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Computer gong processing anti collision

CNC machining simulation system can reduce or even completely eliminate the process of trial cutting and manual verification. Before the new NC machining program is actually processed, the programmer can use the NC machining simulation system to carry out virtual machining environment and processing process on the computer, and detect the possible problems in the program design.

In the process of NC machining, it is easy to appear over cutting, undercutting and other phenomena. At the same time, the damage of cutting tools, or the processing of waste products, the interference and collision between parts and tools, tools and fixtures, tools and worktables, will cause a certain cost waste. Computer gong processing and numerical control machining simulation system can well simulate the relevant program, reduce the loss to the greatest extent.

Before the actual machining, the programmer can confirm whether the finished cutting product is consistent with the original design drawing through the simulation system, and can make better detailed analysis.

collision detection

In the actual processing, five axis CNC machining has more advantages than three axis CNC machining, can achieve a wider range, has faster material and efficiency, can reduce processing time and improve surface accuracy. However, due to the high degree of freedom of the two additional rotating axes, it is easy to cause collision and damage to the machine tool.

Therefore, before the actual processing, it is necessary to detect the collision with the help of NC machining simulation system. The main detection algorithms are as follows:

The machine tool includes many parts, but the collision detection algorithm between different parts is similar. The simulation system takes the tool, workpiece and fixture as the main research object to detect the possible global collision.

According to the tool location, the grid voxel model of the tool head scanning body and the grid voxel model of the tool holder scanning body are solved respectively. The tool holder scanning body is used to detect whether there is a global collision between the tool, workpiece and fixture, and the tool head scanning body is used to calculate the intersection between the tool and the workpiece.
A feature attribute of voxel model is cuboid envelope box. The envelope box is used for rough judgment. If the envelope box does not intersect, the objects enclosed in the envelope box must not intersect. At this time, the position data information of the object envelope box is updated, and other information remains unchanged. Computer processing is used to prepare for the generation and collision detection of the next tool location scanner It can speed up the detection.
Once a collision occurs, the system stops reading data and reports the error message and the precise location of the collision.

Computer gong processing instructions

CNC machining of milling machine is carried out according to the instruction given by digital style. Under normal environment, the labor process does not need manual interference, and the computer gong processing eliminates the man-made deviation of the dominator. When planning to manufacture CNC machine tools, many methods are adopted to make the machine parts of CNC machine tools reach higher accuracy and stiffness. The movement equivalent of CNC machine tool worktable is widely up to 0.01 ~ 0.0001 mm, and the reverse clearance of feed drive chain and screw pitch deviation can be compensated by CNC device. The high-grade CNC machine tool adopts the closed-loop control of working table movement with grating ruler. The machining accuracy of the computer gong machine tool has improved from ± 0.01 mm to ± 0.005 mm or even higher. The positioning accuracy has reached ± 0.002mm to ± 0.005mm in the early 1990s. In addition, the transmission system and layout of CNC machine tools have high stiffness and thermal stability. Computer gongs processing decision compensation skills, CNC machine tools can get higher precision than its own. In particular, it improves the generality of the production of unified batch parts, with high qualified rate and stable processing quality. The selection of milling cutter diameter depends on different products and production batches. The selection of cutter diameter mainly depends on the specification of equipment and the processing size of workpiece.

Plane milling cutter

When selecting the diameter of the plane milling cutter, the power required by the cutter should be within the power range of the machine tool, and the diameter of the spindle of the machine tool can also be used as the basis for selection. The diameter of plane milling cutter for computer gong processing can be selected as d = 1.5D (D is the diameter of the spindle). In mass production, the tool diameter can also be selected according to 1.6 times of the cutting width of the workpiece.

end mill

The selection of end mill diameter should mainly consider the requirements of workpiece processing size, and ensure that the power required by the cutter is within the rated power range of the machine tool. If it is a small diameter end mill, whether the highest speed of the machine tool can reach the minimum cutting speed (60m / min) should be mainly considered.

Slot milling cutter

The diameter and width of the groove milling cutter should be selected according to the size of the workpiece to be processed, and the cutting power should be within the allowable power range of the machine tool. Before using the CNC machine tool, you should carefully read the machine tool manual and other relevant information, so as to correctly operate and use the machine tool, and pay attention to the following points:

(1) The PLC program of the machine tool is designed by the machine tool manufacturer according to the needs of the machine tool and does not need to be modified. Incorrect modification may cause damage to the machine tool and even damage the operator;

(2) It is suggested that the machine tool can be operated continuously for up to 24 hours. If the continuous operation time is too long, the service life of the electrical system and some mechanical components will be affected, thus affecting the accuracy of the machine tool

(3) The operators and maintenance personnel of machine tools must be professionals who have mastered the corresponding professional knowledge of machine tools or have received technical training, and must operate the machine tools according to the safety operation rules and regulations

Computer gong processing button

CNC machining center power supply has three conditions: the first point, the source on button closed. Second, the power off button is closed. Third, the external alarm contact is opened.

The alarm light of power supply unit of CNC machining center is on: the fuse of 24 V output voltage is fused, and + 24 V voltage is used on 1.9 “display screen, as shown in the figure below. Check whether + 24 V is short circuited to the ground. 2. The display / manual data input board is poor. During the use of the center, the tool imbalance may occur. If not adjusted in time, it will affect the processing effect. Therefore, we should always pay attention to the tool balance of CNC machining center. What are the main reasons for the imbalance of the handle?

The main reason for CNC machining is that the tool design is asymmetric, there are defects in the tool body, and all the adjustment of the tool. The correct balance of the tool can significantly reduce noise and vibration, which increases the tool life and improves the accuracy consistency of parts.

The centrifugal force of CNC machining center is proportional to the square of velocity to amplify the vibration caused by unbalance. The vibration increase of NC machining center caused by this will minimize the life of bearing bush, bearing, shaft, spindle and gear.

Before balancing the tool in CNC machining center, it is necessary to measure the unbalance and the angle position of each selected correction plane. These variables are measured on two general types of balancing machines: non rotating or gravity machines are used to measure single plane unbalance, while rotary or centrifuge is used to measure single plane or two plane unbalance.

After measuring the magnitude and angle of the unbalance in the correct plane, you can correct it by adding or removing material from the workpiece. For the components which are not tools, the most widely used material adding method of drilling center is welding counterweight on the components.

CNC machining (CNC machining) refers to the processing with CNC machining tools. CNC index controlled machine tool is programmed by NC machining language, usually G code. NC machining G code language tells CNC machine tool which Cartesian position coordinates, and controls the tool feed speed and spindle speed, as well as tool converter, coolant and other functions. Compared with manual machining, CNC machining has great advantages, such as the parts produced by CNC machining are very accurate and repeatable; CNC machining can produce parts with complex shapes that cannot be completed by manual processing. CNC machining technology has been widely promoted, most of the machining workshops have the ability of NC machining. The most common NC machining methods in typical machining workshops are CNC milling, CNC lathe and CNC EDM wire cutting (WEDM). The tool for NC milling is called CNC milling machine or CNC machining center. CNC turning lathe is called CNC lathe center. NC machining G code can be manually programmed, but usually the machining workshop uses CAM software to automatically read CAD file and generate G code program to control NC machine tool.

Positioning datum of computer gong processing

When there is a large plane on the part that can be used as the positioning reference, the plane is always processed first, and then the hole is positioned by the plane to ensure the position accuracy between the hole and the plane. In this way, the positioning is relatively stable, the clamping is convenient, and the deflection caused by the drilling on the rough surface can be avoided.

c) The principle of “first primary and then secondary” is to process the main surface (datum plane and working surface with high position accuracy requirements) before processing the secondary surface (such as keyway, screw hole, fastening hole, etc.). The secondary surface is generally after the main surface reaches a certain precision and before the final finishing.

d) According to the principle of “first rough and then fine”, for parts with high precision requirements, it is carried out in order from coarse to fine, so as to gradually improve the machining accuracy. High speed computer gongs processing this point for poor rigidity parts, especially can not be ignored. In order to solve such problems, the characteristics of titanium alloy materials, machining characteristics, tool data selection, milling processing characteristics, coolant and other aspects are analyzed to improve the one-time acceptance rate of titanium alloy parts, so as to control the product quality of the parts. In order to better control the product quality, it is necessary to control the cutting parameters of non-standard equipment parts and understand and master the processing characteristics of materials.

Mechanical processing technology is to change the shape, size, relative position and nature of the production object on the basis of the process. CNC processing makes it a finished product or semi-finished product. It is a detailed description of each process. For example, as mentioned above, rough machining may include blank manufacturing, grinding, etc., and finishing may be divided into turning, fitter, milling machine, etc., and each step is just like this There must be detailed data, such as how much roughness and tolerance should be achieved.

The classification of machining is as follows:

Design datum: the datum used to determine the position of other points, lines and planes on the part drawing, which is called design datum.

Process datum: the datum used in the process of machining and assembling parts, which is called process datum. According to different uses, the process datum of die and mould can be divided into assembly datum, measuring datum and locating datum.

(1) Assembly datum: the datum used to determine the position of parts in parts or products during assembly, which is called assembly datum.

(2) Measurement datum: the datum used to check the size and position of machined surface, which is called measuring datum.

(3) Positioning datum: the datum used for workpiece positioning during machining, which is called positioning datum. For the surface (or line, point) as positioning reference, only the rough surface can be selected in the first working procedure. This positioning surface is called rough datum. The machined surface can be used as the positioning datum in the following processes, and the positioning surface is called the precise datum.

The correct use and maintenance of equipment parts processing mold is also a major factor to improve the quality of mold. Mechanical parts processing, such as: large CNC processing mold device debugging mode should be appropriate, in the case of hot runner, the power wiring should be correct, the cooling water circuit should meet the design requirements, and the parameters of injection molding machine, die-casting machine and press machine should be consistent with the design requirements. In order to improve the surface wear resistance of the die parts and improve the quality of the die, the surface strengthening of the main parts of the die is carried out in the precision parts processing. For the surface strengthening, different strengthening methods should be selected according to the mold for different purposes.

Fire prevention in mechanical parts processing plant

(1) The large-scale machining workshop shall be of grade I and II fire-resistant rating, and other simple buildings shall not be built in the workshop.

(2) For used oil rags, oil cotton yarn and oil sawdust. CNC processing should be concentrated in the metal cylinder (box) with cover and processed every day.

(3) It is forbidden to use gasoline, alcohol and other wiping machine tools in the workshop. The residual oil after washing parts shall not be poured into the sewer or trench at will, but shall be poured into the container at the designated place for unified treatment.

(4) Gasoline shall not be stored in the workshop. The storage capacity of machine oil and kerosene should not exceed one day’s consumption. CNC processing and storage in covered iron drums. If the storage capacity is large, a special oil storage room should be set up. No other combustible materials shall be stored in the oil storage room, and the indoor ventilation shall be maintained. The electrical switch shall be installed in the outdoor distribution box.

(5) In the workshop, due to careless use of the stove for heating, using waste oil cotton yarn to light a fire, throwing cigarette butts, match sticks and so on, fires are often caused. Therefore, strict management should be carried out on site smoking and stove heating.

(6) If it is necessary to carry out open flame welding and cutting in the workshop, the surrounding environment should be checked first, combustible materials should be removed, and the nearby machine tools should be covered with refractory materials. At the same time. Special person must be assigned to be responsible for monitoring, and residual fire should be checked and eliminated after operation.

(7) The electrical equipment of the machine tool must be checked frequently, and the hidden danger should be eliminated in time. It is not allowed to run with a fault. CNC processing, installation, removal, maintenance, debugging must be operated by professional electricians according to the regulations. The metal shell of all electrical equipment shall be reliably grounded, and its grounding resistance shall not be greater than 4 Ω.

CNC cutting mode

The influence of vibration of cutter teeth on the surface roughness and tool life. In order to prevent the decline of machining accuracy and tool life, the selected machining center must be equipped with a spindle with excellent dynamic balance performance, and the selected boring tool must also have high dynamic balance characteristics. Especially for the cutter tooth part of boring tools, the geometry, tool material and clamping mode suitable for high-speed cutting should be selected. In order to improve the machining efficiency, the feed rate should be increased on the premise of obtaining the same surface roughness. However, the increase of feed rate should be enough, otherwise it will increase the cutting resistance, which is not conducive to improving the processing efficiency. The cutting edge should be set with negative chamfering less than 0.1 mm, which can effectively maintain the stability of tool life.

In addition to CNC cutting method for precision machining of holes, boring and reaming can also be used for high-precision machining of holes. With the high-speed spindle of machining center, boring tools can be used for high-speed and precision machining of holes. It is reported that the cutting speed can be increased to more than 1500m / min when the diameter of boring is about 40mm on aluminum alloy. This cutting speed can also be used when using CBN sintered body as cutting edge to process steel, cast iron and high hardness steel. It is predicted that the high speed of boring will be popularized rapidly in the future.

As for the tool material, it depends on the nature of the material being processed. For example, when machining steel below 40HRC, cermet tool can be selected. Under the high-speed cutting condition of V = 300m / min, good surface roughness and long tool life can be obtained. Coated cemented carbide tools are suitable for high-speed cutting of steels below 60HRC. The tool life is very stable, but the cutting speed is slightly lower than cermet tools.

Sintered tool is suitable for machining high hardness steel, cast iron and other materials. The cutting speed can reach more than 1000m / min, and the tool life is very stable. Proper chamfering should be carried out on the cutting edge of CBN cutter teeth in CNC machining, which is very beneficial to stable high-speed cutting and prolonging tool life. In ultra-high speed cutting of nonferrous metals and non-metallic materials such as aluminum alloy, diamond sintered body tool can be selected. This kind of cutting tool is stable and has a long service life. It should be noted that when using diamond tools, the blade belt must be chamfered, which is an important condition to ensure the stability of cutting.

Computer gong processing inverter

The power control equipment of AC motor is controlled by the frequency mode of motor power supply. In CNC machine tools, the frequency converter is mainly used to control the action of the spindle.

The blade of end mounted structure milling cutter (as shown in FIG. 10) is fixed on the cutter groove with only one screw, which is simple in structure and convenient in rotation. Although there are few tool parts in mechanical parts processing plant, it is difficult to process the cutter body. Generally, it needs five coordinate machining center for machining. Since the blade is clamped by cutting force, the clamping force increases with the increase of cutting force, so the clamping element can be omitted and the chip holding space is increased. Because the blade is installed in tangential direction, the section of cemented carbide in the direction of cutting force is large, so it can be used for large cutting depth and large cutting distance. This kind of milling cutter is suitable for heavy and medium milling.

The angle of milling cutter includes front angle, back angle, main deflection angle, auxiliary deflection angle, edge inclination angle, etc. In order to meet the different processing needs, there are a variety of angle combination types. Among the various angles, the main deflection angle and rake angle are the main ones (the main deflection angle and rake angle of the cutter are generally clearly stated in the product samples of the manufacturer).

Main deflection angle KR

The main deflection angle is the angle between the cutting edge and the cutting plane, as shown in FIG. 11. The main deflection angles of milling cutter are 90 °, 88 °, 75 °, 70 °, 60 ° and 45 ° etc.

Principal deflection angle

The main deflection angle has a great influence on the radial cutting force and cutting depth. The size of radial cutting force directly affects the cutting power and anti vibration performance of cutting tools. The smaller the main deflection angle of the milling cutter is, the smaller the radial cutting force is, the better the vibration resistance is, but the cutting depth is also reduced.

The main deflection angle of 90 ° is selected when milling the plane with shoulder, and CNC machining is not generally used for pure plane machining. This kind of tool has good versatility (not only can process step surface, but also can process plane), so it can be selected in single piece and small batch processing. Because the radial cutting force of this kind of cutting tool is equal to the cutting force, the feed resistance is large, and it is easy to vibrate. When machining the plane with shoulder, the milling cutter with 88 ° main deflection angle can also be selected. Compared with the milling cutter with 90 ° main deflection angle, its cutting performance is improved to some extent.

The main deflection angle of 60 ° to 75 ° is suitable for rough machining of plane milling. Due to the obvious reduction of radial cutting force (especially at 60 degrees), its vibration resistance is greatly improved, and the cutting is smooth and light. Therefore, it should be preferred in plane machining. 75 ° main deflection angle milling cutter is a general-purpose tool with wide application range; 60 ° main deflection angle milling cutter is mainly used for rough milling and semi finishing milling on boring and milling machines and machining centers.

The radial cutting force of this kind of milling cutter with 45 ° main deflection angle is greatly reduced, which is approximately equal to the axial cutting force. The cutting load is distributed on the longer cutting edge, and has good vibration resistance. It is suitable for the machining occasions with longer spindle overhang of boring and milling machine. When machining plane with this kind of cutting tool, the damage rate of blade is low and the durability is high; when machining iron castings, the edge of the workpiece is not easy to break.

Anterior angle γ

The rake angle of milling cutter can be divided into radial rake angle γ F and axial rake angle γ P. the radial rake angle γ f mainly affects the cutting power; the axial rake angle γ P affects the chip formation and the direction of axial force. When γ P is positive, the chip will fly away from the machining surface.

Anterior horn

The common combination forms of front angle are as follows:

The milling cutter with double negative rake angle and double negative rake angle usually adopts square (or rectangular) blade without back angle. The cutter has many cutting edges (generally 8), high strength and good impact resistance, which is suitable for rough machining of cast steel and cast iron. Because the chip shrinkage ratio is large, it needs a large cutting force, so the machine tool has higher power and higher rigidity. Because the forward angle of the shaft is negative, the chip can not flow out automatically. When cutting ductile materials, chip accretion and tool vibration are easy to occur.

It is suggested to use double cutting tool with negative rake angle when machining. When double positive rake angle milling cutter is used to produce chipping edge (i.e. large impact load), the double negative rake angle milling cutter should also be preferred when the machine tool allows.

The milling cutter with double positive rake angle and double positive rake angle adopts the blade with back angle, which has small wedge angle and sharp cutting edge. Because of the small shrinkage ratio of the chip, the cutting power consumed is small, and the chip is discharged in a spiral shape, which is not easy to form a chip accumulation lump. This kind of milling cutter is most suitable for cutting soft materials, stainless steel, heat-resistant steel and other materials. For the machine tools with poor rigidity (such as boring and milling machines with long spindle overhanging), low power and machining welded structural parts, double positive rake angle milling cutters should also be preferred.

Positive and negative rake angle (axial positive rake angle, radial negative rake angle) this kind of milling cutter combines the advantages of double positive rake angle and double negative rake angle milling cutter. The axial positive rake angle is conducive to the formation and discharge of chips; the radial negative rake angle can improve the edge strength and impact resistance. This kind of milling cutter has the advantages of smooth cutting, smooth chip removal and high metal removal rate, which is suitable for large allowance milling. Computer gong processing, Dongguan computer gong processing, high speed computer gong processing, mechanical parts processing, computer gong processing, Walter’s tangential tooth distribution heavy cutting milling cutter f2265 is a milling cutter with axial positive rake angle and radial negative rake angle structure.

The number of milling cutter teeth is large, which can improve the production efficiency. However, due to the limitation of chip holding space, cutter tooth strength, machine tool power and rigidity, the number of teeth of milling cutter with different diameters has corresponding regulations. In order to meet the needs of different users, there are three types of milling cutters with the same diameter: coarse teeth, medium teeth and dense teeth.

Rough tooth milling cutter is suitable for large allowance rough machining of ordinary machine tools and milling of soft materials or large cutting width; when the power of machine tool is small, in order to make cutting stable, coarse tooth milling cutter is often used.

The middle gear milling cutter is a universal series, which makes

Shaft processing technology of computer gongs

Input shaft: forging and blank making → normalizing → finishing turning → gear rubbing → drilling → gear shaping → undercut angle → hobbing → shaving → heat treatment → grinding → meshing and finishing.

Output shaft: forging billet → normalizing → finishing turning → rolling gear → shaving → heat treatment → grinding → meshing and finishing.

Specific process flow

(1) Forging billet

Hot die forging is a widely used blank forging process for automobile gear parts. Computer gong processing, Dongguan computer gong processing, high speed computer gong processing, mechanical parts processing, computer gong processing

Hot forging and cold extrusion are widely used in the past. In recent years, cross wedge rolling technology has been widely used in shaft machining. This technology is especially suitable for the production of complex stepped shafts. It not only has high precision, small machining allowance, but also has high production efficiency.

(2) Normalizing

The purpose of this process is to obtain the hardness suitable for subsequent gear cutting and to prepare the microstructure for the final heat treatment, so as to effectively reduce the heat treatment deformation. Due to the influence of personnel, equipment and environment, the normal normalizing can not control the cooling rate and cooling uniformity of workpiece, resulting in large hardness dispersion and uneven microstructure, which directly affects machining and final heat treatment.

(3) Finish turning

In order to meet the positioning requirements of high-precision gear machining, CNC lathe is used for the finish turning of gear blank. First, the inner hole and locating end face of the gear are machined, and then the machining of the other end face and outer diameter is completed synchronously. It not only ensures the perpendicularity requirement between the inner hole and the locating end face, but also ensures the small size dispersion in the mass production of gear blanks. Thus, the accuracy of gear blank is improved and the machining quality of subsequent gear is ensured.

There are mainly three ways of positioning datum and clamping for shaft parts processing

Positioning by the center hole of the workpiece: in the machining of the shaft, the coaxiality of the outer circle surface and end face of the part, and the perpendicularity of the end face to the rotating axis are the main items of their mutual position accuracy. The design basis of these surfaces is generally the center line of the shaft. If two center holes are used for positioning, it is in line with the principle of datum coincidence.

Outer circle and central hole as the positioning reference (one clip and one top): Although the centering accuracy is high, the rigidity is poor, especially when machining heavy workpieces, and the cutting parameters cannot be too large.

In rough machining, in order to improve the rigidity of the parts, the cylindrical surface of the shaft and a central hole can be used as the positioning reference. This positioning method can bear large cutting torque and is the most common positioning method for shaft parts.

Take two cylindrical surfaces as positioning datum: when machining the inner hole of hollow shaft (for example: machining the inner hole of Morse taper on the machine tool), the central hole cannot be used as the positioning reference, and the two outer cylindrical surfaces of the shaft can be used as the positioning reference. When the workpiece is the spindle of machine tool, the two supporting Journal (assembly reference) is often used as the positioning reference, which can ensure the coaxiality requirement of the taper hole relative to the supporting journal, and eliminate the error caused by the non coincidence of the reference.

CNC Machining for the heat sink parts

Our factory is a professional CNC plus factory. The processed parts adapt to various industries. The accessories of the heat sink have been processed for more than ten years in our factory. The heat sink material is aluminum or copper. which is processed by CNC, drilled, tapped, deburred, cleaned, sandblasted, and then surface oxidized.

The principle of the heat sink is to increase the surface area and speed up the heat dissipation. As the material of heat sink is the metal with smaller specific heat, it absorbs heat very quickly, at the same time, the speed of heat loss is also relatively fast, so the effect of rapid heat dissipation is achieved through heat transfer.

For example, CPU of the computer use a heat sink,It can reduce the temperature of CPU and ensure the work of CPU.

For the material of heat sink, the thermal conductivity of each material is different, which is arranged from high to low: silver, copper, aluminum and steel.

However, if silver is used for heat sink, it will be cost too expensive, so the best solution is to use copper. Although aluminum is much cheaper, its thermal conductivity is not as good as copper.

Processing automobile parts with computer gong

With the development of society, gold casting technology has been greatly improved. In the production process, it also reduces the environmental pollution, improves the working environment, improves the production technology and level, which is of great help to the development of the casting industry, so as to promote the development of the automobile industry. The domestic and international markets have more and more stringent requirements on the quality and cost price of automobile forgings, such as draft angle, weight tolerance, size, machining allowance, etc., and the price is not ideal, but the batch is large. In order to meet the needs of the market, this paper analyzes the process and repeated practice, and finds an ideal process, which is of great significance to the production of similar products.

Introduction of products and determination of process plan

The arm body is a part used on the brake pump of a heavy vehicle, and the structure is shown in Fig. 1. There are several difficulties in forging: (1) the draft angle is small, only 3 ° outside and 5 ° inside, while the ejection device only has one place in the ∮ 62 hole; (2) the machining allowance is small, only boring and broaching are used for ∮ 62 and square groove of 23.2mm; (3) 10 – ∮ 6.2 * 5 these 10 nails are difficult to fill, and the location requirements are high, and the root fillet of the nails is r0.2, which makes the die wear faster and easy to bump and cause deformation in the production process.

Determination of process plan

In order to adapt to mass production and improve efficiency, we have determined the following processes: (intermediate frequency furnace) heating / (cross wedge rolling) / (25000kN hot die forging press) bending / pre forging / final forging / (3150kN double point press) punching / trimming / normalizing / shot peening / precision pressing. In the technological process, two pieces at a time are used for heating billet, the handle of the part is long and thin, and the blank making efficiency of single piece by free forging is low. The cross wedge rolling billet (as shown in Fig. 2) is adopted and cut into two pieces on the rolling mill at the same time. Because the cross section of the parts changes greatly, it takes two wedges to complete from ∮ 55 to ∮ 23, so it is difficult to process and repair the rolling die.

In addition to ensuring the size of the head and shank, it is more important to correct the position of the 10 nails, the fillet of the root and the bending of the handle. Therefore, two standard platens with 5 holes are used to ensure the position of nails and the root fillet, and improve the service life of forging die.

Key points of mould design and manufacture

Generally, the bending die design only considers that the shape of the extruded blank is consistent with that of the forging. Due to the large difference in the thickness between the big end and the handle of the arm body, the handle of the bending billet will be suspended when it is put into the pre forging die. During the pre forging, the transition between the handle and the big head will be folded. Due to the suspension of the handle of the bending billet, the metal flow in this part is too large.