Today's machining industry, traditional machining equipment has been unable to meet the quality needs. CNC machine tool equipment replaces ordinary machine tools, and automatic processing equipment such as precision CNC machining and CNC lathe processing replaces traditional machine tools. The following will take you to understand the advantages of CNC machining machine tools and the order of precision mechanical parts processing.

In the process of machining mechanical parts, CNC machining machine tools have the following advantages:

1.CNC machining center has high precision and high processing quality.CNC machine tools are renowned for their exceptional precision and accuracy.  They use computer-controlled movements and specialized software to perform tasks with minimal error margins.  Unlike human operators, CNC machines consistently reproduce identical parts to exact specifications.

2.CNC machining parts can be multi-coordinate linkage, can process complex shape parts.CNC machine tools offer remarkable flexibility and versatility compared to traditional manual machines.  With the ability to change tooling and adapt to various operations quickly, they are ideal for manufacturing complex and intricate components.

3.CNC machining process change, generally only need to change the numerical control program, can save production preparation time.CNC machine tools offer remarkable time-saving benefits.  Traditional manual machining methods are time-consuming and labor-intensive, requiring extensive set-up and constant manual adjustments.  In contrast, CNC machines can be easily programmed to perform complex operations accurately, greatly reducing production lead times.And CNC machining machine tool itself has high precision, large rigidity, can choose a favorable processing amount, high productivity (generally 3 to 5 times of ordinary machine tools).

4.CNC machining belongs to CNC machining equipment, high degree of automation, can reduce labor intensity.Although the initial investment in CNC machine tools may be higher than manual machines, they offer substantial long-term cost savings.  These machines reduce labor costs since they require fewer operators for operation and supervision.  Moreover, CNC machines minimize material wastage by executing precision cuts and reducing human errors, leading to significant material savings.

5.Increased Productivity and Efficiency.One of the most significant advantages of CNC machine tools is their ability to increase productivity and efficiency. These machines can operate around the clock, minimizing production downtime and maximizing output.  Once programmed, they can perform complex tasks with minimal supervision, freeing up manpower for other critical areas of production.

CNC machine tools have ushered in a new era of production efficiency, accuracy, and cost-effectiveness.  With precision, productivity, flexibility, cost savings, time-saving advantages, and the right skillset, businesses can harness the full potential of CNC machines and stay ahead in the competitive manufacturing industry.

Each processing method has its processing sequence. Our operators need to process in accordance with its processing order, but not disorderly, so that it will have a certain impact on the processed products, or quality problems. Precision machining is one of them, then the order of precision mechanical parts processing is divided into what kinds.

The arrangement of fine parts processing should be based on the structure and blank situation of the parts, as well as the needs of positioning clamping, and the focus is on the rigidity of the workpiece is not destroyed.

• The processing of the previous process can not affect the positioning and clamping of the next process, and the processing process of general fine parts in the middle of the cross should also be considered comprehensively;
• Stop the inner cavity processing sequence first, and then stop the outer shape processing process;
• The process of processing with the same positioning, clamping method or the same knife is best connected and stopped to reduce the number of repeated positioning, the number of tool changes and the number of moving platen. Shenzhen Machining;
• In the same device to stop multiple processes, should be arranged first to the workpiece rigid damage process.

Tool concentration sorting method: It is divided into processes according to the tool used, and all the parts that can be completed with the same tool are processed. In the second knife, the third knife to complete the other parts they can complete. This can reduce the number of tool changes, shorten the idle time, reduce unnecessary positioning errors.

Processing parts sorting method: On the processing content of a lot of parts, according to its structural characteristics will be processed local dividends several parts, such as internal shape, shape, surface or plane. Ordinary first processing plane, positioning surface, after processing holes; First processing simple geometric shapes, then processing complex geometric shapes; The parts with lower precision are processed first, and then the parts with higher precision requirements are processed.

In short, the current precision machinery parts processing technology is very advanced, high quality and high production efficiency.

HONSCN Precision has 20 years of cnc machining experience. Specializing in cnc machining, hardware machinery parts processing, automation equipment parts processing. Robot parts processing, UAV parts processing, bicycle parts processing, medical parts processing, etc. It is one of the high-quality suppliers of cnc machining. At present, the company has hundreds of cnc machining centers, grinding machines, milling machines, high-quality high-precision testing equipment, to provide customers with precision and high-quality cnc spare parts processing services.

In the field of machining, after CNC machining process methods and division of processes, the main content of the process route is to rationally arrange these processing methods and processing sequence. In general, CNC machining of mechanical parts includes cutting, heat treatment and auxiliary processes such as surface treatment, cleaning and inspection. The sequence of these processes directly affects the quality, production efficiency and cost of the parts. Therefore, when designing CNC machining routes, the order of cutting, heat treatment and auxiliary processes should be reasonably arranged, and the connection problem between them should be solved.

In addition to the basic steps mentioned above, factors such as material selection, fixture design and equipment selection need to be considered when developing a CNC machining route. Material selection is directly related to the final performance of parts, different materials have different requirements for cutting parameters; The fixture design will affect the stability and accuracy of the parts in the process of processing; Equipment selection needs to determine the type of machine tool suitable for its production needs according to the characteristics of the product.

1, the processing method of precision machinery parts should be determined according to the characteristics of the surface. On the basis of familiar with the characteristics of various processing methods, mastering the processing economy and surface roughness, the method that can ensure the processing quality, production efficiency and economy is selected.

2, select the appropriate drawing positioning reference, according to the principle of crude and fine reference selection to reasonably determine the positioning reference of each process.

3, When developing the machining process route of the parts, it is necessary to divide the rough, semi-fine and finishing stages of the parts on the basis of the analysis of the parts, and determine the degree of concentration and dispersion of the process, and reasonably arrange the processing sequence of the surfaces. For complex parts, several schemes can be considered first, and the most reasonable processing scheme can be selected after comparison and analysis.

4, determine the processing allowance and process size and tolerance of each process.

5, select machine tools and workers, clips, quantities, cutting tools. The selection of mechanical equipment should not only ensure the quality of processing, but also be economical and reasonable. Under the conditions of mass production, general machine tools and special jigs should generally be used.

6, Determine the technical requirements and inspection methods of each major process.Determining the cutting amount and time quota of each process is usually decided by the operator for a single small batch production plant. It is generally not specified in the machining process card. However, in the medium batch and mass production plants, in order to ensure the rationality of production and the balance of rhythm, it is required that the cutting amount must be specified, and must not be changed at will.

First rough and then fine

The processing accuracy is gradually improved according to the order of rough turning - semi-fine turning - fine turning. The rough lathe can remove most of the machining allowance of the workpiece surface in a short time, thereby increasing the metal removal rate and meeting the requirement of the uniformity of the allowance. If the residual amount left after the rough turning does not meet the finishing requirements, it is necessary to arrange a semi-finishing car for finishing. The fine car needs to ensure that the outline of the part is cut according to the drawing size to ensure the processing accuracy.

Approach first and then far

Under normal circumstances, the parts close to the tool should be processed first, and then the parts far away from the tool to the tool should be processed to shorten the moving distance of the tool and reduce the empty travel time. In the process of turning, it is beneficial to maintain the stiffness of the blank or semi-finished product and improve its cutting conditions.

The principle of internal and external intersection

For parts that have both an inner surface (inner cavity) and an outer surface to be processed, when arranging the processing sequence, the inner and outer surfaces should be roughed first, and then the inner and outer surfaces should be finished. Must not be part of the surface of the part (outer surface or inner surface) after processing, then processing other surfaces (inner surface or outer surface).

Base first principle

Priority should be given to the surface used as the finishing reference. This is because the more accurate the surface of the positioning reference, the smaller the clamping error. For example, when machining shaft parts, the center hole is usually machined first, and then the outer surface and end face are machined with the center hole as the precision basis.

The principle of the first and the second

The main working surface and assembly base surface of the parts should be processed first, so as to find out the modern defects on the main surface in the blank early. The secondary surface can be interspersed, placed on the main machined surface to a certain extent, before the final finishing.

The principle of the face before the hole

The plane outline size of the box and bracket parts is large, and the plane is generally processed first, and then the hole and other sizes are processed. This arrangement of processing sequence, on the one hand with the processed plane positioning, stable and reliable; On the other hand, it is easy to process the hole on the machined plane, and can improve the processing accuracy of the hole, especially when drilling, the axis of the hole is not easy to deviate.

When developing the machining process of parts, it is necessary to select the appropriate processing method, machine tool equipment, clamp measuring tools, blank and technical requirements for workers according to the production type of parts.

The success or failure of aerospace operations depends on the accuracy, precision and quality of the components used. For this reason, aerospace companies utilize advanced manufacturing techniques and processes to ensure that their components fully meet their needs. While new manufacturing methods such as 3D printing are rapidly gaining popularity in the industry, traditional manufacturing methods such as machining continue to play a key role in the production of parts and products for aerospace applications. Such as better CAM programs, application-specific machine tools, enhanced materials and coatings, and improved chip control and vibration damping - have significantly changed the way aerospace companies manufacture critical aerospace components. However, sophisticated equipment alone is not enough. Manufacturers must have the expertise to overcome the material processing challenges of the aerospace industry.

The manufacture of aerospace parts first requires specific material requirements. These parts typically require high strength, low density, high thermal stability and corrosion resistance to handle extreme operating conditions.

Common aerospace materials include:

1. High strength aluminum alloy

High-strength aluminum alloys are ideal for aircraft structural parts because of their light weight, corrosion resistance and ease of processing. For example, 7075 aluminum alloy is widely used in the manufacture of aerospace parts.

2. titanium alloy

Titanium alloys have excellent strength to weight ratio and are widely used in aircraft engine parts, fuselage components and screws.

3. Superalloy

Superalloys maintain strength and stability at high temperatures and are suitable for engine nozzles, turbine blades and other high-temperature parts.

4. Composite material

Carbon fiber composites perform well in reducing structural weight, increasing strength and reducing corrosion, and are commonly used in the manufacture of casings for aerospace parts and spacecraft components.

Process planning and design

Process planning and design are required before processing. At this stage, it is necessary to determine the overall processing scheme according to the design requirements of the parts and material characteristics. This includes determining the process of processing, the choice of machine tool equipment, the selection of tools, etc. At the same time, it is necessary to carry out detailed process design, including the determination of cutting profile, cutting depth, cutting speed and other parameters.

Material preparation and cutting process

In the process of aerospace parts processing, the first need to prepare working materials. Usually, the materials used in aviation parts include high-strength alloy steel, stainless steel, aluminum alloy and so on. After the material preparation is completed, the cutting process is entered.

This step involves the selection of machine tools, such as CNC machine tools, lathes, milling machines, etc., as well as the selection of cutting tools. The cutting process needs to strictly control the feed speed, cutting speed, cutting depth and other parameters of the tool to ensure the dimensional accuracy and surface quality of the parts.

Precision machining process

Aerospace components are usually very demanding in terms of size and surface quality, so precision machining is an indispensable step. At this stage, it may be necessary to use high-precision processes such as grinding and EDM. The goal of the precision machining process is to further improve the dimensional accuracy and surface finish of the parts, ensuring their reliability and stability in the aviation field.

Heat treatment

Some aerospace parts may require heat treatment after precision machining. The heat treatment process can improve the hardness, strength and corrosion resistance of the parts. This includes heat treatment methods such as quenching and tempering, which are selected according to the specific requirements of the parts.

Surface coating

In order to improve the wear resistance and corrosion resistance of aviation parts, surface coating is usually required. Coating materials can include cemented carbide, ceramic coating, etc. Surface coatings can not only improve the performance of parts, but also extend their service life.

Assembly and testing

Do parts assembly and inspection. At this stage, the parts need to be assembled in accordance with the design requirements to ensure the accuracy of the match between the various parts. At the same time, rigorous testing is required, including dimensional testing, surface quality testing, material composition testing, etc., to ensure that parts meet aviation industry standards.

Strict quality control: The quality control requirements of aviation parts are very strict, and strict testing and control are required at each processing stage of aviation parts to ensure that the quality of parts meets the standards.

High precision requirements: Aerospace components typically require very high accuracy, including dimensional accuracy, shape accuracy and surface quality. Therefore, high-precision machine tools and tools need to be used in the processing process to ensure that the parts meet the design requirements.

Complex structure design: Aviation parts often have complex structures, and it is necessary to use multi-axis CNC machine tools and other equipment to meet the processing needs of complex structures.

High temperature resistance and high strength: aviation parts usually work in harsh environments such as high temperature and high pressure, so it is necessary to choose high temperature resistance and high strength materials, and carry out the corresponding heat treatment process.

Overall, aerospace parts processing is a highly technology-intensive, precision demanding process that requires strict operating processes and advanced processing equipment to ensure that the quality and performance of the final parts can meet the stringent requirements of the aviation sector.

Aerospace parts processing is challenging, mainly in the following areas:

Complex geometry

Aerospace parts often have complex geometrics that require high-precision machining to meet design requirements.

Super alloy processing

The processing of superalloys is difficult and requires special tools and processes to handle these hard materials.

Large parts

The parts of the spacecraft are usually very large, requiring large CNC machine tools and special processing equipment.

Quality control

The aerospace industry is extremely demanding on part quality and requires rigorous quality control and inspection to ensure that every part meets the standards.

In aerospace parts processing, precision and reliability are key. A deep understanding and fine control of materials, processes, precision and machining difficulties is the key to manufacturing high-quality aerospace parts.

The processing methods of holes include drilling, reaming, reaming, boring, drawing, grinding and finishing of holes. The following small series for you to introduce several hole processing technology in detail, crack the hole processing problems.

The hole is an important surface on the box, bracket, sleeve, ring, and disk parts, and it is also a surface often encountered in machining. In the case of the same processing accuracy and surface roughness requirements, it is difficult to process the hole than the outer round surface, low productivity and high cost.

This is because: 1) the size of the tool used in hole processing is limited by the size of the hole being processed, and the rigidity is poor, which is easy to produce bending deformation and vibration; 2) When machining the hole with a fixed-size tool, the size of the hole processing often directly depends on the corresponding size of the tool, and the manufacturing error and wear of the tool will directly affect the processing accuracy of the hole; 3) When machining holes, the cutting area is inside the workpiece, the chip removal and heat dissipation conditions are poor, and the processing accuracy and surface quality are not easy to control.

Drilling

Drilling is the first process of machining holes on solid materials, and the diameter of the drilling hole is generally less than 80mm. There are two ways of drilling: one is the bit rotation; The other is workpiece rotation. The error generated by the above two drilling methods is not the same, in the drilling method of the bit rotation, due to the asymmetry of the cutting edge and the insufficient rigidity of the bit and the bit deflection, the center line of the hole will be skewed or not straight, but the aperture is basically unchanged; On the contrary, in the drilling method of workpiece rotation, the bit deflection will cause the aperture to change, but the center line of the hole is still straight.

Commonly used drilling knives have: twist drill, center drill, deep hole drill, etc., of which the most commonly used is twist drill, its diameter specification is Φ0.1-80mm.

Due to structural limitations, the bending stiffness and torsional rigidity of the drill bit are low, coupled with poor centering, the drilling accuracy is low, generally only IT13 ~ IT11; The surface roughness is also large, Ra is generally 50~12.5μm; However, the metal removal rate of drilling is large and the cutting efficiency is high. Drilling is mainly used for processing holes with low quality requirements, such as bolt holes, thread bottom holes, oil holes, etc. For holes with high machining accuracy and surface quality requirements, they should be achieved by reaming, reaming, boring or grinding in subsequent processing.

Reaming

Reaming is to further process the hole that has been drilled, cast or forged with a reaming drill to enlarge the aperture and improve the processing quality of the hole. Reaming can be used either as a pre-processing before finishing the hole or as the final processing of the hole with low requirements. Reaming drill is similar to twist drill, but has more teeth and no cross edge.

Compared with drilling, reaming has the following characteristics:

(1) the number of reaming drill teeth (3~8 teeth), good guidance, cutting is relatively stable; (2) reaming drill without cross edge, cutting conditions are good;

(3) The processing allowance is small, the chip sink can be made shallower, the drill core can be made thicker, and the tool body strength and rigidity are better. The precision of reaming is generally IT11~IT10, and the surface roughness Ra is 12.5~6.3μm. Reaming is often used to process holes with smaller diameters. When drilling a large diameter hole (D ≥30mm), often use a small drill bit (diameter of 0.5 to 0.7 times of the aperture) to pre-drill, and then use the corresponding size of the hole reaming drill, which can improve the processing quality and production efficiency of the hole.

In addition to processing cylindrical holes, reaming drills of various special shapes (also known as countersinks) can be used to process various countersunk seat holes and countersinks. The front face of the countersink is often equipped with a guide post, guided by a machined hole.

Reaming is one of the finishing methods of holes, which is widely used in production. For smaller holes, reaming is a more economical and practical machining method than internal grinding and fine boring.

1. Reamer

Reamer is generally divided into two kinds of hand reamer and machine reamer. The handle part of the hand reamer is straight handle, the working part is longer, and the guiding function is better. The hand reamer has two kinds of structures: integral and adjustable outside diameter. The machine reamer has two kinds of structure with handle and sleeve. The reamer can not only process round holes, but also taper reamer can process taper holes.

2. Reaming process and its application

Reaming allowance has a great influence on the quality of reaming, the allowance is too large, the load of the reamer is large, the cutting edge is soon blunted, it is not easy to obtain a smooth machining surface, and the dimensional tolerance is not easy to guarantee; The margin is too small to remove the knife marks left by the previous process, and naturally there is no role in improving the quality of hole processing. Generally, the margin of coarse hinge is 0.35~0.15mm, and the fine hinge is 01.5~0.05mm.

To avoid chip nodules, reaming is usually processed at a lower cutting speed (v <8m/min for steel and cast iron with HSS reamers). The value of feed is related to the aperture to be machined, the larger the aperture, the larger the feed value, the feed rate of high-speed steel reamer processing steel and cast iron is usually 0.3~1mm/r.

Reaming must be cooled, lubricated and cleaned with appropriate cutting fluid to prevent chip buildup and remove chips in time. Compared with grinding and boring, the reaming productivity is higher and the accuracy of the hole is easily guaranteed. However, reaming can not correct the position error of the hole axis, and the position accuracy of the hole should be guaranteed by the previous process. Reaming is not suitable for processing step holes and blind holes.

The dimensional accuracy of reaming is generally IT9 ~ IT7, and the surface roughness Ra is generally 3.2~ 0.8μm. For medium-size holes with high precision requirements (such as IT7 precision holes), the driller - reamer - reamer process is a typical processing scheme commonly used in production.

Boring is a machining method in which the prefabricated hole is enlarged with a cutting tool. The boring work can be carried out either on the boring machine or on the lathe.

1. Boring method

There are three different machining methods for boring.

(1) The workpiece rotates and the tool makes feed movement

Boring on the lathe mostly belongs to this boring method. The characteristics of the process are: the axis line of the hole after processing is consistent with the rotation axis of the workpiece, the roundness of the hole mainly depends on the rotation accuracy of the machine tool spindle, and the axial geometry error of the hole mainly depends on the position accuracy of the tool feed direction relative to the rotation axis of the workpiece. This boring method is suitable for machining holes with coaxial requirements on the surface of the outer circle.

(2) The tool rotates and the workpiece is fed

The boring machine spindle drives the boring tool to rotate, and the table drives the workpiece to feed.

(3) The tool rotates and makes feed motion

Using this kind of boring boring method, the overhanging length of the boring bar is changed, the force deformation of the boring bar is also changed, the aperture near the headstock is large, and the aperture away from the headstock is small, forming a cone hole. In addition, with the increase of the overhang length of the boring bar, the bending deformation of the main shaft caused by its own weight also increases, and the axis of the machined hole will have a corresponding bending. This boring method is only suitable for machining short holes.

2. Diamond boring

Compared with general boring, diamond boring is characterized by a small amount of back cutting, small feed, high cutting speed, it can obtain a high processing accuracy (IT7 ~ IT6) and a very smooth surface (Ra is 0.4~ 0.05μm). Diamond boring was originally processed with diamond boring tools, and is now commonly processed with cemented carbide, CBN and artificial diamond tools. Mainly used for processing non-ferrous metal workpieces, can also be used for processing cast iron and steel parts.

The commonly used cutting parameters of diamond boring are: pre-boring of 0.2~0.6mm and final boring of 0.1mm; The feed rate is 0.01~0.14mm/r; The cutting speed is 100~250m/min when processing cast iron, 150~300m/min when processing steel, and 300~2000m/min when processing non-ferrous metals.

In order to ensure that the diamond boring machine can achieve high machining accuracy and surface quality, the machine tool (diamond boring machine) must have high geometric accuracy and stiffness, the main shaft of the machine tool supports the commonly used precision angular contact ball bearing or static pressure plain bearing, and the high-speed rotating parts must be accurately balanced; In addition, the movement of the feed mechanism must be very smooth to ensure that the table can do smooth low-speed feed movement.

The machining quality of diamond boring is good, the production efficiency is high, and it is widely used in the final processing of precision holes in a large number of mass production, such as the engine cylinder hole, the piston pin hole, the main shaft hole on the spindle box of the machine tool. However, it should be noted that when machining ferrous metal products with diamond boring, only the boring tool made of cemented carbide and CBN can be used, and the boring tool made of diamond can not be used, because the carbon atoms in diamond have a large affinity with the iron group elements, and the tool life is low.

3. Boring tool

Boring tool can be divided into single-edge boring tool and double-edge boring tool.

4. Boring process characteristics and application range

Compared with the drilling, expanding and reaming process, the bore size is not limited by the tool size, and the boring has a strong error correction ability, and the deviation error of the original hole axis can be corrected by multiple cutting, and the boring can maintain a higher position accuracy with the positioning surface.

Compared with the outer circle of the boring, due to the poor rigidity of the tool bar system, large deformation, poor heat dissipation and chip removal conditions, the hot deformation of the workpiece and the tool is relatively large, and the processing quality and production efficiency of the boring are not as high as the outer circle of the car.

In summary, it can be seen that the processing range of boring is wide, and holes of different sizes and different precision levels can be processed. For holes and hole systems with large aperture, high size and position accuracy requirements, boring is almost the only processing method. The machining accuracy of boring is IT9 ~ IT7. Boring can be carried out on the boring machine, lathe, milling machine and other machine tools, which has the advantages of flexibility and flexibility, and is widely used in production. In mass production, boring die is often used to improve boring efficiency.

1. Honing principle and honing head

Honing is the method of finishing the hole by using a honing head with a grinding rod (whetstone). When honing, the workpiece is fixed, and the honing head is rotated by the spindle of the machine tool and moves in a reciprocating straight line. In honing processing, the grinding strip acts on the workpiece surface with a certain pressure, and cuts an extremely thin layer of material from the workpiece surface. In order to make the movement of the abrasive particle not repeat, the number of revolutions per minute of the turning movement of the honing head and the number of reciprocating strokes per minute of the honing head should be prime.

The cross Angle of the honing track is related to the reciprocating speed and circular speed of the honing head, and the size of the Angle affects the processing quality and efficiency of the honing. In order to facilitate the discharge of broken abrasive particles and chips, reduce the cutting temperature and improve the processing quality, sufficient cutting fluid should be used when honing.

In order to make the machined hole wall can be uniformly machined, the stroke of the sand bar at both ends of the hole must exceed a section of overpass. In order to ensure the uniform honing allowance and reduce the influence of the spindle rotation error on the machining accuracy, the floating connection between the honing head and the spindle of the machine tool is mostly adopted.

The radial expansion adjustment of honing head grinding rod has various structural forms such as manual, pneumatic and hydraulic.

2. Honing process characteristics and application range

(1) honing can obtain higher dimensional accuracy and shape accuracy, the processing accuracy is IT7~IT6, the roundness and cylindricity error of the hole can be controlled within the range, but honing can not improve the position accuracy of the hole to be machined.

(2) Honing can obtain a higher surface quality, the surface roughness Ra is 0.2~0.25μm, the surface metal metamorphic defect layer depth is very small 2.5~25μm.

(3) Compared with the grinding speed, the circular speed of the honing head is not high (vc=16~60m/min), but due to the large contact area between the sand bar and the workpiece, the reciprocating speed is relatively high (va=8~20m/min), so the honing still has a high productivity.

Honing is widely used in the machining of engine cylinder holes and precision holes in various hydraulic devices in a large number of mass production, and can process deep holes with a length-diameter ratio greater than 10. However, honing is not suitable for processing holes on non-ferrous metal workpieces with large plasticity, nor can it process holes with keyways, spline holes, etc.

1. Broach and broach

Drawing is a high productivity finishing method, which is carried out on a broaching machine with a special broach. Broaching machine divided into horizontal broaching machine and vertical broaching machine two kinds, the horizontal broaching machine is the most common.

Broaching only uses low-speed linear motion (main motion). The number of teeth of the broach working at the same time should generally be not less than 3, otherwise the broach is not stable, and it is easy to produce ring ripples on the surface of the workpiece. In order to avoid generating too much broaching force and causing the broach to break, the number of teeth of the broach working at the same time should not exceed 6 to 8.

There are three different broaching methods, which are described as follows:

(1) Layered broaching

This broaching method is characterized by the broach cutting the workpiece machining allowance layer by layer in sequence. In order to facilitate chip breaking, the cutter teeth are ground with interleaved chip grooves. The broach designed according to the layered broaching method is called the ordinary broach.

(2) block broaching

The characteristic of this broaching method is that each layer of metal on the machined surface is cut by a set of tool teeth that are basically the same size but interlaced with each other (usually each set consists of 2-3 tool teeth). Each tooth cuts only part of a layer of metal. Broach designed according to the block broach method is called rotary broach.

(3) Comprehensive broaching

In this way, the advantages of layering and block broaching are concentrated. Block broaching is used in the rough cutting part and layer broaching is used in the fine cutting part. In this way, the broach length can be shortened, productivity can be increased, and better surface quality can be obtained. The broach designed according to the comprehensive broach method is called the comprehensive broach.

2. Process characteristics and application range of drawing holes

(1) The broach is a multi-edge tool, which can finish the roughing, finishing and finishing of the hole in a sequence in one broaching stroke, and has high production efficiency.

(2) The drawing accuracy mainly depends on the accuracy of the broach, under normal conditions, the drawing accuracy can reach IT9~IT7, and the surface roughness Ra can reach 6.3~ 1.6μm.

(3) When drawing a hole, the workpiece is positioned by the machined hole itself (the leading part of the broach is the positioning element of the workpiece), and the drawing hole is not easy to ensure the mutual position accuracy of the hole and other surfaces; For the processing of rotary parts whose inner and outer circular surfaces have coaxial requirements, it is often necessary to first pull holes, and then process other surfaces with holes as the positioning reference.

(4) broach can not only process round holes, but also process forming holes and spline holes.

(5) broach is a fixed size tool, complex shape, expensive, not suitable for processing large holes.

Drawing holes are commonly used in a large number of mass production to process holes on small and medium-sized parts with a diameter of 10~80mm and a hole depth of not more than 5 times the aperture.

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