die sleeve is characterized in that a first arc-shaped step (901) for positioning a first die core (7) is machined on the inner arc-shaped wall of the die sleeve (9), a first arc-shaped supporting step (902) for being matched with the first die core (7) is arranged on the other side of the first arc-shaped step (901), a second arc-shaped step (905) for being matched with a second die core (10) is arranged on the other side of the first arc-shaped supporting step (902), a second arc-shaped supporting step (906) for being matched with the second die core (10) is arranged on the other side of the second arc-shaped step (905), a die sleeve positioning step (904) for being matched with a die holder structure (3) is machined in the middle of the outer wall of the die sleeve (9), and a pressing plate threaded hole (903) for being matched with a pressing plate (8) is machined on the top end of the die sleeve (9).
9. The horizontal steel tube upsetting split forming device as recited in claim 7, wherein: the end of the first mold core (7) is provided with a first mold core positioning step (701) which is matched with a first arc-shaped step (901), the interior of the first mold core (7) is provided with a first inner molding mold cavity (703), the tail end of the first inner molding mold cavity (703) is provided with a transition step (704), and both sides of the top end of the first mold core (7) are provided with first pressing plate mounting grooves (702) which are matched with the pressing plates (8);
the end processing of second mold core (10) has second mold core location ladder (1001) that are used for with second arc ladder (905) matched with, and the inside processing of second mold core (10) has second internal molding die cavity (1003), and the one end and the transition ladder (704) transition butt joint of second internal molding die cavity (1003), and the top both sides processing of second mold core (10) have second clamp plate mounting groove (1002) that are used for with clamp plate (8) matched with, and second internal molding die cavity (1003) cooperate with the size of steel pipe upsetting section.
10. A horizontal steel tube upsetting split forming device as recited in claim 1, wherein: the internal mold structure comprises an internal mold (11), the internal mold (11) is fixedly connected with a top plate (12) and a first flange (14) through a long bolt (13), the other end of the first flange (14) is connected with a connecting rod (16) through a second flange (15), and a third flange (17) is arranged at the other end of the connecting rod (16).
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202321889568.4U CN220591442U (en) | 2023-07-18 | 2023-07-18 | Horizontal steel pipe upsetting split type forming device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202321889568.4U CN220591442U (en) | 2023-07-18 | 2023-07-18 | Horizontal steel pipe upsetting split type forming device |
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| Publication Number | Publication Date |
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| CN220591442U true CN220591442U (en) | 2024-03-15 |
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| CN202321889568.4U Active CN220591442U (en) | 2023-07-18 | 2023-07-18 | Horizontal steel pipe upsetting split type forming device |
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| Country | Link |
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| CN (1) | CN220591442U (en) |
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