Metal Pipe Bending Machine

A metal pipe bending machine is a metalworking device, used to bend metal pipes at necessary angles. There are pipe bending machines with and without mandrels. The aluminum and steel pipes can easily be bent on our tube bending machines starting from as small as 42 mm of pipe diameter up to 100 mm outside diameter.

A metal pipe bending machine is a specialized tool that is used to bend metal pipes and tubes to a desired angle or shape. The machine operates by applying force to the pipe or tube using hydraulic or mechanical methods, which causes it to bend into the desired shape.

There are different types of metal pipe bending machines, including manual and automatic machines. Manual machines require the operator to adjust the machine and bend the pipe by hand, while automatic machines are computer-controlled and can perform multiple bends with a high degree of accuracy.

Metal pipe bending machines are commonly used in industries such as construction, automotive manufacturing, and aerospace engineering, where metal pipes and tubes are required for various applications. They are also used in the production of furniture, machinery, and other metal products.

The radius of the tube bending is arranged by bending tools. The pipe material can be steel, stainless steel, aluminum, copper, or tin. Aluminum tube benders are mostly used for stair holders. Mandrel bending machines are much bigger and less economic in comparison to the ones without mandrels. But with our bending tube machine, our customers bend the required pipes easily

Aluminum tube bending machines are controlled by NC controllers. On the NC controller, the operator can enter the bending angle and the number of bending cycles so that the bending machine for the sheet metal remembers the required cycles and automatically bends the pipe. The operator puts the pipe and sets the bending angle. The tube bending machine is operated by a foot pedal to keep the operator away from the machine for safety measures.

Our hydraulic pipe bending machines start from the diameter 42 mm to 60,76 and 100 mm maximum. By rotating the metal pipe around its own axis, the operator can have a 3D bending effect from our hydraulic metal bending machine

The tehnical characteristics of our pipe bender machine: CK 45 Monoblock Frame Reducer Driven All Shafts and Necessary parts are hardened and grinded Digital Read out Counter for back support Inverter and speed adjustment CE certificate

Metal Pipe Bending Machine

Metal pipe bending machines are versatile tools used to shape and form various types of metal pipes into desired bends and curves. These machines are widely employed in a variety of industries, including plumbing, automotive, HVAC, and aerospace, to create precise bends that meet specific requirements.

Types of Metal Pipe Bending Machines

There are two primary types of metal pipe bending machines:

1. Mandrel bending machines: These machines utilize an internal mandrel that supports the pipe during the bending process, ensuring consistent and precise bends without distortion or thinning of the material. Mandrel bending is particularly suitable for bending thin-walled or ductile metal pipes.
2. Non-mandrel bending machines: These machines do not use an internal mandrel and instead rely on external pressure rollers to gradually deform the pipe or tube into the desired shape. Non-mandrel bending is well-suited for bending thicker-walled or harder metal pipes.

Key Features of Metal Pipe Bending Machines

1. Bending capacity: This refers to the maximum pipe diameter and wall thickness that the machine can handle.
2. Bending radius: This is the distance from the center of the pipe to the center of the bend. A larger bending radius creates a more gradual bend, reducing wrinkling and ovalization.
3. Bending angle: This is the angle of the bend. Pipe bending machines can typically achieve bending angles of up to 180 degrees.
4. Drive system: The drive system provides the power to bend the pipe. Pipe bending machines typically use hydraulic or electric drive systems.
5. Control system: The control system regulates the bending process and ensures precise angle and radius control.

Applications of Metal Pipe Bending Machines

1. Plumbing and piping: Pipe bending machines are used to create bends in pipes for water supply, drainage, and gas lines.
2. Automotive industry: These machines are employed in the automotive industry to fabricate exhaust pipes, intake manifolds, and other tubular components with precise bends.
3. HVAC systems: Pipe bending is used in HVAC systems to create bends for ductwork, refrigerant lines, and ventilation systems, ensuring smooth airflow and efficient operation.
4. Furniture manufacturing: These machines are used in furniture manufacturing to produce curved metal frames for chairs, tables, and other furniture pieces, adding aesthetic appeal and functionality.
5. Aerospace and defense: Pipe bending is crucial in the aerospace and defense industries for creating precise bends in aircraft components, hydraulic lines, and structural supports, ensuring the integrity and performance of critical components.

Benefits of Metal Pipe Bending Machines

1. Precise bending: Pipe bending machines can achieve precise bending angles and radii, meeting stringent dimensional requirements for various applications.
2. Reduced material waste: Optimized material usage minimizes waste and promotes cost-efficiency.
3. Enhanced structural integrity: Precise bends maintain the structural integrity of the pipe, preventing premature failure or leaks.
4. Improved flow characteristics: Preserving the pipe’s internal diameter ensures optimal flow capacity, reducing pressure drops and maintaining system efficiency.
5. Increased versatility: Pipe bending machines can handle a wide range of pipe sizes, materials, and bending requirements, making them versatile tools for various industries.

Conclusion

Metal pipe bending machines play a vital role in various industries, enabling the creation of precise and durable bends that meet specific functional and aesthetic requirements. Their versatility, efficiency, and ability to produce high-quality bends make them essential tools for manufacturing, construction, and other applications. With proper selection, operation, and maintenance, pipe bending machines can contribute to efficient, safe, and cost-effective production processes

Bending Capacity of the Pipe Bending Machine

Bending capacity refers to the maximum pipe diameter and wall thickness that a pipe bending machine can handle. It is an important factor to consider when selecting a pipe bending machine for a particular application.

The bending capacity of a machine is typically specified in two ways:

• Maximum pipe diameter: This is the largest diameter of pipe that the machine can bend.
• Maximum wall thickness: This is the thickest wall thickness of pipe that the machine can bend.

Bending capacity is determined by the strength and stiffness of the machine’s bending mechanism. Machines with stronger and stiffer bending mechanisms can handle larger and thicker pipes.

Here are some factors that can affect the bending capacity of a pipe bending machine:

• Machine type: Mandrel bending machines typically have a higher bending capacity than non-mandrel bending machines.
• Drive system: Hydraulic drive systems typically have a higher bending capacity than electric drive systems.
• Bending radius: A larger bending radius creates a more gradual bend, which requires less force from the machine.
• Bending angle: Bending smaller angles typically requires less force than bending larger angles.
• Pipe material: Harder pipe materials require more force to bend than softer pipe materials.
• Pipe wall thickness: Thicker pipe walls require more force to bend than thinner pipe walls.

In general, it is important to select a pipe bending machine that has a bending capacity that is at least equal to the diameter and wall thickness of the pipes that you will be bending. If the machine is not powerful enough, it may not be able to bend the pipes without causing damage.

Here are some examples of bending capacity for different types of pipe bending machines:

• Mandrel bending machine for thin-walled steel pipes: 1-inch (25 mm) diameter, 0.030-inch (0.76 mm) wall thickness
• Mandrel bending machine for thick-walled steel pipes: 4-inch (102 mm) diameter, 0.250-inch (6.35 mm) wall thickness
• Non-mandrel bending machine for thin-walled aluminum pipes: 0.5-inch (12.7 mm) diameter, 0.020-inch (0.51 mm) wall thickness
• Non-mandrel bending machine for thick-walled aluminum pipes: 2-inch (50.8 mm) diameter, 0.120-inch (3.05 mm) wall thickness

It is always a good idea to consult with the manufacturer of the pipe bending machine to get specific recommendations for the bending capacity of the machine for your specific application.

Bending radius of the Pipe Bending Machine

Bending radius is a crucial aspect of pipe bending that determines the sharpness of the bend. It is defined as the distance between the center of the pipe and the center of the bend. Larger bending radii create more gradual bends, while smaller bending radii create sharper bends.

The choice of bending radius depends on the specific application and desired bend characteristics. Larger bending radii are generally preferred for pipes that will be subjected to high stresses, as they minimize the risk of wrinkling or ovalization. Sharper bends, on the other hand, may be necessary for applications where aesthetics or space constraints are a concern.

Here are some factors to consider when selecting a bending radius:

• Pipe material: Hard pipe materials, such as steel, can handle smaller bending radii than softer materials, such as aluminum.
• Pipe wall thickness: Thicker pipe walls can handle smaller bending radii than thinner pipe walls.
• Bending angle: Smaller bending angles can be achieved with smaller bending radii.
• Bending machine type: Mandrel bending machines typically allow for smaller bending radii than non-mandrel bending machines.
• Drive system: Hydraulic drive systems typically allow for smaller bending radii than electric drive systems.
• Application: For applications where fatigue or stress concentrations are a concern, larger bending radii are typically preferred. For applications where aesthetics or space constraints are a concern, sharper bends may be necessary.

In general, it is recommended to select a bending radius that is as large as possible while still meeting the specific requirements of the application. This will minimize the risk of wrinkling or ovalization and ensure that the bend is durable and long-lasting.

Here are some examples of bending radii for different types of pipe bending machines:

• Mandrel bending machine: 4:1 to 6:1
• Non-mandrel bending machine: 2:1 to 3:1

It is always a good idea to consult with the manufacturer of the pipe bending machine to get specific recommendations for the bending radius for your specific application.

Bending angle

Bending angle is a crucial parameter in pipe bending, defining the extent to which a pipe is curved or deformed. It is measured in degrees and represents the angle between the original straight axis of the pipe and the new bent axis. The bending angle can range from a few degrees to nearly 180 degrees, depending on the specific application and pipe characteristics.

Factors Affecting Bending Angle

Several factors influence the selection and achievement of the desired bending angle:

1. Pipe Material: Different pipe materials exhibit varying degrees of flexibility and ductility. Ductile materials, such as aluminum or copper, can withstand greater bending angles without deformation or cracking.
2. Pipe Wall Thickness: Thinner-walled pipes can accommodate larger bending angles compared to thicker-walled pipes. This is because thinner walls offer less resistance to bending forces.
3. Bending Radius: The bending radius, the distance from the pipe’s center to the bend’s center, influences the achievable bending angle. Smaller bending radii typically necessitate smaller bending angles to prevent wrinkling or ovalization.
4. Bending Machine Type: Mandrel bending machines, which utilize an internal mandrel to support the pipe during bending, can achieve sharper bending angles compared to non-mandrel bending machines.
5. Drive System: Hydraulic drive systems generally provide more power and control, enabling tighter bending angles compared to electric drive systems.

Applications of Bending Angle

Bending angles play a significant role in various applications, including:

1. Plumbing and Piping: Bending angles are crucial for creating precise connections and routing pipes in plumbing systems, ensuring proper flow and avoiding leaks.
2. Automotive Industry: Bending angles are essential for fabricating exhaust pipes, intake manifolds, and other tubular components in automobiles, ensuring proper fit and performance.
3. HVAC Systems: Bending angles are vital for creating bends in ductwork, refrigerant lines, and ventilation systems, maintaining airflow efficiency and system integrity.
4. Furniture Manufacturing: Bending angles are used to form curved metal frames for chairs, tables, and other furniture pieces, adding aesthetic appeal and functionality.
5. Aerospace and Defense: Bending angles are critical for creating precise bends in aircraft components, hydraulic lines, and structural supports, ensuring the integrity and performance of critical components.

Selecting the Appropriate Bending Angle

The choice of bending angle depends on the specific application and desired bend characteristics. Factors to consider include:

1. Functional Requirements: The bending angle must meet the functional requirements of the application, ensuring proper alignment, flow, and performance.
2. Material Compatibility: The bending angle must be compatible with the pipe material, avoiding excessive strain or deformation that could compromise the pipe’s integrity.
3. Manufacturing Constraints: The bending angle must be achievable within the limitations of the available pipe bending machine and operator expertise.
4. Aesthetic Considerations: For applications where appearance is important, the bending angle should be aesthetically pleasing and consistent with the overall design.
5. Cost-Effectiveness: The bending angle should be selected to minimize material waste and optimize production efficiency while meeting the necessary functional and aesthetic requirements.

In conclusion, bending angle is a critical parameter in pipe bending, influencing the functionality, aesthetics, and manufacturability of bent pipes. Careful consideration of pipe material, wall thickness, bending radius, machine type, drive system, and application requirements is essential for selecting the appropriate bending angle for each application.

Pipe Material

Pipe material is a crucial consideration for pipe bending, as the properties of the material directly impact the feasibility and outcome of the bending process. Different pipe materials exhibit varying degrees of flexibility, ductility, and resistance to deformation, making them suitable for specific applications and bending methods.

Common Pipe Materials for Bending

1. Steel: Steel is a versatile and widely used pipe material due to its strength, durability, and resistance to corrosion. However, it is also relatively rigid, requiring larger bending radii and mandrel support for sharper bends.
2. Aluminum: Aluminum is a lighter and more ductile material than steel, allowing for tighter bending angles and reduced material thickness. However, it is also more susceptible to fatigue and stress concentrations, making it less suitable for applications with high pressure or vibration.
3. Copper: Copper is another ductile material with excellent thermal conductivity, making it suitable for applications involving fluid transfer or electrical wiring. It can handle smaller bending radii than steel but requires careful handling to avoid strain hardening.
4. Polyethylene: Polyethylene is a flexible and corrosion-resistant plastic commonly used for underground pipes and drainage systems. It can be bent with minimal radius, making it suitable for tight spaces and complex geometries.
5. PTFE (Polytetrafluoroethylene): PTFE, also known as Teflon, is a non-stick and highly resistant plastic known for its exceptional flexibility. It can be bent into complex shapes without requiring mandrel support, making it ideal for applications where aesthetics or space constraints are a concern.

Bending Methods and Pipe Material Compatibility

The choice of bending method also influences the selection of pipe material. Mandrel bending is typically preferred for bending thin-walled or ductile materials, such as aluminum or copper, as it provides internal support and minimizes the risk of wrinkling or ovalization. Non-mandrel bending can be used for thicker-walled or harder materials, such as steel, but it requires larger bending radii and greater care to prevent deformation.

In summary, pipe material plays a critical role in pipe bending, determining the achievable bending angle, bending method, and overall bend quality. Careful selection of the appropriate pipe material based on the specific application and bending requirements is essential for ensuring efficient, effective, and durable bends.

Pipe Wall Thickness

Pipe wall thickness is another crucial factor in pipe bending, directly impacting the bending process, bend quality, and overall performance of the bent pipe. Thinner-walled pipes tend to be more flexible, allowing for tighter bends and smaller bending radii. However, they are also more susceptible to wrinkling or ovalization during the bending process, requiring careful handling and support.

Effect of Wall Thickness on Bending Angle and Bend Quality

Bending angle is typically limited for thicker-walled pipes due to the increased resistance to deformation. Smaller bending angles are required to prevent excessive thinning of the pipe wall, which could compromise the pipe’s integrity.

Bend quality also depends on wall thickness. Thinner-walled pipes tend to deform more easily during bending, potentially leading to wrinkling or ovalization, which could affect the pipe’s structural integrity and fluid flow characteristics.

Selection of Appropriate Wall Thickness for Bending

The choice of pipe wall thickness depends on the specific application and bending requirements. For applications where tight bends and small bending radii are necessary, thinner-walled pipes are preferable. However, for applications where high pressure, vibration, or impact loads are expected, thicker-walled pipes are more suitable to ensure structural integrity.

Bending Methods and Wall Thickness Compatibility

Mandrel bending is generally preferred for thin-walled pipes, as the internal mandrel provides support and prevents wrinkling or ovalization. Non-mandrel bending can be used for thicker-walled pipes, but it requires larger bending radii and greater care to prevent excessive deformation.

In summary, pipe wall thickness plays a significant role in the feasibility and success of pipe bending. Careful consideration of the application requirements, bending angle, and material properties is essential for selecting the appropriate wall thickness for optimal bend quality and pipe performance.

Hydraulic Tube Bender

Hydraulic tube benders are versatile tools used to shape and form various types of tubes into desired bends and curves. These machines utilize hydraulic pressure to gradually deform the tube, creating precise bends without distortion or thinning of the material. Hydraulic tube benders are widely employed in various industries, including plumbing, automotive, aerospace, and furniture manufacturing.

Advantages of Hydraulic Tube Benders

1. High Power and Precision: Hydraulic systems provide powerful and controlled bending force, enabling the production of precise bends with minimal material deformation.
2. Versatility: Hydraulic tube benders can handle a wide range of tube sizes and materials, including steel, stainless steel, aluminum, and copper.
3. Uniform Bends: The hydraulic system ensures consistent and repeatable bends, meeting stringent dimensional requirements for various applications.
4. Reduced Material Waste: Precise bending minimizes material waste and promotes cost-effectiveness.
5. Ease of Operation: Hydraulic tube benders are relatively easy to operate and require minimal setup, making them suitable for both skilled operators and beginners.

Key Components of Hydraulic Tube Benders

1. Frame: The frame provides the structural support for the machine and houses the hydraulic system and bending mechanism.
2. Hydraulic System: The hydraulic system generates and controls the pressure required to bend the tube.
3. Bending Formers: These formers, also known as dies, shape the tube during the bending process based on the desired bend radius and angle.
4. Pressure Roller System: The pressure rollers apply force to the tube, gradually deforming it into the desired shape.
5. Control System: The control system regulates the bending process and ensures precise angle and radius control.

Bending Formers

Bending formers, also known as dies, are essential components of tube bending machines. They are shaped to create the desired bend radius and angle in the tube during the bending process. The type of bending former used depends on the specific application and the properties of the tube material.

Types of Bending Formers

There are two main types of bending formers:

1. Mandrel formers: Mandrel formers are inserted into the tube before bending to provide support and prevent collapse. This is especially important for thin-walled tubes and materials that are prone to wrinkling or ovalization.
2. Non-mandrel formers: Non-mandrel formers do not require an internal support mandrel. This makes them suitable for thicker-walled tubes or materials that are more resistant to deformation.

Features of Bending Formers

Bending formers are typically made from hardened steel or other high-strength materials to withstand the forces applied during the bending process. They are also designed to minimize friction and wear on the tube material.

Applications of Bending Formers

Bending formers are used in a wide variety of industries, including:

1. Plumbing and piping: Bending formers are used to create bends in pipes for water supply, drainage, and gas lines.
2. Automotive industry: Bending formers are used to fabricate exhaust pipes, intake manifolds, and other tubular components with precise bends.
3. HVAC systems: Bending formers are used to create bends for ductwork, refrigerant lines, and ventilation systems.
4. Furniture manufacturing: Bending formers are used to produce curved metal frames for chairs, tables, and other furniture pieces.
5. Aerospace and defense: Bending formers are used to create precise bends in aircraft components, hydraulic lines, and structural supports.

Selection of Bending Formers

The selection of bending formers is based on the following factors:

1. Tube size: The diameter and wall thickness of the tube must be compatible with the former.
2. Bending radius: The desired bend radius determines the curvature of the former.
3. Bending angle: The desired bend angle determines the angle of the former.
4. Material compatibility: The former material must be compatible with the tube material to prevent corrosion or damage.

Care and Maintenance of Bending Formers

Regularly inspect the bending formers for cracks, damage, or wear. Replace any damaged formers to ensure consistent and safe operation.

Store the formers in a clean, dry environment to prevent corrosion or damage.

Avoid excessive force when inserting or removing the formers from the tube.

Use the appropriate lubricant to reduce friction and wear.

Conclusion

Bending formers are essential tools for creating precise bends in tubes. By carefully selecting the appropriate formers and following proper care and maintenance guidelines, users can ensure consistent and reliable bending results.

Applications of Hydraulic Tube Benders

1. Plumbing and Piping: Hydraulic tube benders are used to create bends in pipes for water supply, drainage, and gas lines.
2. Automotive Industry: These machines are employed in the automotive industry to fabricate exhaust pipes, intake manifolds, and other tubular components with precise bends.
3. HVAC Systems: Hydraulic bending is used in HVAC systems to create bends for ductwork, refrigerant lines, and ventilation systems, ensuring smooth airflow and efficient operation.
4. Furniture Manufacturing: These machines are used in furniture manufacturing to produce curved metal frames for chairs, tables, and other furniture pieces, adding aesthetic appeal and functionality.
5. Aerospace and Defense: Hydraulic tube bending is crucial in the aerospace and defense industries for creating precise bends in aircraft components, hydraulic lines, and structural supports, ensuring the integrity and performance of critical components.

Safety Considerations for Hydraulic Tube Bender Operation

1. Wear Proper Personal Protective Equipment (PPE): Always wear appropriate PPE, including safety glasses, gloves, and hearing protection, when operating a hydraulic tube bender.
2. Secure Workpiece Placement: Properly secure the tube to the machine’s worktable or clamping system to prevent it from moving or twisting during the bending process.
3. Inspect the Bending Formers: Regularly inspect the bending formers for cracks, damage, or wear. Replace any damaged formers to ensure consistent and safe operation.
4. Maintain Proper Clearance: Maintain adequate clearance between the operator and moving parts of the machine to prevent injuries.
5. Follow Manufacturer Guidelines: Always follow the manufacturer’s operating instructions and safety guidelines for the specific hydraulic tube bender being used.

Conclusion

Hydraulic tube benders offer a powerful and efficient method for shaping and forming tubes into precise bends. Their ability to handle a wide range of tube sizes and materials, coupled with their ease of operation and safety features, makes them valuable tools in various industries. With proper selection, operation, and maintenance, hydraulic tube benders can contribute to efficient, safe, and cost-effective manufacturing processes.

Hydraulic tube benders can also be used to bend square tubes. The difference between bending a metal pipe and a square pipe lies in the molds. The molds for square tube bending are designed for the square tubes to bend. The square tube benders without mandrels are used to bend square tubes with the required angles.

The square metal tubes are placed on the tooling dies of the bending press machine and the bending angle is set through the NC controller. Through this controller, you can set angles as small as 0.1 Angles. This cold bending press starts to rotate the central wheel to bend the square pipe in the required direction and with the given angle. After the first bending, the operator can rotate the square pipe around its own axis to bend the square pipe in 3D space.

This can also be done CNC tubing bender. CNC tubing benders are tube benders that operate with a CNC controller. The operator uploads the bending drawing into the pressing machine and the pipe bending machine starts to bend the tubes or square pipes.

As the material type of the pipes that can be bent on this pipe bender: aluminum tube bender, copper tube bender, stainless steel tube bender, and mild steel tube bender can be listed. for the aluminum tube benders, these bending machines can bend aluminum pipes for decorative purposes. the copper tube bender is used for the plumbing industry as copper tubes are used for the heating systems. the stainless steel tube bender, also called the exhaust tubing bender is used to bend the exhaust pipes of the cars. The tubing bender dies to need to be changed in accordance with the exhaust or stainless steel pipe that needs to be bent.

Pipe bender / Tube bender

Manual pipe bending machines or manual tube benders are preferred for more simple works such as HVAC tubing. These machines are lighter in weight and easier to transport and for small capacities, they can be preferred. These manual pipe bending machines can bend around pipes as well as square tubes. Bending stainless steel tubing has no different characteristics than metal tube bending. it is also the same for bending galvanized pipes.

Metal bending tools are also manufactured in our own production facility. We use CNC machinery to manufacture our bending tools as well as our machines. We use low carbon tool steel for our bending tools and our bending tools are covered by a carbon coat to avoid damage and scratches during the bending process. For square tube benders, we manufacture related bending tools for any tool dimension the customer asks for. For pipe tube benders, we have bending tools starting from as small as 1″, 2″,3, and 4″

Pipe Bending Machine

Metal pipe bending machines are used in various industries for bending pipes of different materials, shapes, and sizes. Some of the industries where these machines are commonly used include:

1. Automotive industry: Metal pipe bending machines are used to bend tubes and pipes used in the manufacturing of various automotive parts, such as exhaust systems, roll cages, and chassis.
2. Construction industry: Metal pipe bending machines are used to bend pipes used in the construction of buildings, bridges, and other structures. These machines are also used in the production of HVAC ducts, railings, and handrails.
3. Aerospace industry: Metal pipe bending machines are used to bend pipes and tubes used in the construction of aircraft, such as hydraulic and fuel lines, and structural components.
4. Furniture industry: Metal pipe bending machines are used to bend pipes and tubes used in the manufacturing of furniture, such as chairs, tables, and shelves.
5. Manufacturing industry: Metal pipe bending machines are used in various manufacturing processes, such as in the production of kitchen appliances, bicycles, and fitness equipment.
6. Agriculture industry: Metal pipe bending machines are used to bend pipes and tubes used in the manufacturing of agricultural equipment, such as irrigation systems and livestock handling equipment.

EMS Metalworking Machinery

We design, manufacture and assembly metalworking machinery such as:

• Hydraulic transfer press
• Glass mosaic press
• Hydraulic deep drawing press
• Casting press
• Hydraulic cold forming press
• Hydroforming press
• Composite press
• Silicone rubber moulding press
• Brake pad press
• Melamine press
• SMC & BMC Press
• Labrotaroy press
• Edge cutting trimming machine
• Edge curling machine
• Trimming beading machine
• Trimming joggling machine
• Cookware production line
• Pipe bending machine
• Profile bending machine
• Bandsaw for metal
• Cylindrical welding machine
• Horizontal pres and cookware
• Kitchenware, hotelware
• Bakeware and cuttlery production machinery

as a complete line as well as an individual machine such as:

• Edge cutting trimming beading machines
• Polishing and grinding machines for pot and pans
• Hydraulic drawing presses
• Circle blanking machines
• Riveting machine
• Hole punching machines
• Press feeding machine

You can check our machinery at work at: EMS Metalworking Machinery – YouTube

Applications:

• Beading and ribbing
• Flanging
• Trimming
• Curling
• Lock-seaming
• Ribbing
• Flange-punching