CN111687356A - Straight bevel gear warm forging precision forming die - Google Patents

Abstract

The invention provides a warm forging precision forming die for a straight bevel gear, which relates to the technical field of mechanical manufacturing and comprises a rough forging die matched with an upper tooth die and a lower cavity die and a finish forging die matched with the upper cavity die and the lower tooth die; wherein, a knockout structure consisting of elastic elements is arranged in the upper dies of the rough forging die and the finish forging die, so as to prevent the formed gear blank and the gear from being adhered to the upper dies; guide cylinders are respectively arranged on the outer circumferences of the tooth dies of the rough forging die and the finish forging die, so that the staggered die amount of the upper die and the lower die is ensured not to exceed 0.3mm, prestress is provided for the tooth dies, and the tooth profile precision ultra-difference caused by tooth profile deformation of the tooth dies due to three-way pressure stress is prevented; meanwhile, the lower cavity die is provided with a floating die lifting structure to float the lower cavity die, and the blank is accurately positioned by matching with the shaft neck of the lower cavity die, so that the blank is uniformly distributed in the tooth profile of the cavity of the tooth die during rough forging, the deformation of the gear after residual stress is eliminated is reduced, a concave structure towards the inside of the tooth blank is conveniently forged on the tooth profile end surface and the shaft neck end surface of the tooth blank, and the utilization rate of the blank is improved.

Description

Straight bevel gear warm forging precision forming die

Technical Field

The invention relates to the technical field of machine manufacturing, in particular to a warm forging precision forming die for a straight bevel gear.

Background

When the electric screw press is used for warm forging forming of the on-line straight bevel gear, on one hand, due to the anisotropy of a deformation material and the fact that a die carrier used for die installation is required to be convenient for a manipulator to place and grab materials, a guide pillar-free structure is usually adopted, and the problem that the staggered die amount is not more than 0.3mm when the upper die and the lower die are closed by only depending on the precision and the rigidity of a guide rail of the device cannot be solved; on the other hand, when the rough forging tooth die is used as a lower die in the prior art, the blank to be deformed cannot be accurately positioned in the rough forging tooth die because the diameter of the positioning surface in the rough forging tooth die is usually larger than that of the blank to be deformed; due to the two reasons, the blank to be deformed is unevenly distributed when the gear blank is formed, the residual stress of the gear is eliminated, the deformation is large, and the precision grade is low. Meanwhile, when the rough forging tooth die is used as a lower die, the contact time with a high-temperature tooth blank is long, the rough forging tooth die is easy to soften by high-temperature tempering, the service life of the rough forging tooth die is greatly shortened, and the service life of the rough forging tooth die is generally not more than 3000.

In some processes, the positions of a rough forging tooth die and a rough forging cavity die are exchanged, the rough forging tooth die is used as an upper die, the rough forging cavity die is used as a lower die, a blank to be deformed is accurately positioned by using a shaft neck of the rough forging cavity die, and a hydraulic device is used for beating, but the hydraulic device has hysteresis, so that when an equipment slide block returns to a certain distance above a lower dead point, an extruded tooth blank is separated from a die cavity of the rough forging tooth die, and a manipulator cannot normally grab the tooth blank, so that the automatic line of the electric screw press is abnormally stopped.

Disclosure of Invention

The invention aims to provide a warm forging precision forming die for a straight bevel gear, which is characterized in that the forming die is subjected to precision structural design and comprises an upper die and a lower die which are adjusted to form, the upper die automatically beats materials during forging, a blank is accurately positioned, a prestress and guide mechanism is arranged, the service life of a rough forging die and a finish forging die is obviously prolonged, the tooth profile precision and the blank utilization rate are improved, and the technical problems are effectively solved.

In order to achieve the above purpose, the invention provides the following technical scheme: a warm forging precision forming die for a straight bevel gear comprises a rough forging die and a finish forging die which are formed by an electric screw press automatic line, wherein the rough forging die and the finish forging die are defined to be divided into a first upper die and a first lower die by taking a die cavity parting surface in the rough forging die as a boundary, and the finish forging die is defined to be divided into a second upper die and a second lower die by taking the die cavity parting surface in the finish forging die as a boundary;

the first upper die comprises an upper tooth die, a first upper knockout ejector rod, an upper tooth die pressure-bearing cushion block, a first upper transition cushion block, a first upper pressure-bearing cushion block, a first upper knockout elastic element and a first guide cylinder; the lower end surface of the upper tooth mold is provided with an upper tooth mold cavity with a downward opening, the outer circumference of the upper tooth mold is sleeved with a first guide cylinder, and the lower end surface of the first guide cylinder protrudes downwards out of the lower end surface of the upper tooth mold; the first upper knockout mandril is vertically arranged in the inner holes of the upper tooth die and the upper tooth die pressure-bearing cushion block and is supported by a first upper transition cushion block movably arranged in the upper tooth die pressure-bearing cushion block and the inner hole of the first upper pressure-bearing cushion block; the first upper transition cushion block is a step shaft, and the step surface of the first upper transition cushion block is supported on the upper end surface of the pressure-bearing cushion block of the upper tooth mold; the first upper knockout elastic element is vertically arranged in an inner hole of the first upper pressure-bearing cushion block, the lower end face of the first upper knockout elastic element is abutted against the upper end face of the first upper transition cushion block, and the first upper knockout elastic element, the first upper transition cushion block and the first upper knockout ejector rod form a coaxial jacking structure;

the first upper knockout elastic element at least has a first state and a second state in an inner hole of the first upper pressure-bearing cushion block; in the first state, the first upper knockout elastic element supports the step surface of the first upper transition cushion block to abut against the upper end surface of the upper tooth die pressure-bearing cushion block, and the first upper knockout ejector rod partially extends into the upper tooth die cavity; and the second state is that the first upper knockout elastic element is in a compressed state, and the step surface of the first upper transition cushion block is spaced from the upper end surface of the upper tooth die pressure-bearing cushion block.

The first lower die comprises a lower cavity die, a first lower ejector rod, a floating die lifting elastic element, a lower cavity die pressure-bearing cushion block, a first lower transition cushion block, a first lower pressure-bearing cushion block and a first lower ejector rod; the upper end surface of the lower cavity die is provided with a lower cavity die with an upward opening, the lower cavity die is matched with the upper tooth die, and the outer circumference of the lower cavity die is matched with the inner hole of the first guide cylinder; an inner hole is formed in the middle of the lower cavity die pressure-bearing cushion block, the first lower ejector rod is vertically arranged in the lower cavity die and the inner hole of the lower cavity die pressure-bearing cushion block, and the first lower ejector rod is supported by a first lower transition cushion block movably arranged in the inner hole of the lower cavity die pressure-bearing cushion block; the first lower transition cushion block is arranged as a vertical cylindrical shaft, and the lower end surface of the cylindrical shaft is supported on the upper end surface of the first lower pressure bearing cushion block; the first lower ejector rod is vertically arranged in an inner hole of the first lower pressure bearing cushion block, the upper end face of the first lower ejector rod is abutted against the lower end face of the first lower transition cushion block, and the first lower ejector rod, the first lower transition cushion block and the first lower ejector rod form a coaxial jacking structure;

the floating die lifting elastic element is arranged between the lower cavity die and the first lower pressure-bearing cushion block, the upper end face of the floating die lifting elastic element abuts against the lower end face of the lower cavity die, and the lower end face of the floating die lifting elastic element abuts against the upper end face of the first lower pressure-bearing cushion block; the floating die lifting elastic element at least has a first compression state and a second compression state between the lower cavity die and the first lower pressure bearing cushion block, the first compression state is that the floating die lifting elastic element supports the lower end face of the lower cavity die and is spaced from the upper end face of the lower cavity die pressure bearing cushion block, the second compression state is that the floating die lifting elastic element is compressed to the lower end face of the lower cavity die and is abutted against the upper end face of the lower cavity die pressure bearing cushion block, and the first lower ejector rod part extends into the lower cavity die.

The second upper die comprises an upper cavity die, a second upper knockout ejector rod, an upper cavity die pressure-bearing cushion block, a second upper transition cushion block, a second upper pressure-bearing cushion block and a second upper knockout elastic element; an upper female die cavity with a downward opening is arranged in the middle of the lower end surface of the upper cavity die, and the upper female die cavity partially protrudes downwards from the lower end surface of the upper cavity die to form an excircle guide part of the upper cavity die; the second upper knockout pin is vertically arranged in the inner holes of the upper cavity die and the upper cavity die pressure-bearing cushion block and is supported by a second upper transition cushion block movably arranged in the upper cavity die pressure-bearing cushion block and the inner hole of the second upper pressure-bearing cushion block; the second upper transition cushion block is a step shaft, and the step surface of the second upper transition cushion block is supported on the upper end surface of the upper cavity die pressure-bearing cushion block; the second upper knockout elastic element is vertically arranged in an inner hole of the second upper pressure-bearing cushion block, the lower end face of the second upper knockout elastic element is abutted against the upper end face of the second upper transition cushion block, and the second upper knockout elastic element, the second upper transition cushion block and the second upper knockout ejector rod form a coaxial jacking structure;

the second upper knockout elastic element at least has a third state and a fourth state in an inner hole of the second upper pressure-bearing cushion block; in the third state, the second upper knockout elastic element supports the step surface of the second upper transition cushion block to abut against the upper end surface of the upper cavity die pressure-bearing cushion block, and the second upper knockout ejector rod partially extends into the upper concave die cavity; and the fourth state is that the second upper knockout elastic element is in a compressed state, and the step surface of the second upper transition cushion block is spaced from the upper end surface of the upper cavity die pressure-bearing cushion block.

The second lower die comprises a lower tooth die, a second lower ejector rod, a lower tooth die pressure-bearing cushion block, a second lower transition cushion block, a second lower pressure-bearing cushion block and a second lower ejector rod, and the lower tooth die is matched with the upper cavity die; the upper end surface of the lower tooth die is provided with a lower tooth die cavity with an upward opening, and the outer circumference of the lower tooth die is sleeved with a second guide cylinder; the upper end surface of the second guide cylinder upwards protrudes out of the upper end surface of the lower tooth mold, and an inner hole of the second guide cylinder is matched with the outer circumference of the excircle guide part of the upper cavity mold; the second lower ejector rod is vertically arranged in the inner holes of the lower tooth die and the lower tooth die pressure-bearing cushion block, and is supported by a second lower transition cushion block movably arranged in the inner hole of the lower tooth die pressure-bearing cushion block, and part of the second lower ejector rod extends into the lower tooth die cavity; the second lower transition cushion block is arranged as a vertical cylindrical shaft, and the lower end surface of the cylindrical shaft is supported on the upper end surface of the second lower pressure bearing cushion block; the second lower ejector rod is vertically arranged in a second lower pressure bearing cushion block inner hole, the upper end face of the second lower ejector rod abuts against the lower end face of the second lower transition cushion block, and the second lower ejector rod, the second lower transition cushion block and the second lower ejector rod form a coaxial jacking structure.

Further, the height difference of the lower end surface of the first guide cylinder and the lower end surface of the upper tooth die in the vertical direction is defined as H1, the height difference of the upper end surface of the second guide cylinder and the upper end surface of the lower tooth die in the vertical direction is defined as H2, the height of the excircle guide part of the upper cavity die protruding out of the lower end surface of the upper cavity die is defined as H3, then H3 is H2, H2 is more than or equal to 23mm, and H1 is more than or equal to 40 mm.

Furthermore, an exhaust hole is formed in the excircle guide part of the upper cavity die.

Furthermore, the upper end face of the first guide cylinder abuts against the lower end face of the upper tooth die pressure-bearing cushion block, the lower end face of the second guide cylinder abuts against the upper end face of the lower tooth die pressure-bearing cushion block, the first guide cylinder is in interference fit with the upper tooth die, the second guide cylinder is in interference fit with the lower tooth die, the interference coefficient is kept to be 4-6 per mill optimal, the first guide cylinder and the second guide cylinder are made of H13 die steel, and the hardness of the first guide cylinder and the second guide cylinder after heat treatment is HRC 44-48.

Furthermore, a plurality of through holes penetrating through the upper end surface and the lower end surface of the lower cavity die pressure-bearing cushion block are also formed in the lower cavity die pressure-bearing cushion block, and the through holes are uniformly distributed along the periphery of the inner hole of the lower cavity die pressure-bearing cushion block; the floating die lifting elastic element is arranged in the through hole and is provided with a spring.

Further, the first upper knockout elastic element is set as a first nitrogen spring, and the second upper knockout elastic element is set as a second nitrogen spring; a first cooling mechanism is arranged in the first upper pressure-bearing cushion block, and a second cooling mechanism is arranged in the second upper pressure-bearing cushion block; the cooling mechanism is used for adjusting the nitrogen spring to a normal working temperature.

According to the technical scheme, the straight bevel gear warm forging precision forming die provided by the technical scheme of the invention has the beneficial effects that:

the warm forging precision forming die for the straight bevel gear, disclosed by the invention, is simple in structure and convenient to operate, and comprises a rough forging die matched with an upper tooth die and a lower cavity die and a finish forging die matched with the upper cavity die and the lower tooth die; when rough forging is carried out, the tooth die is arranged on the upper portion, the contact time of a high-temperature blank and the tooth die is shortest, the risk of high-temperature tempering softening of the tooth die is basically eliminated, the failure mode of the upper tooth die is only normal abrasion, and the service life of the tooth die is obviously prolonged. According to the invention, the knockout structures formed by elastic elements are respectively arranged in the upper dies of the rough forging die and the finish forging die, so that the formed gear blank and the gear are prevented from being adhered to the upper die, namely, the elastic elements store energy during die assembly, the blank is separated from the upper die by directly applying the energy storage during demoulding, and the problem of 'hysteresis' during knockout by adopting a hydraulic device is solved; the guide cylinders are respectively arranged on the outer circumferences of the upper tooth die of the rough forging die and the lower tooth die of the finish forging die, on one hand, the guide cylinders are used for matching the guide cavity die and the tooth dies to ensure that the staggered modulus of the upper die and the lower die does not exceed 0.3mm, on the other hand, the prestress in the covering range of the guide cylinders is provided for the cavity die, the tooth profile deformation of the tooth dies is avoided, and the flash of the blank is prevented from being generated during die matching and upsetting.

According to the invention, the lower die of the rough forging die is provided with the floating die lifting structure formed by the elastic structure, the lower cavity die is floated from the lower cavity die pressure bearing cushion block and matched with the cavity die shaft neck to accurately position the blank, so that the blank to be deformed is uniformly distributed in the tooth profile of the tooth model cavity during rough forging, the tooth profile precision is improved, and the deformation of the gear after residual stress is eliminated is reduced; meanwhile, the floating die lifting structure is compressed during die assembly during rough forging, so that the first lower ejection rod part extends into the lower concave die cavity, and a concave structure facing the inside of the gear blank is forged at the tooth-shaped end face and the shaft neck end face of the gear blank in cooperation with the first upper knockout ejector rod, and the utilization rate of the blank is improved by 3%.

In addition, the adoption of the structure for providing prestress on the guide cylinder for the precision forging tooth die not only ensures that the staggered modulus of the upper die and the lower die does not exceed 0.3mm, but also avoids the tooth profile deformation of the precision forging tooth die in a three-dimensional compressive stress state, thereby avoiding the problem of tooth profile accuracy reduction caused by die deformation; meanwhile, the exhaust holes are formed in the guide part of the outer circle of the precision forging upper cavity die, so that the uniform distribution of a lubricant on the tooth surface of the precision forging gear can be ensured, the consistency of precision of the precision forging tooth shape is ensured, the service life of the die is prolonged, and the amplification is increased by over 68.75 percent.

It should be understood that all combinations of the foregoing concepts and additional concepts described in greater detail below can be considered as part of the inventive subject matter of this disclosure unless such concepts are mutually inconsistent.

The foregoing and other aspects, embodiments and features of the present teachings can be more fully understood from the following description taken in conjunction with the accompanying drawings. Additional aspects of the present invention, such as features and/or advantages of exemplary embodiments, will be apparent from the description which follows, or may be learned by practice of specific embodiments in accordance with the teachings of the present invention.

Drawings

The drawings are not intended to be drawn to scale. In the drawings, each identical or nearly identical component that is illustrated in various figures may be represented by a like numeral. For purposes of clarity, not every component may be labeled in every drawing. Embodiments of various aspects of the present invention will now be described, by way of example, with reference to the accompanying drawings, in which:

FIG. 1 is a schematic structural view of a straight bevel gear rough forging forming die;

FIG. 2 is a schematic structural view of a straight bevel gear finish forging forming die;

FIG. 3 is a cross-sectional view of the upper tooth die with the first guide cylinder of FIG. 1;

FIG. 4 is a cross-sectional view of the first upper bearing pad of FIG. 1;

FIG. 5 is a cross-sectional view of the lower cavity mold of FIG. 1;

FIG. 6 is a cross-sectional view of the lower cavity mold pressure pad of FIG. 1;

FIG. 7 is a cross-sectional view of the first lower bearing pad of FIG. 1;

FIG. 8 is a cross-sectional view of the upper cavity mold of FIG. 2;

FIG. 9 is a cross-sectional view of the second upper bearing pad of FIG. 2;

fig. 10 is a cross-sectional view of the lower tooth die of fig. 2.

In the figure, the specific meaning of each mark is:

1-upper tooth die, 2-first upper knockout pin, 3-upper tooth die pressure-bearing cushion block, 4-first upper transition cushion block, 5-first upper pressure-bearing cushion block, 6-first upper knockout elastic element, 7-first guide cylinder, 8-lower cavity die, 9-first lower knockout pin, 10-floating knockout elastic element, 11-lower cavity die pressure-bearing cushion block, 12-first lower transition cushion block, 13-first lower pressure-bearing cushion block, 14-first lower knockout pin, 15-upper cavity die, 16-second upper knockout pin, 17-upper cavity die pressure-bearing cushion block, 18-second upper transition cushion block, 19-second upper pressure-bearing cushion block, 20-second upper knockout elastic element, 21-lower tooth die, 22-second lower knockout pin, 23-lower tooth die pressure-bearing cushion block, 24-a second lower transition cushion block, 25-a second lower pressure bearing cushion block, 26-a second lower ejector rod and 27-a second guide cylinder.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the drawings of the embodiments of the present invention. It is to be understood that the embodiments described are only a few embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the invention without any inventive step, are within the scope of protection of the invention. Unless defined otherwise, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this invention belongs.

The use of "first," "second," and similar terms in the description and claims of the present application do not denote any order, quantity, or importance, but rather the terms are used to distinguish one element from another. Similarly, the singular forms "a," "an," or "the" do not denote a limitation of quantity, but rather denote the presence of at least one, unless the context clearly dictates otherwise. The terms "comprises," "comprising," or the like, mean that the elements or items listed before "comprises" or "comprising" encompass the features, integers, steps, operations, elements, and/or components listed after "comprising" or "comprising," and do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. "upper", "lower", and the like are used only to indicate relative positional relationships, and when the absolute position of the object to be described is changed, the relative positional relationships may also be changed accordingly.

Based on the problems that in the process of forging the straight bevel gear, when a tooth die is used as a rough forging lower die, blank positioning is not accurate, so that the blank is unevenly distributed among tooth shapes during die assembly and the tempering softening life of the tooth die is short, and when the tooth die is used as a rough forging upper die, the problem of 'hysteresis' caused by adopting a hydraulic knockout mechanism exists; in addition, a series of technical problems that the requirement that the staggered mold quantity does not exceed 0.3mm cannot be met only by equipment positioning and a guide rail during forging exist. The invention aims to provide a warm forging precision forming die for a straight bevel gear, which has a simple structure, effectively solves the technical problems, and integrally improves the service life of the die and the precision of a formed gear.

The invention will be further described in detail with reference to the following embodiments shown in the accompanying drawings.

Referring to fig. 1 and 2, a warm forging precision forming die for a straight bevel gear comprises a roughing die and a finishing die which are formed by an electric screw press automatic line, wherein the die is defined to be divided into a first upper die and a first lower die by taking a die cavity parting surface in the roughing die as a boundary, and to be divided into a second upper die and a second lower die by taking a die cavity parting surface in the finishing die as a boundary; the first upper die comprises an upper tooth die 1, the first lower die comprises a lower cavity die 8, the second upper die comprises an upper cavity die 15, the second lower die comprises a lower tooth die 21, namely, a cavity die journal is used for positioning a blank during rough forging, the high-temperature blank mainly stays on the lower cavity die 8 during rough forging, the contact time between the high-temperature blank and the upper tooth die 1 is also reduced, the risk that the upper tooth die 1 is easily softened by high-temperature tempering is basically eliminated, the failure mode of the upper tooth die 1 is changed from the past collapse, deformation and cracking, the early failure mode of rapid wear is changed into the present normal wear failure, the service life of the upper tooth die 1 is changed from the past forming of not more than 3000 to the present forming of far more than 10000, and the service life of the rough forging tooth die is prolonged by more than 200%.

In order to avoid the technical problems that the upper tooth die 1 has hysteresis due to the fact that a hydraulic device is adopted for material beating on an automatic line of the electric screw press, and the conventional automatic line of the electric screw press has no guide post structure, and the offset of the upper die and the lower die during die assembly cannot exceed 0.3mm only by the aid of precision and rigidity of a guide rail of equipment, the structure of the upper tooth die 1 is improved as follows. As shown in fig. 3 and 4, the first upper die further includes a first upper knockout pin 2, an upper tooth die pressure-bearing cushion block 3, a first upper transition cushion block 4, a first upper pressure-bearing cushion block 5, a first upper knockout elastic element 6, and a first guide cylinder 7, wherein the lower end surface of the upper tooth die 1 is provided with an upper tooth die cavity with an opening facing downward, the first guide cylinder 7 is sleeved on the outer circumference of the upper tooth die 1, and the lower end surface of the first guide cylinder 7 protrudes downward from the lower end surface of the upper tooth die 1. The first upper knockout pin 2 is vertically arranged in the inner holes of the upper tooth die 1 and the upper tooth die pressure-bearing cushion block 3 and is supported by a first upper transition cushion block 4 movably arranged in the inner holes of the upper tooth die pressure-bearing cushion block 3 and the first upper pressure-bearing cushion block 5; the first upper transition cushion block 4 is a step shaft, and the step surface of the first upper transition cushion block 4 is supported on the upper end surface of the upper tooth mold pressure-bearing cushion block 3; the first upper knockout elastic element 6 is vertically arranged in an inner hole of the first upper pressure bearing cushion block 5, the lower end surface of the first upper knockout elastic element 6 props against the upper end surface of the first upper transition cushion block 4, and the first upper knockout elastic element 6, the first upper transition cushion block 4 and the first upper knockout ejector rod 2 form a coaxial ejector structure.

In order to ensure that the first upper knockout pin 2 can rapidly separate the tooth blank from the upper tooth die 1 during demolding, the first upper knockout elastic element 6 at least has a first state and a second state in an inner hole of the first upper pressure-bearing cushion block 5, specifically, the first state is that the first upper knockout elastic element 6 supports a step surface of the first upper transition cushion block 4 to be abutted against an upper end surface of the upper tooth die pressure-bearing cushion block 3, and at the moment, the part of the first upper knockout pin 2, which is close to the end part of the upper tooth die 1, extends into a cavity of the upper tooth die under the action of the first upper knockout elastic element 6; and in the second state, the first upper knockout elastic element 6 is in a compressed state, and under the action of the mold closing pressure, the step surface of the first upper transition cushion block 4 is spaced from the upper end surface of the upper tooth mold pressure-bearing cushion block 3.

The upper tooth die 1 is in a first state under the action of the first upper knockout elastic element 6 at the beginning, and is extruded by blanks in a cavity of the upper tooth die during die assembly, and the first upper knockout ejector rod 2 compresses the first upper knockout elastic element 6 upwards through the first upper transition cushion block 4, so that the pre-tightening energy storage of the first upper knockout elastic element 6 is realized; when the drawing of patterns, go up tooth mould 1 and upwards return stroke immediately after the slider of electronic screw press reachs the lower dead point, first material elastic component 6 of beating need not hydraulic start automatic recovery deformation, release the energy storage rapidly, first material elastic component 6 of beating pushes up material ejector pin 2 on pushing down first through first transition cushion 4 and stretches into the tooth model intracavity of tooth mould 1 until the part, material ejector pin 2 pushes out the tooth mould chamber with the tooth base that takes shape on first, make the tooth base break away from tooth mould 1, leave in the die cavity mould 8 all the time, avoid taking place tooth base and glue tooth mould 1 on, lead to the tooth base to drop from last tooth mould 1 and bump the phenomenon of hindering.

As shown in fig. 5 to 7, the first lower mold further includes a first lower ejector rod 9, a floating elastic element 10 for lifting the mold, a lower cavity mold pressure-bearing cushion block 11, a first lower transition cushion block 12, a first lower pressure-bearing cushion block 13, and a first lower ejector rod 14, an upper end surface of the lower cavity mold 8 is provided with a lower cavity mold with an upward opening, the lower cavity mold 8 is adapted to the upper tooth mold 1, and an outer circumference of the lower cavity mold 8 is adapted to an inner hole of the first guide cylinder 7. An inner hole is formed in the center of the lower cavity die pressure-bearing cushion block 11, the first lower ejector rod 9 is vertically arranged in the inner holes of the lower cavity die 8 and the lower cavity die pressure-bearing cushion block 11, and the first lower ejector rod 9 is supported by a first lower transition cushion block 12 movably arranged in the inner hole of the lower cavity die pressure-bearing cushion block 11. The first lower transition cushion block 12 is arranged as a vertical cylindrical shaft, and the lower end surface of the cylindrical shaft is supported on the upper end surface of the first lower pressure bearing cushion block 13; the first lower ejector rod 14 is vertically arranged in an inner hole of the first lower pressure bearing cushion block 13, the upper end face of the first lower ejector rod 14 abuts against the lower end face of the first lower transition cushion block 13, and the first lower ejector rod 14, the first lower transition cushion block 12 and the first lower ejector rod 9 form a coaxial jacking structure. The floating die lifting elastic element 10 is arranged in the lower cavity die 8 to enable the lower cavity die 8 to float from the lower cavity die pressure bearing cushion block 11, on one hand, the floating die lifting elastic element is used for matching with a lower cavity die shaft neck to accurately position a blank, the blank is ensured to be uniformly distributed in the tooth form of the upper tooth die cavity during rough forging, the deformation of the gear after residual stress is eliminated is reduced, and the tooth form precision is improved; on the other hand, the utilization rate of the blank is improved during rough forging.

Specifically, the floating die lifting elastic element 10 is arranged between the lower cavity die 8 and the first lower pressure-bearing cushion block 13, the upper end face of the floating die lifting elastic element 10 abuts against the lower end face of the lower cavity die 8, and the lower end face of the floating die lifting elastic element 10 abuts against the upper end face of the first lower pressure-bearing cushion block 13. The floating die lifting elastic element 10 at least has a first compression state and a second compression state between the lower cavity die 8 and the first lower pressure bearing cushion block 13, and the first compression state is that the floating die lifting elastic element 10 supports the lower end surface of the lower cavity die 8 to be spaced from the upper end surface of the lower cavity die pressure bearing cushion block 11, namely, the floating die lifting elastic element floats above the lower cavity die pressure bearing cushion block 11; in the second compression state, the floating mold lifting elastic element 10 is compressed until the lower end surface of the lower cavity mold 8 abuts against the upper end surface of the lower cavity mold pressure bearing cushion block 11, and the first lower ejector rod 9 partially extends into the cavity of the lower concave mold. When the die is closed, the floating die lifting elastic element 10 is compressed under the pressure of the upper tooth die 1, the floating die lifting elastic element 10 is in a second compression state, the end part of the first lower ejector rod 9 close to the first upper die is contacted with the blank in the lower concave die cavity, and a concave structure towards the inner part of the tooth blank is forged on the end face of the shaft neck of the tooth blank during forming.

Meanwhile, in the upper tooth die 1, when the die is closed, and the first upper knockout elastic element 6 is in the second state, the end part of the first upper knockout ejector rod 2 close to the first lower die also partially extends into the upper tooth die cavity to be contacted with the blank, and a concave structure facing the inside of the tooth blank is forged on the tooth-shaped end surface of the formed tooth blank. The concave structures at the two ends of the gear blank can further improve the material utilization rate by 3 percent on the basis of the existing blank utilization rate.

During rough forging, the first guide cylinder 7 is arranged on the outer circumference of the upper tooth die 1, so that the lower cavity die 8 can be accurately guided during die assembly, the central axes of the upper tooth die 1 and the lower cavity die 8 are overlapped, the quantity of staggered dies between the upper die and the lower die is controlled within 0.3mm, prestress is provided for the upper tooth die 1, and the problems of tooth profile accuracy ultra-difference and flash caused by tooth profile deformation of the upper tooth die 1 due to three-direction compressive stress are solved.

Referring to fig. 8 and 9, the second upper die further includes a second upper knockout pin 16, an upper cavity die pressure-bearing cushion block 17, a second upper transition cushion block 18, a second upper pressure-bearing cushion block 19, and a second upper knockout elastic element 20, wherein an upper cavity die cavity with a downward opening is arranged in the middle of the lower end surface of the upper cavity die 15, and a part of the upper cavity die cavity protrudes downward from the lower end surface of the upper cavity die 15 to form an upper cavity die outer circle guide portion. The second upper knockout pin 16 is vertically arranged in the inner holes of the upper cavity die 15 and the upper cavity die pressure-bearing cushion block 17 and is supported on a second upper transition cushion block 18 movably arranged in the inner holes of the upper cavity die pressure-bearing cushion block 17 and a second upper pressure-bearing cushion block 19; the second upper transition cushion block 18 is a step shaft, and the step surface of the second upper transition cushion block 18 is supported on the upper end surface of the upper cavity die pressure-bearing cushion block 17. The second upper knockout elastic element 20 is vertically arranged in an inner hole of the second upper pressure-bearing cushion block 19, the lower end surface of the second upper knockout elastic element 20 is abutted against the upper end surface of the second upper transition cushion block 18, and the second upper knockout elastic element 20, the second upper transition cushion block 18 and the second upper knockout ejector rod 16 form a coaxial ejector structure.

In order to ensure that the second upper knockout pin 16 can rapidly separate the formed gear from the upper cavity die 15 during demolding, the second upper knockout elastic element 20 at least has a third state and a fourth state in an inner hole of the second upper pressure bearing cushion block 19; in the third state, the second upper knockout elastic element 20 supports the step surface of the second upper transition cushion block 18 to be abutted against the upper end surface of the upper cavity die pressure-bearing cushion block 17, and the second upper knockout ejector rod 16 partially extends into the upper cavity of the female die; in the fourth state, the second upper knockout elastic element 20 is in a compressed state, and the step surface of the second upper transition cushion block 18 is spaced from the upper end surface of the upper cavity die pressure-bearing cushion block 17.

Similar to the rough forging process, initially, the second upper knockout elastic element 20 is in a third state, and is extruded by the blank in the cavity of the upper female die during die assembly, and the second upper knockout ejector rod 16 compresses the second upper knockout elastic element 20 upwards through the second upper transition cushion block 18, so that pre-tightening energy storage of the second upper knockout elastic element 20 is realized; when demoulding, the upper cavity die 15 returns upwards immediately after the slide block of the electric screw press reaches the lower dead point, the second upper knockout elastic element 20 automatically recovers deformation without hydraulic start, energy storage is rapidly released, the second upper knockout elastic element 20 pushes the second upper knockout ejector rod 16 downwards through the second upper transition cushion block 18 until part of the second upper knockout ejector rod extends into the upper concave die cavity, and the second upper knockout ejector rod 16 pushes out the gear obtained by precision forging to separate from the upper cavity die 15.

As shown in fig. 10, the second lower die further includes a second lower ejector rod 22, a lower tooth die pressure-bearing cushion block 23, a second lower transition cushion block 24, a second lower pressure-bearing cushion block 25, and a second lower ejector rod 26, wherein the lower tooth die 21 is adapted to the upper cavity die 15, an upper end surface of the lower tooth die 21 is provided with a lower tooth die cavity with an upward opening, and an outer circumference of the lower tooth die 21 is sleeved with a second guide cylinder 27; the upper end surface of the second guide cylinder 27 upwards protrudes out of the upper end surface of the lower tooth die 21, and the inner hole of the second guide cylinder 27 is matched with the outer circumference of the excircle guide part of the upper cavity die. The second lower ejector rod 22 is vertically arranged in inner holes of the lower tooth die 21 and the lower tooth die pressure-bearing cushion block 23, the second lower ejector rod 22 is supported by a second lower transition cushion block 24 movably arranged in the inner hole of the lower tooth die pressure-bearing cushion block 23, and part of the second lower ejector rod 22 extends into the lower tooth die cavity; the second lower transition cushion block 24 is arranged as a vertical cylindrical shaft, and the lower end surface of the cylindrical shaft is supported on the upper end surface of the second lower pressure bearing cushion block 25. The second lower ejector rod 26 is vertically arranged in an inner hole of the second lower pressure bearing cushion block 25, the upper end face of the second lower ejector rod 26 abuts against the lower end face of the second lower transition cushion block 24, and the second lower ejector rod 26, the second lower transition cushion block 24 and the second lower ejector rod 22 form a coaxial jacking structure.

The second guide cylinder 27 achieves the same technical effect as that during rough forging, and guides and provides prestress, and specifically, the second guide cylinder 27 on the outer circumference of the lower tooth die 21 is matched with the guide part on the outer circumference of the upper cavity die during die assembly to accurately guide the upper cavity die 15, so that the central axes of the upper cavity die 15 and the lower tooth die 21 are ensured to be superposed, the quantity of staggered dies between the finish forging upper die and the finish forging lower die is controlled within 0.3mm, the prestress is provided for the lower tooth die 21, the problem of tooth profile accuracy reduction caused by tooth profile deformation of the tooth die under a three-dimensional compressive stress state of the lower tooth die is avoided, and tooth die loss is reduced. In the embodiment, in order to improve the consistency of tooth profile precision during finish forging and prolong the service life of a finish forging die, the exhaust holes are arranged on the excircle guide part of the upper cavity die, so that the uniform distribution of a lubricant on the tooth surface of the upper tooth model cavity is ensured, and the service life of the finish forging die is increased by over 68.75 percent.

In the embodiment, in order to ensure that the first guide cylinder 7 and the second guide cylinder 27 have sufficient rigidity to guide the cavity die and provide prestress, the first guide cylinder 7 and the second guide cylinder 27 are made of H13 die steel with the hardness of HRC44-HRC48, the upper end face of the first guide cylinder 7 abuts against the lower end face of the upper tooth die pressure-bearing cushion block 3, the lower end face of the second guide cylinder 27 abuts against the upper end face of the lower tooth die pressure-bearing cushion block 23, the first guide cylinder 7 is in interference fit with the upper tooth die 1, the second guide cylinder 27 is in interference fit with the lower tooth die 21, and the interference coefficient is kept to be 4-6 per thousand optimally. Meanwhile, in order to ensure the implementation effect of the first guide cylinder 7 and the second guide cylinder 27, the height difference between the lower end surface of the first guide cylinder 7 and the lower end surface of the upper tooth die 1 in the vertical direction is defined as H1, the height difference between the upper end surface of the second guide cylinder 27 and the upper end surface of the lower tooth die 21 in the vertical direction is defined as H2, and the height of the excircle guide part of the upper cavity die protruding out of the lower end surface of the upper cavity die 15 is defined as H3, so that H3 is H2, H2 is more than or equal to 23mm, and H1 is more than or equal to 40 mm; if the lower cavity die 8 does not contact the blank at the upper tooth die 1, the whole outer circumference enters the interior of the first guide cylinder 7 by more than 5 mm.

Further combining with the embodiment shown in fig. 1, the lower cavity die pressure-bearing cushion block 11 is further provided with a plurality of through holes penetrating through the upper and lower end faces of the lower cavity die pressure-bearing cushion block 11, the through holes are uniformly arranged along the circumference of the inner hole of the lower cavity die pressure-bearing cushion block, and the floating die-lifting elastic element 10 is arranged in the through holes and is provided as a spring. In the embodiment shown in the attached drawings, 4 through holes are arranged on the periphery of an inner hole of the lower cavity die pressure bearing cushion block, the springs are rectangular springs with the model of SG25X12.5X125, the 4 rectangular springs are uniformly distributed in the through holes in a combined mode, the compression stroke of the rectangular springs is preset to be 10mm, and the floating height of the lower cavity die 8 on the upper end face of the lower cavity die pressure bearing cushion block 11 is not more than 10 mm.

In order to reduce the axial space occupied by the upper knockout elastic element arranged in the upper die, the first upper knockout elastic element 6 is set to be a first nitrogen spring, the second upper knockout elastic element 20 is set to be a second nitrogen spring, and the models of the nitrogen springs are U4700-16. Meanwhile, the requirement of the nitrogen spring on the temperature of the use environment is high, the normal use temperature of the nitrogen spring is in the range of 0-40 ℃, otherwise, the early failure of a nitrogen spring sealing element can be caused, the normal service life of the nitrogen spring is reduced, and the continuity of automatic line production is affected, so in order to ensure the stability of the temperature of the work environment of the nitrogen spring, in the embodiment, the first cooling mechanism is arranged in the first upper pressure bearing cushion block 5, the second cooling mechanism is arranged in the second upper pressure bearing cushion block 19, and the nitrogen spring is adjusted to the normal work temperature, as shown in fig. 4 and 9. The cooling mechanism can be realized by combining a temperature thermocouple and a cooling circulation channel, for example, the lower limit temperature of the temperature thermocouple is set to be 10 ℃, the upper limit temperature of the temperature thermocouple is set to be 30 ℃, signals are transmitted to a control center PLC through the temperature thermocouple, and a PLC instruction switch introduces compressed air into the cooling circulation channel to ensure that the nitrogen spring works within the specified environment temperature.

The warm forging precision forming die for the straight bevel gear changes the damage form of a rough forging die and a finish forging die into normal wear failure by adopting the modes of adjusting die composition, automatically beating materials on an upper die, accurately positioning blanks, arranging a prestress guide mechanism and the like, obviously prolongs the service life of the rough forging die and the finish forging die, and improves the tooth profile precision and the blank utilization rate.

Although the present invention has been described with reference to the preferred embodiments, it is not intended to be limited thereto. Those skilled in the art can make various changes and modifications without departing from the spirit and scope of the invention. Therefore, the protection scope of the present invention should be determined by the appended claims.

Claims (10)

1. A warm forging precision forming die for a straight bevel gear comprises a rough forging die and a finish forging die which are formed by an electric screw press automatic line, wherein the rough forging die and the finish forging die are defined to be divided into a first upper die and a first lower die by taking a die cavity parting surface in the rough forging die as a boundary, and the finish forging die is defined to be divided into a second upper die and a second lower die by taking the die cavity parting surface in the finish forging die as a boundary; the first upper die comprises an upper tooth die, a first upper knockout ejector rod, an upper tooth die pressure-bearing cushion block, a first upper transition cushion block, a first upper pressure-bearing cushion block, a first upper knockout elastic element and a first guide cylinder;

the lower end surface of the upper tooth mold is provided with an upper tooth mold cavity with a downward opening, the outer circumference of the upper tooth mold is sleeved with a first guide cylinder, and the lower end surface of the first guide cylinder protrudes downwards out of the lower end surface of the upper tooth mold; the first upper knockout mandril is vertically arranged in the inner holes of the upper tooth die and the upper tooth die pressure-bearing cushion block and is supported by a first upper transition cushion block movably arranged in the upper tooth die pressure-bearing cushion block and the inner hole of the first upper pressure-bearing cushion block; the first upper transition cushion block is a step shaft, and the step surface of the first upper transition cushion block is supported on the upper end surface of the pressure-bearing cushion block of the upper tooth mold; the first upper knockout elastic element is vertically arranged in an inner hole of the first upper pressure-bearing cushion block, the lower end face of the first upper knockout elastic element is abutted against the upper end face of the first upper transition cushion block, and the first upper knockout elastic element, the first upper transition cushion block and the first upper knockout ejector rod form a coaxial jacking structure;

the first upper knockout elastic element at least has a first state and a second state in an inner hole of the first upper pressure-bearing cushion block; in the first state, the first upper knockout elastic element supports the step surface of the first upper transition cushion block to abut against the upper end surface of the upper tooth die pressure-bearing cushion block, and the first upper knockout ejector rod partially extends into the upper tooth die cavity; the second state is that the first upper knockout elastic element is in a compressed state, and the step surface of the first upper transition cushion block is spaced from the upper end surface of the upper tooth die pressure-bearing cushion block;

the first lower die comprises a lower cavity die, a first lower ejector rod, a floating die lifting elastic element, a lower cavity die pressure-bearing cushion block, a first lower transition cushion block, a first lower pressure-bearing cushion block and a first lower ejector rod;

the upper end surface of the lower cavity die is provided with a lower cavity die with an upward opening, the lower cavity die is matched with the upper tooth die, and the outer circumference of the lower cavity die is matched with the inner hole of the first guide cylinder; an inner hole is formed in the middle of the lower cavity die pressure-bearing cushion block, the first lower ejector rod is vertically arranged in the lower cavity die and the inner hole of the lower cavity die pressure-bearing cushion block, and the first lower ejector rod is supported by a first lower transition cushion block movably arranged in the inner hole of the lower cavity die pressure-bearing cushion block; the first lower transition cushion block is arranged as a vertical cylindrical shaft, and the lower end surface of the cylindrical shaft is supported on the upper end surface of the first lower pressure bearing cushion block; the first lower ejector rod is vertically arranged in an inner hole of the first lower pressure bearing cushion block, the upper end face of the first lower ejector rod is abutted against the lower end face of the first lower transition cushion block, and the first lower ejector rod, the first lower transition cushion block and the first lower ejector rod form a coaxial jacking structure;

the floating die lifting elastic element is arranged between the lower cavity die and the first lower pressure-bearing cushion block, the upper end face of the floating die lifting elastic element abuts against the lower end face of the lower cavity die, and the lower end face of the floating die lifting elastic element abuts against the upper end face of the first lower pressure-bearing cushion block; the floating die lifting elastic element at least has a first compression state and a second compression state between the lower cavity die and the first lower pressure bearing cushion block, the first compression state is that the floating die lifting elastic element supports the lower end surface of the lower cavity die to be spaced from the upper end surface of the lower cavity die pressure bearing cushion block, the second compression state is that the floating die lifting elastic element is compressed until the lower end surface of the lower cavity die is abutted against the upper end surface of the lower cavity die pressure bearing cushion block, and the first lower ejector rod part extends into the lower cavity die;

the second upper die comprises an upper cavity die, the second lower die comprises a lower tooth die, and the lower tooth die is matched with the upper cavity die.

2. The warm-forging precision forming die for the bevel straight bevel gear according to claim 1, wherein the height difference between the lower end surface of the first guide cylinder and the lower end surface of the upper tooth die in the vertical direction is defined as H1, and H1 is more than or equal to 40 mm.

3. The warm-forging precision forming die for the bevel straight bevel gear according to claim 1, wherein the second upper die further comprises a second upper knockout mandril, an upper cavity die pressure-bearing cushion block, a second upper transition cushion block, a second upper pressure-bearing cushion block and a second upper knockout elastic element;

an upper female die cavity with a downward opening is arranged in the middle of the lower end surface of the upper cavity die, and the upper female die cavity partially protrudes downwards from the lower end surface of the upper cavity die to form an excircle guide part of the upper cavity die; the second upper knockout pin is vertically arranged in the inner holes of the upper cavity die and the upper cavity die pressure-bearing cushion block and is supported by a second upper transition cushion block movably arranged in the upper cavity die pressure-bearing cushion block and the inner hole of the second upper pressure-bearing cushion block; the second upper transition cushion block is a step shaft, and the step surface of the second upper transition cushion block is supported on the upper end surface of the upper cavity die pressure-bearing cushion block; the second upper knockout elastic element is vertically arranged in an inner hole of the second upper pressure-bearing cushion block, the lower end face of the second upper knockout elastic element is abutted against the upper end face of the second upper transition cushion block, and the second upper knockout elastic element, the second upper transition cushion block and the second upper knockout ejector rod form a coaxial jacking structure;

the second upper knockout elastic element at least has a third state and a fourth state in an inner hole of the second upper pressure-bearing cushion block; in the third state, the second upper knockout elastic element supports the step surface of the second upper transition cushion block to abut against the upper end surface of the upper cavity die pressure-bearing cushion block, and the second upper knockout ejector rod partially extends into the upper concave die cavity; the fourth state is that the second upper knockout elastic element is in a compressed state, and the step surface of the second upper transition cushion block is spaced from the upper end surface of the upper cavity die pressure-bearing cushion block;

the second lower die also comprises a second lower ejector rod, a lower tooth die pressure-bearing cushion block, a second lower transition cushion block, a second lower pressure-bearing cushion block and a second lower ejector rod; the upper end surface of the lower tooth die is provided with a lower tooth die cavity with an upward opening, and the outer circumference of the lower tooth die is sleeved with a second guide cylinder; the upper end surface of the second guide cylinder upwards protrudes out of the upper end surface of the lower tooth mold, and an inner hole of the second guide cylinder is matched with the outer circumference of the excircle guide part of the upper cavity mold; the second lower ejector rod is vertically arranged in the inner holes of the lower tooth die and the lower tooth die pressure-bearing cushion block, and is supported by a second lower transition cushion block movably arranged in the inner hole of the lower tooth die pressure-bearing cushion block, and part of the second lower ejector rod extends into the lower tooth die cavity; the second lower transition cushion block is arranged as a vertical cylindrical shaft, and the lower end surface of the cylindrical shaft is supported on the upper end surface of the second lower pressure bearing cushion block; the second lower ejector rod is vertically arranged in a second lower pressure bearing cushion block inner hole, the upper end face of the second lower ejector rod abuts against the lower end face of the second lower transition cushion block, and the second lower ejector rod, the second lower transition cushion block and the second lower ejector rod form a coaxial jacking structure.

4. The warm-forging precision forming die for the bevel straight bevel gear according to claim 3, wherein the height difference between the upper end surface of the second guide cylinder and the upper end surface of the lower tooth die in the vertical direction is defined as H2, and the height of the outer circle guide part of the upper cavity die protruding out of the lower end surface of the upper cavity die is defined as H3, so that H3 is H2, and H3 is more than or equal to 23 mm.

5. The warm-forging precision forming die for the bevel straight bevel gear according to claim 3, wherein the outer circle guide part of the upper cavity die is provided with exhaust holes.

6. The warm-forging precision forming die for the bevel straight gear according to claim 3, wherein the upper end surface of the first guide cylinder abuts against the lower end surface of the pressure-bearing cushion block of the upper tooth die, the lower end surface of the second guide cylinder abuts against the upper end surface of the pressure-bearing cushion block of the lower tooth die, and the first guide cylinder is in interference fit with the upper tooth die and the second guide cylinder is in interference fit with the lower tooth die.

7. The bevel straight bevel gear warm forging precision forming die of claim 1, wherein the lower cavity die bearing cushion block is further provided with a plurality of through holes penetrating through the upper end surface and the lower end surface of the lower cavity die bearing cushion block, and the through holes are uniformly arranged along the circumference of an inner hole of the lower cavity die bearing cushion block; the floating die lifting elastic element is arranged in the through hole and is provided with a spring.

8. The warm-forging precision forming die for the bevel straight bevel gear according to claim 6, wherein the first guide cylinder and the second guide cylinder are made of H13 die steel.

9. The warm-forging precision forming die for the bevel straight bevel gear according to claim 3, wherein the first upper knockout elastic element is provided as a first nitrogen spring, and the second upper knockout elastic element is provided as a second nitrogen spring.

10. The warm-forging precision forming die for the bevel straight bevel gear according to claim 9, wherein a first cooling mechanism is arranged in the first upper pressure-bearing cushion block, and a second cooling mechanism is arranged in the second upper pressure-bearing cushion block.

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