CN116197259A - Hot extrusion drawing forming device and method for preparing variable-section hollow pipe - Google Patents

Abstract

The invention discloses a hot extrusion and drawing forming device for preparing a variable-section hollow pipe, which comprises a forming mechanism, a clamping mechanism and an extrusion mechanism, wherein a blank cavity is formed in the forming mechanism, a forming hole is formed in one side of the blank cavity, the forming cavity is formed in one side of the clamping mechanism, the clamping mechanism moves along the axial direction, the extrusion mechanism is provided with an extrusion cylinder and a perforating mandrel, the extrusion cylinder is used for extruding a blank, and the perforating mandrel is used for forming the inner diameter of the hollow pipe; the method is also disclosed, the forming cavity is propped against and communicated with the forming hole, the blank is placed, the perforating core moves towards the direction of the blank cavity, the blank enters the clamping mechanism to prop against the thimble, the extrusion cylinder is driven to extrude the blank, and the clamping mechanism is separated from the forming mechanism, so that the hollow tube is processed. The invention provides a hot extrusion forming device and a hot extrusion forming method for preparing a variable-section hollow pipe, which are suitable for processing the variable-section hollow pipe with a large depth-to-diameter ratio and ensure coaxiality of different sections.

Description

Hot extrusion drawing forming device and method for preparing variable-section hollow pipe

Technical Field

The invention relates to the field of pipe processing, in particular to a hot extrusion and drawing forming device and a hot extrusion and drawing forming method for preparing a variable-section hollow pipe.

Background

The variable-section hollow thin-wall slender pipe shaft part is widely applied to transmission systems in the fields of aerospace, high-end equipment and the like, and plays a key core role in power transmission under the conditions of high temperature, high rotating speed and high load. But because of the structural characteristics of large depth-to-diameter ratio, thin wall and variable cross section, the high-precision and high-performance manufacturing of the parts becomes a technical problem puzzling the industry. The traditional manufacturing process of the parts is deep hole drilling and heat treatment, but the problems of extremely high rejection rate of the parts in the deep hole drilling process, low material utilization rate, long production period and the like are caused by the fact that the inner hole is large, the drilling is inclined and the like due to uncontrollable factors such as overlong drill bit or shank, cutting vibration and the like, and the increasingly huge market demands are difficult to meet. Therefore, the precise plastic forming method is adopted to replace the traditional deep hole drilling process to produce the hollow thin-wall slender pipe shaft parts with large depth-diameter ratio and variable cross section, and the hollow thin-wall slender pipe shaft parts have the characteristics of high part performance, high material utilization rate and high production efficiency, and become the necessary trend under the driving of the global market.

The existing plastic forming methods for preparing hollow tube shaft parts comprise cross wedge rolling, radial forging, extrusion and the like, but for parts with the depth-to-diameter ratio more than or equal to 30 and the inner hole shape and position dimensional accuracy requirement, the cross wedge rolling and radial forging methods can obviously influence the roundness and coaxiality of the inner hole of the part in the part processing process; the single-channel extrusion forming can cause that the extrusion core rod bears too much because of the too large depth-to-diameter ratio, so that the core rod is bent to influence the straightness of an inner hole, the multi-channel extrusion forming needs the application of a plurality of extrusion dies to cause the cost to rise, and meanwhile, after the part is positioned for many times, the shape and position precision of the inner hole of the part can be influenced, and the coaxiality of the positioning for many times is easy to deviate.

Currently, there are related documents that propose plastic forming solutions for hollow tube shaft type parts with large depth-to-diameter ratio. The patent publication No. CN109332410A discloses a novel extrusion device and method for a hollow thin-wall shaft with large length-diameter ratio, which can improve the utilization rate of raw materials, shorten the production period and reduce the production cost through a simple structure, but the structural device can only be used for manufacturing a hollow shaft with constant inner diameter. The patent publication No. CN105921671A discloses a reverse extrusion forming method and a die for stepped hollow shaft parts, wherein a one-die two-process and two-continuous extrusion forming method is adopted to manufacture the variable cross-section hollow shaft part, so that the production speed can be increased, the extrusion force of a punch is shared, and the production beat is improved, but the formed variable cross-section hollow shaft part is not suitable for the characteristic of large depth-diameter ratio.

Disclosure of Invention

The technical problems to be solved by the invention are as follows: the hot extrusion and drawing forming device and the hot extrusion and drawing forming method for preparing the variable-section hollow pipe are suitable for processing the variable-section hollow pipe with large depth-to-diameter ratio and ensure coaxiality of different sections.

The invention solves the problems by adopting the following technical scheme: the utility model provides a hot extrusion drawing forming device for preparing variable cross-section hollow tube, includes forming mechanism, fixture and extrusion mechanism, forming mechanism is fixed setting, one side of forming mechanism is located to the fixture, the opposite side of forming mechanism is located to the extrusion mechanism, be equipped with the blank chamber that is used for placing the blank after the heating on the forming mechanism, one side that the blank chamber is close to the fixture is equipped with the shaping hole of shaping hollow tube external diameter, one side that the fixture is close to the forming mechanism is equipped with the shaping chamber of shaping hollow tube's tip, the tip external diameter of hollow tube is the reducing setting, enlarges to the tip direction external diameter of hollow tube, the fixture is along the axis direction removal connection of shaping hole, be equipped with extrusion section of thick bamboo and perforation dabber on the extrusion section of thick bamboo removes the grafting in the blank chamber and is used for the extrusion blank to the shaping hole direction removal, perforation dabber removes the internal diameter that is used for shaping hollow tube on the axis of connecting at the shaping hole, the internal diameter of hollow tube is the reducing setting.

Compared with the prior art, the invention has the advantages that: in the production process, the outer diameter reducing structure of the hollow pipe is extruded and formed through the forming cavity, the coaxiality of the outer diameter can be guaranteed only by guaranteeing the coaxiality of the forming cavity structure, the coaxiality of the forming cavity structure is a die structure, the blank can be stably applied to the machining of the concentric pipe only by high-precision machining forming, so that the coaxiality of the outer diameter is guaranteed, the inner diameter reducing structure of the hollow pipe is formed by perforating through the perforating mandrel, the coaxiality of different outer diameters of the perforating mandrel and the coaxiality of the outer wall of the hollow pipe only need to be guaranteed, the perforating mandrel is the die structure at first, the high-strength material which is difficult to deform can be adopted, the slow wire with a longer period is adopted for machining in the machining process, the dimensional precision of the perforating mandrel and the coaxiality of different outer diameters are guaranteed, then the blank moves in the blank cavity in the direction of the forming hole through the forming hole, the air in the blank is eliminated, the hollow cavity and the hollow structure in the forming hole is more uniform, and the perforating mandrel penetrates through the forming hole to pass through the coaxiality of the different outer diameters, and the diameter of the hollow pipe is also guaranteed to be applicable to the forming device with different lengths of the hollow pipe, and the diameter is different in the diameter of the hollow pipe is different from the forming device, and the diameter is different in the diameter of the diameter is different from the diameter of the hollow pipe, and the diameter is also variable, and the diameter is suitable to be equal to the hollow pipe.

As an improvement of the invention, a first driving hydraulic cylinder for driving the clamping mechanism to move is arranged on one side of the clamping mechanism far away from the forming mechanism, a first guide seat is arranged between the first driving hydraulic cylinder and the clamping mechanism, a plurality of first guide rods are arranged between the first guide seat and the forming mechanism, the clamping mechanism is movably connected to the plurality of first guide rods, by the improvement, the stability of the movement of the clamping mechanism can be ensured, when the clamping mechanism moves towards the forming mechanism, the accuracy of the alignment of the forming cavity and the forming hole can be ensured, and when the clamping mechanism moves away from the forming mechanism, the straightness of the hollow tube can be ensured, and the quality of the hollow tube can be ensured.

According to the invention, the first driving hydraulic cylinder is in driving connection with the clamping mechanism through the first traction rod, the thimble is arranged on the axis of the first traction rod and is used for propping against the perforating mandrel to form the complete inner diameter of the hollow tube, a spring is arranged at one end of the thimble, which is far away from the perforating mandrel, through the improvement, when the length of the hollow tube is stretched, the reducing structure of the inner diameter of the hollow tube can be separated from a forming hole area, so that the end part of the perforating mandrel is in a state without stable support, through the design of the thimble, the end part of the perforating mandrel can be stably connected to the forming hole area when the length of the hollow tube is not stretched, the thimble is propped against the end part of the perforating mandrel at the moment, and then after the end part of the perforating mandrel passes through the forming hole area, the end stability of the perforating mandrel is ensured, so that the condition that the perforating mandrel bends downwards is avoided, the problem of the inner diameter of the hollow tube is prevented, through the design of the spring, the propping force between the thimble and the perforating mandrel can be ensured, and the condition that the inner diameter of the hollow tube is excessively extruded or the perforating mandrel is deformed is avoided, so that the inner diameter of the hollow tube is ensured, and meanwhile, the thimble can be used for forming the hollow tube, and the hollow tube can be used in part of the forming area.

The clamping mechanism comprises a clamping seat movably connected to a first guide rod, an upper die and a lower die for forming a forming cavity, wherein the upper die is movably connected to the upper half part in the clamping seat through a hydraulic cylinder, the lower die is movably connected to the lower half part of the clamping seat through another hydraulic cylinder, upper positioning pins are arranged on two sides of the upper die, lower positioning pins are arranged on two sides of the lower die, an upper limit groove in movable limit connection with the upper positioning pins is arranged on the upper half part of the clamping seat, a lower limit groove in movable limit connection with the lower positioning pins is arranged on the lower half part of the clamping seat, when the upper positioning pins are abutted against the lower end of the upper limit groove, the upper die is abutted against the lower die to form the forming cavity, and by the improvement, the outer diameter of the end part of a hollow pipe is in a variable diameter setting mode, the outer diameter of the end part of the hollow pipe is enlarged, after the end part of the hollow pipe is formed, the upper die and the lower die is in a broken structure, the upper die and the lower die can be driven to be matched with the upper die and lower die in a high-accuracy mode when the lower die is driven by the upper die and lower die is in a high-accuracy mode, and the upper die and lower die is matched with the lower die is in a limit groove in a driving mode.

In addition, the invention is an improvement, the upper locating pin and the upper die are connected by adopting a threaded connection, the lower locating pin and the lower die are connected by adopting a threaded connection, the diameter of one end of the upper locating pin, which is far away from the upper die, is larger than the width of the upper limit groove, the inner side of one end of the upper locating pin, which is far away from the upper die, is propped against the clamping seat, the diameter of one end of the lower locating pin, which is far away from the lower die, is larger than the width of the lower limit groove, and the inner side of one end of the lower locating pin, which is far away from the lower die, is propped against the clamping seat.

As a further improvement of the invention, a second driving hydraulic cylinder for driving the extrusion mechanism to move is arranged on one side of the extrusion mechanism away from the forming mechanism, two driving hydraulic cylinders are arranged in the second driving hydraulic cylinder, one driving hydraulic cylinder is used for driving the extrusion cylinder to move, and the other driving hydraulic cylinder is used for driving the perforating mandrel to move.

According to the invention, the second driving hydraulic cylinder is fixedly connected with the extrusion cylinder through the connecting seat, the second guide seat is arranged between the second driving hydraulic cylinder and the connecting seat, the movable seat is arranged between the connecting seat and the forming mechanism, one end of the extrusion cylinder is fixedly connected with the connecting seat, the extrusion end of the extrusion cylinder is movably connected with the movable seat, a plurality of second guide rods are arranged between the second guide seat and the forming mechanism, the connecting seat and the movable seat are movably connected with the second guide rods, the connecting seat is internally provided with a centering sleeve, the centering sleeve is sleeved on the punching mandrel and used for ensuring that the punching mandrel moves along the axis direction of the forming hole, by the improvement, the stability of the movement of the connecting seat and the movable seat can be ensured, when the extrusion cylinder moves towards the direction of the blank cavity, the accuracy of the alignment of the extrusion cylinder and the blank cavity can be ensured, when the extrusion cylinder moves towards the forming hole, the punching mandrel moves towards the forming hole, the coaxiality between the punching mandrel and the forming hole is ensured, and the high quality of the hollow tube inner diameter is ensured.

According to the invention, the compression spring is arranged between the movable seat and the connecting seat and sleeved on the second guide rod, and by the improvement, the movable seat and the connecting seat are required to be driven to move because of the relative movement between the movable seat and the connecting seat, and the direct collision between the movable seat and the connecting seat can be avoided through the design of the compression spring, so that the movable seat and the connecting seat are protected.

As an improvement of the invention, the extrusion end of the extrusion cylinder is also connected and fixed with a high-temperature-resistant extrusion ring, the extrusion ring is provided with a through hole for the perforating core shaft to pass through, and by the improvement, the production cost of the extrusion cylinder is reduced under the condition that the extrusion quality of the extrusion cylinder can be protected by the design of the extrusion ring, and when the extrusion ring is damaged, the extrusion ring is only required to be replaced, and the whole extrusion cylinder is not required to be replaced.

The technical scheme adopted by the invention for solving the problems is that a hot extrusion and drawing forming method for preparing the variable cross-section hollow pipe is suitable for a hot extrusion and drawing forming device for preparing the variable cross-section hollow pipe, and comprises the following steps of:

s1: driving the upper die and the lower die to be matched;

s2: the first driving hydraulic cylinder is started to drive the clamping mechanism to move towards the forming mechanism direction, and the forming cavity and the forming hole are mutually connected

Abutting and communicating;

s3: closing the first driving hydraulic cylinder;

s4: placing a billet heated to a suitable temperature in a billet cavity;

s5: starting a second driving hydraulic cylinder, and driving the extrusion cylinder to move towards the direction of the blank cavity by the connecting seat;

s6: the connecting seat is propped against the compression spring to drive the moving seat to move towards the forming mechanism until the moving seat and the forming mechanism

The two are propped against each other;

s7: the connecting seat continuously drives the extrusion cylinder to move forwards, the extrusion cylinder passes through the moving seat and enters the blank cavity to be propped against the blank,

suspending driving the extrusion barrel;

s8: driving the perforating core to move along the direction of the blank cavity until the perforating core shaft penetrates through the blank and enters the clamping mechanism and the ejector pin

Abutting, suspending driving the perforating mandrel;

s9: the extrusion cylinder is driven to enable the extrusion ring to extrude blanks in the blank cavity, the blanks are deformed, and the blanks are led to the forming cavity through the forming holes

Flow until the forming cavity is filled;

s10: the first driving hydraulic cylinder is reversely driven to separate the clamping mechanism from the forming mechanism, and the blank is continuously pulled out of the forming hole under the synchronous action of the extrusion cylinder, and the perforating mandrel is synchronously driven to keep the perforating mandrel in a propping state with the ejector pin all the time;

s11: after the blanks in the blank cavity are completely extruded, the hollow tube to be formed is cooled, and the upper die and the lower die are separated to make the forming cavity

Separating from the reducing end of the hollow tube, the clamping mechanism is kept away from the forming mechanism;

s12: the second driving hydraulic cylinder is reversely driven, the hollow pipe moves along with the direction of the perforating core axial direction of the second driving hydraulic cylinder, and the hollow pipe is hollow

After the reducing end of the pipe abuts against the forming hole, the perforating mandrel is separated from the hollow pipe;

s13: and (5) taking the hollow tube off from the forming mechanism to finish the processing of the hollow tube.

Compared with the prior art, the invention has the advantages that: in the production process, the outer diameter reducing structure of the hollow pipe is extruded and formed through the forming cavity, the coaxiality of the outer diameter can be guaranteed only by guaranteeing the coaxiality of the forming cavity structure, the coaxiality of the forming cavity structure is a die structure, the blank can be stably applied to the machining of the concentric pipe only by high-precision machining forming, so that the coaxiality of the outer diameter is guaranteed, the inner diameter reducing structure of the hollow pipe is formed by perforating through the perforating mandrel, the coaxiality of different outer diameters of the perforating mandrel and the coaxiality of the outer wall of the hollow pipe only need to be guaranteed, the perforating mandrel is the die structure at first, the high-strength material which is difficult to deform can be adopted, the slow wire with a longer period is adopted for machining in the machining process, the dimensional precision of the perforating mandrel and the coaxiality of different outer diameters are guaranteed, then the blank moves in the blank cavity in the direction of the forming hole through the forming hole, the air in the blank is eliminated, the hollow cavity and the hollow structure in the forming hole is more uniform, and the perforating mandrel penetrates through the forming hole to pass through the coaxiality of the different outer diameters, and the diameter of the hollow pipe is also guaranteed to be applicable to the forming device with different lengths of the hollow pipe, and the diameter is different in the diameter of the hollow pipe is different from the forming device, and the diameter is different in the diameter of the diameter is different from the diameter of the hollow pipe, and the diameter is also variable, and the diameter is suitable to be equal to the hollow pipe.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present invention.

FIG. 2 is a schematic cross-sectional view of the overall structure of the present invention at a preparatory stage.

FIG. 3 is a schematic view showing the connection structure of the forming mechanism at the initial stage of extrusion according to the present invention.

FIG. 4 is a schematic view of the structure of the ejector pin and the piercing mandrel of the present invention.

Fig. 5 is a schematic cross-sectional view of the clamping mechanism of the present invention.

FIG. 6 is a schematic cross-sectional view of the extrusion mechanism of the present invention.

FIG. 7 is a schematic view of the structure of the hollow tube of the present invention when it is formed.

The figure shows: 1. forming mechanism, 1.1, blank cavity, 1.2, forming hole, 2, clamping mechanism, 2.1, forming cavity, 2.2, clamping seat, 2.2.1, upper limit groove, 2.2.2, lower limit groove, 2.3, upper die, 2.3.1, upper locating pin, 2.4, lower die, 2.4.1, lower locating pin, 3, extruding mechanism, 3.1, extruding cylinder, 3.1.1, extruding ring, 3.1.2, through hole, 3.2, perforating core shaft, 4, first driving hydraulic cylinder, 4.1, traction rod, 4.2, thimble, 4.2.1, centering hole, 4.3, spring, 5, first guide seat, 6, first guide rod, 7, second driving hydraulic cylinder, 8, connecting seat, 8.1, centering sleeve, 9, second guide seat, 10, moving seat, 11, second guide rod, 12, compression spring, 13 and hollow tube.

Detailed Description

Embodiments of the present invention are further described below with reference to the accompanying drawings.

As shown in fig. 1-3, a hot extrusion and drawing forming device for preparing a variable cross-section hollow tube comprises a forming mechanism 1, a clamping mechanism 2 and an extrusion mechanism 3, wherein the forming mechanism 1 is fixedly arranged, the clamping mechanism 2 is arranged on one side of the forming mechanism 1, the extrusion mechanism 3 is arranged on the other side of the forming mechanism 1, a blank cavity 1.1 for placing a heated blank is arranged on the forming mechanism 1, a forming hole 1.2 for forming the outer diameter of the hollow tube 13 is arranged on one side of the blank cavity 1.1 close to the clamping mechanism 2, a forming cavity 2.1 for forming the end part of the hollow tube 13 is arranged on one side of the clamping mechanism 2 close to the forming mechanism 1, the outer diameter of the end part of the hollow tube 13 is in a variable diameter arrangement, the outer diameter of the end part of the hollow tube 13 is enlarged, the clamping mechanism 2 is movably connected along the axial direction of the forming hole 1.2, an extrusion cylinder 3.1 and a perforating mandrel 3.2 are arranged on the extrusion mechanism 3, the extrusion cylinder 3.1 is movably inserted in the blank cavity 1.1 for extruding the blank to move along the direction forming hole 1.2, and the perforating mandrel is movably connected on the inner diameter of the hollow tube 13 in the axial direction of the forming hole 1.2.

The clamping mechanism 2 is provided with a first driving hydraulic cylinder 6 for driving the clamping mechanism 2 to move on one side far away from the forming mechanism 1, a first guide seat 5 is arranged between the first driving hydraulic cylinder 6 and the clamping mechanism 2, a plurality of first guide rods 6 are arranged between the first guide seat 5 and the forming mechanism 1, and the clamping mechanism 2 is movably connected to the plurality of first guide rods 6.

As shown in fig. 2 and fig. 4, the first driving hydraulic cylinder 6 is in driving connection with the clamping mechanism 2 through the traction rod 4.1, a thimble 4.2 is arranged on the axis of the traction rod 4.1, the thimble 4.2 is used for propping against the perforating mandrel 3.2, forming the complete inner diameter of the hollow tube 13, a spring 4.3 is arranged at one end, away from the perforating mandrel 3.2, of the thimble 4.2, one end, propped against the thimble 4.2, of the perforating mandrel 3.2 is conical, a blank can be better penetrated, meanwhile, a centering hole 4.2.1 is formed at one end, propped against the perforating mandrel 3.2, centering of the perforating mandrel 3.2 can be better ensured, and coaxiality of the inner diameter of the hollow tube 13 is ensured when the perforating mandrel 3.2 is kept in forming the hollow tube 13.

As shown in fig. 1, fig. 2 and fig. 5, the clamping mechanism 2 comprises a clamping seat 2.2 movably connected to the first guide rod 6, an upper die 2.3 and a lower die 2.4 for forming a forming cavity 2.1, an upper half part movably connected to the clamping seat 2.2 through a hydraulic cylinder, a lower die 2.4 movably connected to a lower half part of the clamping seat 2.2 through another hydraulic cylinder, an upper locating pin 2.3.1 arranged on two sides of the upper die 2.3, a lower locating pin 2.4.1 arranged on two sides of the lower die 2.4, an upper limit groove 2.2.1 arranged on the upper half part of the clamping seat 2.2 and in movable limit connection with the upper locating pin 2.3.1, a lower limit groove 2.2.1 arranged on the lower half part of the clamping seat 2.2.2 and in movable limit groove 2.1, and a lower limit groove 2.1 arranged on one end of the upper die 2.1 and the lower die 2.1, and a diameter of the upper die 2.1 and the lower die 2.1 arranged on two ends of the lower die 2.4, and a diameter of the upper die 2.1.1 and the lower die 2.1 is larger than the lower die 2.1, and the upper end of the upper die 2.1 is far from the upper end of the upper die 2.1 and the lower die 2.4, and the lower die 2.1 is formed far from the upper end of the upper die 2.1 and the lower die 2.1.

As shown in fig. 1, fig. 2 and fig. 6, one side of the extrusion mechanism 3, which is far away from the forming mechanism 1, is provided with a second driving hydraulic cylinder 7 for driving the extrusion mechanism 3 to move, two driving hydraulic cylinders are arranged in the second driving hydraulic cylinder 7, one driving hydraulic cylinder is used for driving the extrusion cylinder 3.1 to move, the other driving hydraulic cylinder is used for driving the perforating mandrel 3.2 to move, the second driving hydraulic cylinder 7 is fixedly connected with the extrusion cylinder 3.1 through a connecting seat 8, a second guide seat 9 is arranged between the second driving hydraulic cylinder 7 and the connecting seat 8, a movable seat 10 is arranged between the connecting seat 8 and the forming mechanism 1, one end of the extrusion cylinder 3.1 is fixedly connected to the connecting seat 8, the extrusion end of the extrusion cylinder 3.1 is movably connected to the movable seat 10, a plurality of second guide rods 11 are arranged between the second guide seat 9 and the forming mechanism 1, the connecting seat 8 and the movable seat 10 are all movably connected to the second guide rods 11, a centering sleeve 8.1 is arranged in the connecting seat 8, a centering sleeve 8.1 is arranged between the connecting seat 8 and the compression mandrel 3.2.1 and the compression mandrel 3.1 is further provided with a compression sleeve 12.1 along the compression mandrel 3.2, and the compression mandrel 3.1 is further provided with a compression mandrel 12.2, and the compression mandrel 1 is fixedly connected to the compression mandrel 1 along the compression mandrel 2.2.

As shown in fig. 3, the die of the blank cavity 1.1 is detachably connected in the forming mechanism 1, and when extrusion is performed, the die of the blank cavity 1.1 is limited in the forming mechanism 1, and when blanking and taking are performed, the die of the blank cavity 1.1 can be detached.

The first guide rod 6 and the second guide rod 11 may be the same guide rod, so that the moving coaxiality can be better ensured.

As shown in fig. 2, 3 and 7, a hot extrusion and drawing method for preparing a hollow pipe with a variable cross section is applicable to a hot extrusion and drawing device for preparing a hollow pipe with a variable cross section, and comprises the following steps:

s1: driving the upper die 2.3 and the lower die 2.4 to be matched;

s2: starting a first driving hydraulic cylinder 6, driving the clamping mechanism 2 to move towards the forming mechanism 1, and enabling the forming cavity 2.1 to prop against and be communicated with the forming hole 1.2;

s3: closing the first driving hydraulic cylinder 6;

s4: placing a billet which is heated to a suitable temperature in the billet cavity 1.1;

s5: starting a second driving hydraulic cylinder 7, and driving the extrusion cylinder 3.1 to move towards the blank cavity 1.1 by the connecting seat 8;

s6: the connecting seat 8 is propped against the compression spring 12 to drive the movable seat 10 to move towards the forming mechanism 1 until the movable seat 10 is propped against the forming mechanism 1;

s7: the connecting seat 8 continuously drives the extrusion cylinder 3.1 to move forwards, the extrusion cylinder 3.1 passes through the moving seat 10 and enters the blank cavity 1.1,

the extrusion cylinder 3.1 is stopped to be driven against the blank;

s8: the perforating mandrel 3.2 is driven to move towards the blank cavity 1.1 until the perforating mandrel 3.2 penetrates through the blank and enters the clamping device

The mechanism 2 is propped against the thimble 4.2, and the driving of the perforating mandrel 3.2 is stopped;

s9: the extrusion cylinder 3.1 is driven to extrude the blank in the blank cavity 1.1 by the extrusion ring 3.1.1, and the blank is deformed and formed

The holes 1.2 flow in the direction of the forming cavity 2.1 until the forming cavity 2.1 is filled;

s10: the first driving hydraulic cylinder 6 is reversely driven to separate the clamping mechanism 2 from the forming mechanism 1, and the blank is continuously pulled out of the forming hole 1.2 under the synchronous action of the extrusion cylinder 3.1, and the perforating mandrel 3.2 is synchronously driven to ensure that the perforating mandrel

3.2 always keeps the state of being propped against the thimble 4.2;

s11: after the blanks in the blank cavity are completely extruded, the hollow tube 13 to be formed is cooled, the upper die 2.3 is separated from the lower die 2.4,

separating the forming cavity 2.1 from the reduced end of the hollow tube 13, the clamping mechanism 2 continuing to be remote from the forming mechanism 1;

s12: the second driving hydraulic cylinder 7 is reversely driven, the hollow tube 13 moves along with the perforating mandrel 3.2 towards the second driving hydraulic cylinder 7, and after the reducing end part of the hollow tube 13 is propped against the forming hole 1.2, the perforating mandrel 3.2 is separated from the hollow tube 13;

s13: the hollow tube 13 is removed from the forming mechanism 1, and the hollow tube 13 is finished.

The foregoing is illustrative of the preferred embodiments of the present invention and is not to be construed as limiting the claims. The present invention is not limited to the above embodiments, and the specific structure thereof is allowed to vary. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Claims (10)

1. A hot extrusion drawing forming device for preparing variable cross-section hollow tube, its characterized in that: including forming mechanism (1), fixture (2) and extrusion mechanism (3), forming mechanism (1) is fixed setting, one side of forming mechanism (1) is located to fixture (2), the opposite side of forming mechanism (1) is located to extrusion mechanism (3), be equipped with blank chamber (1.1) that are used for placing the blank after the heating on forming mechanism (1), one side that is close to fixture (2) in blank chamber (1.1) is equipped with shaping hole (1.2) of shaping hollow tube (13) external diameter, one side that is close to fixture (2) is equipped with shaping chamber (2.1) of the tip of shaping hollow tube (13) tip external diameter of hollow tube (13) is the reducing setting, and the tip direction external diameter of to hollow tube (13) enlarges, fixture (2) are connected along the axis direction removal of shaping hole (1.2), be equipped with extrusion section of thick bamboo (3.1) and perforation (3.2) on extrusion mechanism (3.1) one side that is close to fixture (2), extrusion section of thick bamboo (3.1) is used for the shaping hollow tube (1.1) internal diameter direction of moving in the hollow tube (1.1) the inside diameter direction of hollow tube (13), the inside diameter of hollow tube (13) is connected.

2. A hot extrusion apparatus for making a hollow tube of varying cross-section as claimed in claim 1, wherein: one side of the clamping mechanism (2) away from the forming mechanism (1) is provided with a first driving hydraulic cylinder (4) for driving the clamping mechanism (2) to move, a first guide seat (5) is arranged between the first driving hydraulic cylinder (4) and the clamping mechanism (2), a plurality of first guide rods (6) are arranged between the first guide seat (5) and the forming mechanism (1), and the clamping mechanism (2) is movably connected to the plurality of first guide rods (6).

3. A hot extrusion apparatus for making a hollow tube of varying cross-section as claimed in claim 2, wherein: the first driving hydraulic cylinder (4) is in driving connection with the clamping mechanism (2) through the traction rod (4.1), a thimble (4.2) is arranged on the axis of the traction rod (4.1), the thimble (4.2) is used for propping against the perforating mandrel (3.2) to form the inner diameter of the complete hollow tube (13), and a spring (4.3) is arranged at one end, far away from the perforating mandrel (3.2), of the thimble (4.2).

4. A hot extrusion apparatus for making a hollow tube of varying cross-section as claimed in claim 2, wherein: clamping mechanism (2) are including movable connection grip slipper (2.2) on first guide bar (6), be used for constituteing last mould (2.3) and lower mould (2.4) of shaping chamber (2.1) last mould (2.3) remove the last half of connection in grip slipper (2.2) through a pneumatic cylinder, lower mould (2.4) remove the lower half of connection in grip slipper (2.2) through another pneumatic cylinder, the both sides of going up mould (2.3) are equipped with locating pin (2.3.1), the both sides of lower mould (2.4) are equipped with lower locating pin (2.4.1), the last half of grip slipper (2.2) is equipped with last spacing groove (2.2.1) of spacing connection with last locating pin (2.3.1), the lower half of grip slipper (2.2) is equipped with and moves spacing groove (2.2.1) of spacing connection with lower locating pin (2.4.1), and when last locating pin (2.1) offset lower mould (2.2.4.1), form lower mould (2.1) and lower mould (2.2.4.1).

5. The hot extrusion apparatus for preparing a hollow tube of varying cross-section of claim 4, wherein: the upper locating pin (2.3.1) is in threaded connection with the upper die (2.3), the lower locating pin (2.4.1) is in threaded connection with the lower die (2.4), one end diameter of the upper locating pin (2.3.1) away from the upper die (2.3) is larger than the width of the upper limit groove (2.2.1), one end inner side of the upper locating pin (2.3.1) away from the upper die (2.3) is propped against the clamping seat (2.2), one end diameter of the lower locating pin (2.4.1) away from the lower die (2.4) is larger than the width of the lower limit groove (2.2.2), and one end inner side of the lower locating pin (2.4.1) away from the lower die (2.4) is propped against the clamping seat (2.2).

6. A hot extrusion apparatus for making a hollow tube of varying cross-section as claimed in claim 1, wherein: one side of the extrusion mechanism (3) far away from the forming mechanism (1) is provided with a second driving hydraulic cylinder (7) for driving the extrusion mechanism (3) to move, two driving hydraulic cylinders are arranged in the second driving hydraulic cylinder (7), one driving hydraulic cylinder is used for driving the extrusion cylinder (3.1) to move, and the other driving hydraulic cylinder is used for driving the perforating mandrel (3.2) to move.

7. The hot extrusion apparatus for preparing a hollow tube of varying cross-section of claim 6, wherein: the novel punching machine is characterized in that the second driving hydraulic cylinder (7) is fixedly connected with the extrusion cylinder (3.1) through a connecting seat (8), a second guide seat (9) is arranged between the second driving hydraulic cylinder (7) and the connecting seat (8), a movable seat (10) is arranged between the connecting seat (8) and the forming mechanism (1), one end of the extrusion cylinder (3.1) is fixedly connected with the connecting seat (8), the extrusion end of the extrusion cylinder (3.1) is movably connected with the movable seat (10), a plurality of second guide rods (11) are arranged between the second guide seat (9) and the forming mechanism (1), the connecting seat (8) is movably connected with the movable seat (10) on the plurality of second guide rods (11), a centering sleeve (8.1) is arranged in the connecting seat (8), and the centering sleeve (8.1) is sleeved on the punching mandrel (3.2) and is used for guaranteeing that the punching mandrel (3.2) moves along the axis direction of the forming hole (1.2).

8. A hot extrusion apparatus for making a hollow tube of varying cross-section as set forth in claim 7, wherein: a compression spring (12) is arranged between the movable seat (10) and the connecting seat (8), and the compression spring (12) is sleeved on the second guide rod (11).

9. The hot extrusion apparatus for preparing a hollow tube of varying cross-section of claim 6, wherein: the extrusion end of the extrusion cylinder (3.1) is also connected and fixed with a high-temperature-resistant extrusion ring (3.1.1), and the extrusion ring (3.1.1) is provided with a through hole (3.1.2) for the perforating mandrel (3.2) to pass through.

10. A hot extrusion forming method for preparing a hollow pipe with a variable cross section, which is characterized by being applied to the hot extrusion forming device for preparing a hollow pipe with a variable cross section according to any one of claims 1 to 9, and comprising the following steps:

s1: driving the upper die (2.3) and the lower die (2.4) to be matched;

s2: starting a first driving hydraulic cylinder (4), driving the clamping mechanism (2) to move towards the forming mechanism (1), and enabling the forming cavity (2.1) to prop against and be communicated with the forming hole (1.2);

s3: closing the first driving hydraulic cylinder (4);

s4: placing a billet which is heated to a suitable temperature in a billet cavity (1.1);

s5: starting a second driving hydraulic cylinder (7), and driving the extrusion cylinder (3.1) to move towards the blank cavity (1.1) by the connecting seat (8);

s6: the connecting seat (8) is propped against the compression spring (12) to drive the movable seat (10) to move towards the forming mechanism (1) until the movable seat (10) is propped against the forming mechanism (1);

s7: the connecting seat (8) continuously drives the extrusion cylinder (3.1) to move forwards, the extrusion cylinder (3.1) passes through the moving seat (10) and enters the blank cavity (1.1) to be propped against the blank, and the extrusion cylinder (3.1) is stopped to be driven;

s8: driving the perforating core shaft (3.2) to move towards the blank cavity (1.1) until the perforating core shaft (3.2) penetrates through the blank, entering the clamping mechanism (2) to prop against the thimble (4.2), and suspending driving the perforating core shaft (3.2);

s9: driving the extrusion cylinder (3.1), so that the extrusion ring (3.1.1) extrudes blanks in the blank cavity (1.1), and the blanks are deformed and flow to the forming cavity (2.1) through the forming hole (1.2) until the forming cavity (2.1) is filled;

s10: the first driving hydraulic cylinder (4) is reversely driven to separate the clamping mechanism (2) from the forming mechanism (1), and the blank is continuously pulled out of the forming hole (1.2) under the synchronous action of the extrusion cylinder (3.1),

the perforating core shaft (3.2) is synchronously driven, so that the perforating core shaft (3.2) always keeps the abutting state with the thimble (4.2);

s11: after the blanks in the blank cavity are completely extruded, the hollow tube (13) to be formed is cooled, the upper die (2.3) is separated from the lower die (2.4) to separate the forming cavity (2.1) from the reducing end part of the hollow tube (13),

the clamping mechanism (2) is further away from the forming mechanism (1);

s12: the second driving hydraulic cylinder (7) is reversely driven, the hollow pipe (13) moves along with the perforating mandrel (3.2) towards the second driving hydraulic cylinder (7), and after the reducing end part of the hollow pipe (13) is propped against the forming hole (1.2), the perforating mandrel (3.2) is separated from the hollow pipe (13);

s13: and (3) removing the hollow tube (13) from the forming mechanism (1) to finish the processing of the hollow tube (13).

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