Can deep hole drilling inserts be used in automated drilling systems

Threading inserts are a critical component of any threading operation as they provide a precision threading surface. When selecting threading inserts, a number of factors must be taken into consideration to ensure a successful operation.

The first factor to consider is material compatibility. Threading inserts must be made of a compatible material to the workpiece material, as it will affect the cutting performance. For fast feed milling inserts example, carbide threading inserts are suitable for hard materials such as steel, while ceramic inserts are better suited for softer materials such as aluminum.

The second factor to consider is thread size. Threading inserts come in a variety of thread sizes, and the size of the thread must match the thread size of the workpiece. This ensures that the insert fits into the workpiece and provides a secure fit.

The third factor to consider is the type of thread form. Threading inserts come in different thread forms such as V-threads, Acme threads, and Buttress threads. Depending on the type of thread being cut, the correct thread form must be chosen to ensure a successful threading operation.

Finally, the fourth factor to consider is the finish required. Threading inserts come in different finishes such tungsten carbide inserts as TiN, TiCN, and TiAlN. Depending on the finish required for the operation, the correct finish must be chosen.

By considering these factors, it is possible to select the best threading inserts for the job.

The Carbide Inserts Website: https://www.estoolcarbide.com/cutting-inserts/snmg-insert/

Threading inserts are a critical component of any threading operation as they provide a precision threading surface. When selecting threading inserts, a number of factors must be taken into consideration to ensure a successful operation.

The first factor to consider is material compatibility. Threading inserts must be made of a compatible material to the workpiece material, as it will affect the cutting performance. For fast feed milling inserts example, carbide threading inserts are suitable for hard materials such as steel, while ceramic inserts are better suited for softer materials such as aluminum.

The second factor to consider is thread size. Threading inserts come in a variety of thread sizes, and the size of the thread must match the thread size of the workpiece. This ensures that the insert fits into the workpiece and provides a secure fit.

The third factor to consider is the type of thread form. Threading inserts come in different thread forms such as V-threads, Acme threads, and Buttress threads. Depending on the type of thread being cut, the correct thread form must be chosen to ensure a successful threading operation.

Finally, the fourth factor to consider is the finish required. Threading inserts come in different finishes such tungsten carbide inserts as TiN, TiCN, and TiAlN. Depending on the finish required for the operation, the correct finish must be chosen.

By considering these factors, it is possible to select the best threading inserts for the job.

The Carbide Inserts Website: https://www.estoolcarbide.com/cutting-inserts/snmg-insert/

How Do Aluminum Milling Inserts Improve Efficiency in Milling Operations

Cutting inserts are an essential part of machining operations, as they help enhance the precision of machined components. Cutting inserts are designed to be used with cutting tools, such as drills, mills, and lathes, to achieve a higher level of accuracy and faster machining speeds. By using cutting inserts, the machining process is Cemented Carbide Inserts made more efficient and precise, resulting in high-quality components.

The most important aspect of cutting inserts is their geometry. The shape of the cutting insert determines the type of cut it produces and the accuracy of the machined component. Cutting inserts come in a variety of shapes and sizes, such as square, round, and triangular. Different shapes and sizes of cutting inserts allow for different levels of precision, depending on the type of machining operation being performed.

In addition to the shape and size of the cutting insert, the material it is made of is also important. Cutting inserts come in a variety of materials, such as carbide, ceramic, and high-speed steel. Each material has its own advantages and disadvantages, so selecting the right material for the job is essential. For example, carbide turning inserts for aluminum is extremely wear-resistant and provides a longer life cycle, while ceramic is highly resistant to heat and can be used for high-speed machining operations.

Lastly, the cutting edge of the cutting insert is also important. The cutting edge determines the speed and quality of the machined component. Generally, the sharper and more durable the cutting edge, the faster and more accurate the machining operation. Different types of cutting edges, such as single-point, multi-point, and chamfered, are available to provide different levels of precision.

In conclusion, cutting inserts are an essential part of machining operations. By selecting the right cutting insert for the job, machining operations can be made more efficient and precise. The shape, size, material, and cutting edge of the cutting insert are all important factors to consider when selecting the right cutting insert for the job.

The Carbide Inserts Website: https://www.estoolcarbide.com/cutting-tool-inserts/

Cutting inserts are an essential part of machining operations, as they help enhance the precision of machined components. Cutting inserts are designed to be used with cutting tools, such as drills, mills, and lathes, to achieve a higher level of accuracy and faster machining speeds. By using cutting inserts, the machining process is Cemented Carbide Inserts made more efficient and precise, resulting in high-quality components.

The most important aspect of cutting inserts is their geometry. The shape of the cutting insert determines the type of cut it produces and the accuracy of the machined component. Cutting inserts come in a variety of shapes and sizes, such as square, round, and triangular. Different shapes and sizes of cutting inserts allow for different levels of precision, depending on the type of machining operation being performed.

In addition to the shape and size of the cutting insert, the material it is made of is also important. Cutting inserts come in a variety of materials, such as carbide, ceramic, and high-speed steel. Each material has its own advantages and disadvantages, so selecting the right material for the job is essential. For example, carbide turning inserts for aluminum is extremely wear-resistant and provides a longer life cycle, while ceramic is highly resistant to heat and can be used for high-speed machining operations.

Lastly, the cutting edge of the cutting insert is also important. The cutting edge determines the speed and quality of the machined component. Generally, the sharper and more durable the cutting edge, the faster and more accurate the machining operation. Different types of cutting edges, such as single-point, multi-point, and chamfered, are available to provide different levels of precision.

In conclusion, cutting inserts are an essential part of machining operations. By selecting the right cutting insert for the job, machining operations can be made more efficient and precise. The shape, size, material, and cutting edge of the cutting insert are all important factors to consider when selecting the right cutting insert for the job.

The Carbide Inserts Website: https://www.estoolcarbide.com/cutting-tool-inserts/

How Can Aluminum Milling Inserts Reduce Tooling Costs in Milling Processes

Using a lathe is an essential process in many industrial settings. It is a precision tool that uses cutting inserts to produce high-quality products. However, when using a lathe, it is essential to use coolant to ensure that the inserts remain cool and do not wear out quickly.

Coolant is essential for lathe inserts, as it helps to reduce friction and heat. When the inserts become too hot, they can lose their hardness and become brittle. The result could be significant damage to the inserts and the workpiece. Therefore, always use coolant when using lathe inserts.

Another advantage of using coolant is that it flushes away debris and chips created during the cutting process. These chips can clog up the cutting edge, making it dull and unusable. With coolant, the chips are quickly flushed away, ensuring that the insert maintains its sharpness for longer.

There are various types of coolants that can be used with lathe inserts. Water-soluble oils are popular because they are less expensive and are relatively easy to dispose of. Synthetic coolants are more expensive but have a more extended lifespan and better lubrication qualities. Always choose a coolant that is suitable for your application and the type of lathe inserts you are using.

It is crucial to apply the coolant correctly for it to be effective. The coolant should be directed onto the insert at an angle of around 30 degrees. Applying the coolant directly onto the insert can result in it being washed away too quickly, whereas not applying enough could mean the insert becomes too hot, resulting in damage. It is also essential to ensure that the coolant is flowing correctly and is not blocked by any chips or debris.

In conclusion, the use of coolant is an essential Carbide Cutting Tools aspect of using lathe inserts. It helps to reduce friction, dissipate heat, and CCMT Insert flush away debris, ensuring that your inserts remain sharp and usable for a more extended period. Always choose the right coolant for your application and apply it correctly to maximize its benefits.

The Carbide Inserts Website: https://www.cuttinginsert.com/product/pvd-coated-insert/

Using a lathe is an essential process in many industrial settings. It is a precision tool that uses cutting inserts to produce high-quality products. However, when using a lathe, it is essential to use coolant to ensure that the inserts remain cool and do not wear out quickly.

Coolant is essential for lathe inserts, as it helps to reduce friction and heat. When the inserts become too hot, they can lose their hardness and become brittle. The result could be significant damage to the inserts and the workpiece. Therefore, always use coolant when using lathe inserts.

Another advantage of using coolant is that it flushes away debris and chips created during the cutting process. These chips can clog up the cutting edge, making it dull and unusable. With coolant, the chips are quickly flushed away, ensuring that the insert maintains its sharpness for longer.

There are various types of coolants that can be used with lathe inserts. Water-soluble oils are popular because they are less expensive and are relatively easy to dispose of. Synthetic coolants are more expensive but have a more extended lifespan and better lubrication qualities. Always choose a coolant that is suitable for your application and the type of lathe inserts you are using.

It is crucial to apply the coolant correctly for it to be effective. The coolant should be directed onto the insert at an angle of around 30 degrees. Applying the coolant directly onto the insert can result in it being washed away too quickly, whereas not applying enough could mean the insert becomes too hot, resulting in damage. It is also essential to ensure that the coolant is flowing correctly and is not blocked by any chips or debris.

In conclusion, the use of coolant is an essential Carbide Cutting Tools aspect of using lathe inserts. It helps to reduce friction, dissipate heat, and CCMT Insert flush away debris, ensuring that your inserts remain sharp and usable for a more extended period. Always choose the right coolant for your application and apply it correctly to maximize its benefits.

The Carbide Inserts Website: https://www.cuttinginsert.com/product/pvd-coated-insert/

The Role of Market Competition in Carbide Inserts Price

Cutting inserts are tools used to cut a variety of materials. They come in a wide range of shapes and sizes, and each type of insert has its own unique features and benefits. In this article, we’ll explore the different types of cutting inserts available and the advantages of each.

The most common type of cutting insert is the single-point insert. This is a one-piece tool that is designed to cut into a workpiece with a single cutting edge. These inserts are most commonly used for machining operations such as Lathe Inserts drilling, turning, and milling. Single-point inserts are available in a variety of shapes and sizes and can be used with a variety of different cutting tools.

Another type of cutting insert is the multi-point insert. This type of insert has multiple cutting edges that are designed to cut into a workpiece at the same time. Multi-point inserts are often used for more complicated machining operations, as they allow for faster and more accurate cutting. These inserts are available in a variety of shapes, sizes, and materials.

Finally, there are also specialty cutting inserts. These inserts are designed for specific applications and are not as widely available as the other types of inserts. Examples of specialty inserts include ceramic inserts, diamond inserts, and carbide inserts. Each of these inserts offer their own unique advantages tungsten carbide inserts and are best suited for specific cutting applications.

In conclusion, there are a variety of different types of cutting inserts available. Each type of insert has its own unique features and benefits, so it is important to choose the right insert for the job. By understanding the different types of inserts available, you can ensure that you are using the best tool for the job.

The Carbide Inserts Website: https://www.cuttinginsert.com/product/indexable-milling-insert/

Cutting inserts are tools used to cut a variety of materials. They come in a wide range of shapes and sizes, and each type of insert has its own unique features and benefits. In this article, we’ll explore the different types of cutting inserts available and the advantages of each.

The most common type of cutting insert is the single-point insert. This is a one-piece tool that is designed to cut into a workpiece with a single cutting edge. These inserts are most commonly used for machining operations such as Lathe Inserts drilling, turning, and milling. Single-point inserts are available in a variety of shapes and sizes and can be used with a variety of different cutting tools.

Another type of cutting insert is the multi-point insert. This type of insert has multiple cutting edges that are designed to cut into a workpiece at the same time. Multi-point inserts are often used for more complicated machining operations, as they allow for faster and more accurate cutting. These inserts are available in a variety of shapes, sizes, and materials.

Finally, there are also specialty cutting inserts. These inserts are designed for specific applications and are not as widely available as the other types of inserts. Examples of specialty inserts include ceramic inserts, diamond inserts, and carbide inserts. Each of these inserts offer their own unique advantages tungsten carbide inserts and are best suited for specific cutting applications.

In conclusion, there are a variety of different types of cutting inserts available. Each type of insert has its own unique features and benefits, so it is important to choose the right insert for the job. By understanding the different types of inserts available, you can ensure that you are using the best tool for the job.

The Carbide Inserts Website: https://www.cuttinginsert.com/product/indexable-milling-insert/

How to Improve Surface Finish in Turning with the Right Cutting Inserts

Cutting insert edge preparation is a critical process in achieving optimal cutting performance. It is the process of preparing the cutting edges on the cutting insert to provide the best possible cutting conditions for a particular application. This process includes pre-sharpening, honing, and polishing, all of which have a direct effect on the cutting performance of the cutting insert.

Pre-sharpening is the initial step in the edge preparation process. It involves grinding the cutting edge to the correct geometry and degree CNC Inserts of sharpness. This is important as it ensures that the cutting edge will stay sharp during the cutting process. Furthermore, it also reduces the chance of chipping and breakage during the cutting process.

Honing is the next step in the process and is used to further refine the cutting edge. It is designed to provide a smooth, uniform finish to the cutting edge. This helps to reduce cutting forces, which can lead to improved cutting performance, as well as reducing cutting vibrations and increasing tool life. In addition, honing also reduces the risk of tool breakage.

The last step in the edge preparation process is polishing. This is done to remove any burr or debris on the cutting edge. It also improves the surface finish of the workpiece and reduces the risk of defects while cutting. In addition, polishing helps reduce cutting forces, making cutting more efficient and accurate.

In conclusion, it is clear that cutting insert edge preparation is an essential step in achieving optimal cutting performance. It is important Cemented Carbide Inserts to ensure that the cutting edges are correctly prepared, as this can have a direct effect on the cutting performance and the life of the cutting insert. Therefore, it is essential that this step is taken seriously and done correctly in order to ensure the best possible cutting performance.

The Carbide Inserts Website: https://www.cuttinginsert.com/pro_cat/dijet/index.html

Cutting insert edge preparation is a critical process in achieving optimal cutting performance. It is the process of preparing the cutting edges on the cutting insert to provide the best possible cutting conditions for a particular application. This process includes pre-sharpening, honing, and polishing, all of which have a direct effect on the cutting performance of the cutting insert.

Pre-sharpening is the initial step in the edge preparation process. It involves grinding the cutting edge to the correct geometry and degree CNC Inserts of sharpness. This is important as it ensures that the cutting edge will stay sharp during the cutting process. Furthermore, it also reduces the chance of chipping and breakage during the cutting process.

Honing is the next step in the process and is used to further refine the cutting edge. It is designed to provide a smooth, uniform finish to the cutting edge. This helps to reduce cutting forces, which can lead to improved cutting performance, as well as reducing cutting vibrations and increasing tool life. In addition, honing also reduces the risk of tool breakage.

The last step in the edge preparation process is polishing. This is done to remove any burr or debris on the cutting edge. It also improves the surface finish of the workpiece and reduces the risk of defects while cutting. In addition, polishing helps reduce cutting forces, making cutting more efficient and accurate.

In conclusion, it is clear that cutting insert edge preparation is an essential step in achieving optimal cutting performance. It is important Cemented Carbide Inserts to ensure that the cutting edges are correctly prepared, as this can have a direct effect on the cutting performance and the life of the cutting insert. Therefore, it is essential that this step is taken seriously and done correctly in order to ensure the best possible cutting performance.

The Carbide Inserts Website: https://www.cuttinginsert.com/pro_cat/dijet/index.html

Unlocking the Power of Ceramic Lathe Inserts A Step-by-Step Guide

Cutting inserts are used in a variety of industrial applications to perform precise and efficient cutting operations. From machining components for cars and airplanes to creating intricate shapes in wood, cutting inserts are used in countless applications. The most common applications include turning, milling, drilling, and threading.

Turning is one of the most common uses for cutting inserts. Turning inserts are used to create cylindrical shapes in metals and other materials. The cutting edges of the insert are designed to cut the material in a single pass, enabling faster and more precise operations. Turning inserts are also used to create contours and other shapes.

Milling VBMT Insert is another popular application for cutting inserts. These inserts are used to create flat surfaces, grooves, and pockets in metals and other materials. The edges of the insert are designed to remove material quickly and accurately, allowing for faster and more precise machining operations.

Drilling is another common application for cutting inserts. These inserts are used to create holes in metals and other materials. The edges of the insert are designed to accurately drill holes of varying sizes and depths. This helps to reduce the number of passes needed to complete the drilling operation.

Threading is the last application for cutting inserts. These inserts are used to create threads in metals and other materials. The edges of the insert are designed to accurately cut threads with a high degree of precision. This DCMT Insert helps to reduce the amount of time needed to complete the threading operation.

Cutting inserts are used in a variety of industrial applications to perform precise and efficient cutting operations. From turning, milling, and drilling to threading, cutting inserts are used to perform a variety of operations in a wide range of materials.

The Carbide Inserts Website: https://www.cuttinginsert.com/pro_cat/hitachi/index.html

Cutting inserts are used in a variety of industrial applications to perform precise and efficient cutting operations. From machining components for cars and airplanes to creating intricate shapes in wood, cutting inserts are used in countless applications. The most common applications include turning, milling, drilling, and threading.

Turning is one of the most common uses for cutting inserts. Turning inserts are used to create cylindrical shapes in metals and other materials. The cutting edges of the insert are designed to cut the material in a single pass, enabling faster and more precise operations. Turning inserts are also used to create contours and other shapes.

Milling VBMT Insert is another popular application for cutting inserts. These inserts are used to create flat surfaces, grooves, and pockets in metals and other materials. The edges of the insert are designed to remove material quickly and accurately, allowing for faster and more precise machining operations.

Drilling is another common application for cutting inserts. These inserts are used to create holes in metals and other materials. The edges of the insert are designed to accurately drill holes of varying sizes and depths. This helps to reduce the number of passes needed to complete the drilling operation.

Threading is the last application for cutting inserts. These inserts are used to create threads in metals and other materials. The edges of the insert are designed to accurately cut threads with a high degree of precision. This DCMT Insert helps to reduce the amount of time needed to complete the threading operation.

Cutting inserts are used in a variety of industrial applications to perform precise and efficient cutting operations. From turning, milling, and drilling to threading, cutting inserts are used to perform a variety of operations in a wide range of materials.

The Carbide Inserts Website: https://www.cuttinginsert.com/pro_cat/hitachi/index.html

How Do Cast Iron Inserts Contribute to Your Home's Energy Efficiency

Threading inserts are a type of tool used to create internal threading along the inside of a hole. They are usually made from carbide, hardened steel, or ceramic, and come in a variety of sizes, shapes, and thread pitches. Threading inserts are available in the market in several different types, each offering unique advantages and drawbacks. Here is a look at the four main types of threading inserts.

Helical Threading Inserts: Helical threading inserts are a type of threading insert with a continuous helical groove. They are commonly used in a variety of applications where accurate threading Carbide Inserts is needed. The helical grooves make it so that cuts are consistent along the surface, reducing the chances of a stripped thread. Helical threading inserts are available in a variety of pitches and sizes.

Helicoil Threading Inserts: Helicoil threading inserts are a type of threading insert that feature a helical coil. These inserts are commonly used in applications that require high thread density, such as in aircraft and automotive engines. The helical coil allows for a tighter thread and a stronger connection than other types of threading inserts.

T-Thread Threading Inserts: T-Thread threading inserts feature a T-shaped thread on the outside surface. This type of threading insert is best suited for applications that require good accommodations to slight misalignments. The T-thread allows for a high degree of flexibility in the threading.

Spiral Point Threading Inserts: Spiral point threading inserts are a type of threading insert with a spiral point. This type of threading insert is designed to provide improved cutting performance. It can be used for threading operations that require high cutting speeds and accurate threading results.

Choosing the right type of threading insert for your application is important for achieving the desired Lathe Inserts results. It is important to consider the type of material you are using, the type of threading operation you are performing, and the desired results when selecting the correct threading insert for your application.

The Carbide Inserts Website: https://www.cuttinginsert.com/pro_cat/walter/index.html

Threading inserts are a type of tool used to create internal threading along the inside of a hole. They are usually made from carbide, hardened steel, or ceramic, and come in a variety of sizes, shapes, and thread pitches. Threading inserts are available in the market in several different types, each offering unique advantages and drawbacks. Here is a look at the four main types of threading inserts.

Helical Threading Inserts: Helical threading inserts are a type of threading insert with a continuous helical groove. They are commonly used in a variety of applications where accurate threading Carbide Inserts is needed. The helical grooves make it so that cuts are consistent along the surface, reducing the chances of a stripped thread. Helical threading inserts are available in a variety of pitches and sizes.

Helicoil Threading Inserts: Helicoil threading inserts are a type of threading insert that feature a helical coil. These inserts are commonly used in applications that require high thread density, such as in aircraft and automotive engines. The helical coil allows for a tighter thread and a stronger connection than other types of threading inserts.

T-Thread Threading Inserts: T-Thread threading inserts feature a T-shaped thread on the outside surface. This type of threading insert is best suited for applications that require good accommodations to slight misalignments. The T-thread allows for a high degree of flexibility in the threading.

Spiral Point Threading Inserts: Spiral point threading inserts are a type of threading insert with a spiral point. This type of threading insert is designed to provide improved cutting performance. It can be used for threading operations that require high cutting speeds and accurate threading results.

Choosing the right type of threading insert for your application is important for achieving the desired Lathe Inserts results. It is important to consider the type of material you are using, the type of threading operation you are performing, and the desired results when selecting the correct threading insert for your application.

The Carbide Inserts Website: https://www.cuttinginsert.com/pro_cat/walter/index.html

Custom Retail Boxes An Ideal Packaging Solution For Variety Of Products

Walter has revised its Xtra-tec XT M5130 shoulder milling cutter, increasing its productivity with strength-enhancing features, a new mounting position for inserts, a 7-degree clearance angle and 17% more teeth.

The M5130 handles a wide array of machining operations including face, shoulder, ramping and pocket milling, as well as circular interpolation Carbide Insert for Cast Iron operations. Walter recommends it for machining steel, stainless steel, cast iron, non-ferrous material and materials with difficult cutting properties.

This wide range of applications results in lower tooling and administrative costs, and its 90-degree approach angle reduces rod peeling inserts the need for finishing operations.

Walter’s M5130 features two pitches for different applications, and a stable cross-section due to the modified installation position for indexable inserts. The cutter is available in diameters between 0.5 and 6.0 in. (10-160 mm), and four geometries: F55, for increased stability; G55, for medium machining conditions; K55, for light cutting; and M85, for aluminum machining, low cutting forces and sharp cutting edges.

The Cemented Carbide Blog: turning Inserts

Walter has revised its Xtra-tec XT M5130 shoulder milling cutter, increasing its productivity with strength-enhancing features, a new mounting position for inserts, a 7-degree clearance angle and 17% more teeth.

The M5130 handles a wide array of machining operations including face, shoulder, ramping and pocket milling, as well as circular interpolation Carbide Insert for Cast Iron operations. Walter recommends it for machining steel, stainless steel, cast iron, non-ferrous material and materials with difficult cutting properties.

This wide range of applications results in lower tooling and administrative costs, and its 90-degree approach angle reduces rod peeling inserts the need for finishing operations.

Walter’s M5130 features two pitches for different applications, and a stable cross-section due to the modified installation position for indexable inserts. The cutter is available in diameters between 0.5 and 6.0 in. (10-160 mm), and four geometries: F55, for increased stability; G55, for medium machining conditions; K55, for light cutting; and M85, for aluminum machining, low cutting forces and sharp cutting edges.

The Cemented Carbide Blog: turning Inserts

Inserts Groove, Part, Profile Small Parts

The most recent version of SolidCAM features upgrades for mold and insert machining, including its iMachining 3D, HSM and simultaneous five-axis modules.

iMachining 3D is designed to automatically CNMG Insert produce a complete, ready-to-run CNC program. According to the company, it is capable of generating optimal cutting conditions to rough, rest-rough and semi-finish a complete 3D part with True Scallop on all slopes in a single operation. The tool path is adjusted automatically to avoid collisions between the holder and the updated stock at every stage. A knowledge-based technology wizard helps to achieve optimal cutting conditions. The function is said to improve machining time over other CAM systems.

SolidCAM’s HSM module provides an optimum 3D finish tool path for molds or inserts. The function avoids sharp angles, ensuring that the tool stays in contact with the workpiece CCGT Insert as much as possible. Non-machining moves are optimized to reduce air cutting, and generate smooth and tangential lead in and out trajectories.

Enhanced simultaneous five-axis strategies for CNC milling enable control over toolpath and collision checking. Updates were made to multi-axis drill, five-axis contour and convert HSM to simultaneous five-axis strategy. For example, the contour five-axis function enables the tool to follow the selected 2D curve, staying parallel to predefined tilting lines. According to the company, this feature is ideal for chamfering and pencil machining complex contours with undercuts.

The Cemented Carbide Blog: http://thomaschap.blogtez.com/

The most recent version of SolidCAM features upgrades for mold and insert machining, including its iMachining 3D, HSM and simultaneous five-axis modules.

iMachining 3D is designed to automatically CNMG Insert produce a complete, ready-to-run CNC program. According to the company, it is capable of generating optimal cutting conditions to rough, rest-rough and semi-finish a complete 3D part with True Scallop on all slopes in a single operation. The tool path is adjusted automatically to avoid collisions between the holder and the updated stock at every stage. A knowledge-based technology wizard helps to achieve optimal cutting conditions. The function is said to improve machining time over other CAM systems.

SolidCAM’s HSM module provides an optimum 3D finish tool path for molds or inserts. The function avoids sharp angles, ensuring that the tool stays in contact with the workpiece CCGT Insert as much as possible. Non-machining moves are optimized to reduce air cutting, and generate smooth and tangential lead in and out trajectories.

Enhanced simultaneous five-axis strategies for CNC milling enable control over toolpath and collision checking. Updates were made to multi-axis drill, five-axis contour and convert HSM to simultaneous five-axis strategy. For example, the contour five-axis function enables the tool to follow the selected 2D curve, staying parallel to predefined tilting lines. According to the company, this feature is ideal for chamfering and pencil machining complex contours with undercuts.

The Cemented Carbide Blog: http://thomaschap.blogtez.com/

Efficient Aluminum Cutting PCD Milling Cutter

The Tongtai MT series of lathes, available from Absolute Machine Tools, was developed to improve cycle times and turning processes for the automotive industry and is suitable for precision turning, high-production volume, automatic production and insertion into mass-production lines.

The machines feature twin spindles and two individual machining areas with separate bed structure to limit transfer of harmonic vibration, improving machining accuracy and surface finish. The turrets and spindles are parallel to each other, enabling parts which need two processes to be finished on one machine, the supplier says. Cutting feed rates range from 0.001 to 5,000 mm/min.

The two individual working areas feature a separate bed Carbide Drilling Inserts structure which is designed to decrease the transferring of harmonic vibration to provide increased machining accuracy and high-quality surface finishes. Maximum swing diameter is 210 mm with a machining diameter of 210 or 120 mm with a robotic arm, and a machining length of 145 or 100 mm with a robotic arm. 

That series features a programmable, gantry-type robotic arm that processes three axes movements and is driven by a servomotor, enabling the operator to adjust positioning points and moving routes. The arm provides rapid traverse rates of 160, 120 and 35 m/min. in the X, Y and Z axes, respectively. The rotary axis moves at 180 degrees/sec.

The lathes are equipped with 6" or 8" chucks on 6,000- or 4,500-rpm spindles. Other standard features include a through-coolant spindle, A2-5 or A2-6 spindle SNMG Insert nose, and 0.001" indexing increments. 

The Cemented Carbide Blog: CNC Turning Inserts

The Tongtai MT series of lathes, available from Absolute Machine Tools, was developed to improve cycle times and turning processes for the automotive industry and is suitable for precision turning, high-production volume, automatic production and insertion into mass-production lines.

The machines feature twin spindles and two individual machining areas with separate bed structure to limit transfer of harmonic vibration, improving machining accuracy and surface finish. The turrets and spindles are parallel to each other, enabling parts which need two processes to be finished on one machine, the supplier says. Cutting feed rates range from 0.001 to 5,000 mm/min.

The two individual working areas feature a separate bed Carbide Drilling Inserts structure which is designed to decrease the transferring of harmonic vibration to provide increased machining accuracy and high-quality surface finishes. Maximum swing diameter is 210 mm with a machining diameter of 210 or 120 mm with a robotic arm, and a machining length of 145 or 100 mm with a robotic arm. 

That series features a programmable, gantry-type robotic arm that processes three axes movements and is driven by a servomotor, enabling the operator to adjust positioning points and moving routes. The arm provides rapid traverse rates of 160, 120 and 35 m/min. in the X, Y and Z axes, respectively. The rotary axis moves at 180 degrees/sec.

The lathes are equipped with 6" or 8" chucks on 6,000- or 4,500-rpm spindles. Other standard features include a through-coolant spindle, A2-5 or A2-6 spindle SNMG Insert nose, and 0.001" indexing increments. 

The Cemented Carbide Blog: CNC Turning Inserts