Item Description
MSG17 MSG21 MSG27 MSG35 MSG17E MSG21E MSG27E MSG35E MSG17S MSG21S MSG27S MSG35S MSC7 MSC9 MSC12 MSC15 MSC7L MSC9L MSC12L MSC15L MSD7 MSD9 MSD12 MSD15 MSD7L MSD9L MSD12L MSD15L MSC7M MSC7LM MSC9M MSC9LM MSC12M MSC12LM MSC15M MSC15LM MSD7M MSD7LM MSD9M MSD9LM MSD12M MSD12LM MSD15M MSD15LM MSH2OL MSH3OL MSH20 MSH30 MSH20T MSH30T MSH20LS MSH30LS MSR20T MSR25T MSR30T MSR35T MSR45T MSR55T MSR65T MSR20E MSR20LE MSR25E MSR25LE MSR30E MSR30LE MSR35E MSR35LE MSR45E MSR45LE MSR55E MSR55LE MSR65E MSR65LE
MSR20S MSR20LS MSR25S MSR25LS MSR30S MSR30LS MSR35S MSR35LS MSR45S MSR45LS MSR55S MSR55LS MSR65S MSR65LS SMR25 SMR30 SMR35 SMR45 SMR55 SMR65 SMR25T SMR30T SMR35T SMR45T SMR55T SMR65T SMR25E SMR25LE SMR30E SMR30LE SMR35E SMR35LE SMR45E SMR45LE SMR55E SMR55LE SMR65E SMR65LE SMR25S SMR25LS SMR30S SMR30LS SMR35S SMR35LS SMR45S SMR45LS SMR55S SMR55LS SMR65S SMR65LS
SME15 SME20 SME25 SME30 SME35 SME45 SME15L SME20L SME25L SME30L SME35L SME45L SME15T SME20T SME25T SME30T SME35T SME45T SME15EA SME15LEA SME20EA SME20LEA SME25EA SME25LEA SME30EA SME30LEA SME35EA SME35LEA SME45EA SME45LEA SME15EB SME15LEB SME20EB SME20LEB SME25EB SME25LEB SME15SA SME15LSA SME20SA SME20LSA SME25SA SME25LSA SME30SA SME30LSA SME35SA SME35LSA SME45SA SME45LSA SME15SB SME15LSB SME20SB SME20LSB SME25SB SME25LSB SME30SB SME30LSB SME35SB SME35LSB SME45SB SME45LSB SMA15 SMA20 SMA15A SMA20A SMA15E SMA20E SMA15S SMA20S
SMB15 SMB20 SMB25 SMB30 SMB15E SMB20E SMB25E SMB30E SMB15S SMB20S SMB25S SMB30S SMH45L SMH45 SMH45T SMH45LS M3C M4C M5C M6C M8C M12C M14C M16C M4MC M5MC M6MC M8MC M12MC M14MC M16MC
MSA15A MSA20A MSA20LA MSA25A MSA25LA MSA30 A MSA3OLA MSA35 A MSA35 LA MSA45A MSA45LA
MSA15E MSA20E MSA20LE MSA25E MSA25LE MSA30E MSA30LE MSA35E MSA35LE MSA45E MSA45LE MSA55E MSA55LE MSA65E MSA65LE
MSA15S MSA20S MSA20LS MSA25S MSA25LS MSA30S MSA30LS MSA35S MSA35LS MSA45S MSA45LS MSA55S MSA55LS MSA65S MSA65LS
HGW15CB HGW20CB HGW20HB HGW2SCB HGW25HB HGW30CB HGW30HB HGW35CB HGW35HB HGW45CB HGW45HB HGW55CB HGW55HB HGW65CB HGW65HB
Feature: | Corrosion Resistant |
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Function: | Super |
Flange Shape: | Cutting-Edge |
Shape: | Flange |
Series: | LME |
Material: | Stainless Steel |
Samples: |
US$ 20/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
| Customized Request |
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Choosing a Linear Rail
Whether you are using a linear rail for your business or home, you will find that there are some key considerations that you must keep in mind. These include the stability and accuracy of the system, as well as the cost of the rail.
Cost of linear rails
Choosing the right rail can be crucial to the performance and cost of a machine. There are many different types, with different levels of accuracy, load bearing capacity and rigidity. Some of the more common choices are drilled, profiled and undrilled.
The cost of linear rails can vary drastically depending on the type. Some are made from hardened steel, while others are fabricated from aluminum extrusions. Both types offer different advantages and disadvantages.
Rails that have been manufactured with aluminum extrusions will offer better rigidity. These rails also provide a larger range of motion.
Linear rails are generally used in mechanical systems that need high precision. These components must be fully supported and protected while being assembled. The assembly process is complex and time consuming.
These components are used in a wide variety of industrial applications. They can be used for transporting loads between two points or for guiding a moving part in linear motion.
Linear rails are usually manufactured from hardened steel, which is corrosion-resistant. Stainless steel is also commonly used. High-strength steel is also used. It is also known as cold drawn steel.
Rails have a high load bearing capacity and can handle loads from a few grams to a few tons. They offer smooth motion and can also be used to support overhung loads. Linear rails are generally used in automation machinery. They are also used in laser welding machines and bending machines.
Stiffness
Using a linear rail is a common solution for many industrial applications. These linear guides are known for their rigidity and load-bearing capabilities. They are designed to accommodate a wide variety of uses, including precision motion, high load capacities, and high speed operation.
These linear guides are available in various sizes and shapes, including cylindrical rollers, spherical balls, and race profiles. Each type offers different load capacities, speeds, and accuracy levels. They are typically used in applications that require precision, such as machine tools.
They are typically fixed at the ends. They are designed to transfer weights along a predetermined vertical or horizontal course. Linear rails are usually made of toughened steel. They require hex slot screws along the length of the rail. They are also used to guide actuators driven by screws or belts.
These linear guides are designed to offer high travel accuracy, which is important for many machine tools. They also offer high rigidity, which is needed to support heavy loads.
The stiffness of a linear rail is generally higher than that of a round rail. They can handle travel speeds up to 5 meters per second. They can support thousands of kilograms. They are also less likely to bend under heavy load, which can prevent misalignment problems.
Linear guides are often used in pneumatic-driven systems. They also have a rolling-friction operation mode. This reduces friction, which helps the machine tool to run smoothly.
Accuracy
Choosing the best linear rail depends on the application and the level of accuracy required. Some applications require high accuracy, while others are less demanding. A guide rail that has the right amount of preloading can minimize the effect of misalignment and sinking.
Rails are designed to withstand a variety of loads from a few grams to several tons. They can also handle moment and lift-off loads. Linear rails are made from high-strength steel that is galvanized.
A variety of processing methods are used to manufacture rails. Rails are available in square and round shapes. They can also be shaped to fit into smaller spaces.
The most accurate linear rail is the one that meets all of the above requirements. It can be difficult to know which rail is best for your application. It is important to consider the application and the total load conditions during the lifetime of the system.
It is also important to choose the most appropriate accuracy class for your application. Choosing the accuracy class of a rail is partially dependent on the positioning of the load and the mounting arrangement of the bearings.
For instance, the best accuracy class for a rail would be one that has a high preloading rate. This will increase the rigidity and minimize the effect of sinking. It will also increase the life of the component.
A linear rail that has a high preloading rate also has a higher accuracy class. This is because it will compensate for a lack of accuracy in the mounting surface.
Stability
Whether you’re moving items through a production process or handling heavy loads, you’ll appreciate the reliability and precision of a linear rail. It’s also important to consider the stability of your linear rail.
It’s important to design your linear rail with a complete support structure to prevent deflection. This may include mounting it on an I-beam support. This supports heavy loads and eliminates deflection concerns.
Linear rails also offer a wide range of motion, including the ability to support overhung loads. They are also suitable for guiding weights, providing a smooth motion in a single axis.
A single linear rail can also be used to guide actuators driven by screws or belts. These are commonly used in industrial applications. However, they may not be ideal for consumer applications.
For a more robust solution, you may consider using a dual rail. Dual linear rails maximize bearing life, and minimize deflection. These can also be anchored to aluminum extrusion profiles to improve stiffness.
Various types of materials can have a dramatic impact on the cost and performance of a project. These include stainless steel, which is corrosion-resistant and cold drawn. Other options include aluminum extrusion profiles and cylinders, which can reduce mechanical stresses.
In addition, the level of stiffness of your rail may be critical to its operation. In some applications, a rail may have to flex slightly in one plane. Using a cylinder instead of a sphere can also reduce play.
Sliding carriage and rail
Known for their rigidity and load-bearing capabilities, linear slides are ideal for applications that require repeatable motion. However, these units have a variety of components that can complicate their integration into your machine. Fortunately, there are a variety of products available that can help you find the right slide.
The main components of a linear slide include the carriage, bearings, guide rails, and control systems. The bearing system determines the accuracy of the slide.
Bearings can be a variety of shapes, including cylindrical and ball. They can be plain or filled with PTFE, ceramic, or metal. A ball screw drive with a motor may be necessary for stiff, reproducible slides. In less expensive applications, a round shaft system may be the best option.
Typically, the carriage is attached to the rail. The rail supports the carriage while it moves, and it can be a round rail, profiled rail, or linear stage. The carriage can be made of stainless steel, aluminum, granite, or other materials. Its threaded holes can be used for mounting tooling.
Carriage designs can be based on plain bearings, ball bearings, or cross rollers. Aside from simple surface bearings, these designs require lubrication. In less expensive applications, plain bearings may be sufficient.
Roller bearings are cylindrical roller load-bearing elements. They are used in track rollers and cam rollers. The rollers are inside the carriage and rotate with the carriage.
Applications
Whether you’re building an industrial automation system or simply need to move a load, the right linear guide can be a valuable tool. The benefits include high load capacity, reduced friction, high rigidity and increased accuracy.
The applications of linear rails can range from simple machine-tool applications to advanced medical applications. The most common applications include transportation and industrial machinery. However, the applications can also be found in the consumer space. Consumer health monitoring devices are a great example of applications that take advantage of linear motion.
Linear rails are a linear assembly consisting of load-supporting balls on each side and a pair of parallel tracks. Depending on the size and type of application, the load capacity can range from a few grams to several tons.
Linear rails are typically made from high-strength steel, which is profiled or galvanised. The rail is then cut to a specified length. Depending on the size, the cost of a linear guide rail will vary.
The linear rail’s name is a mouthful, but there are several models to choose from. Profiled rail guides are most suitable for high load applications.
The CZPT is a great choice for heavy-duty applications. It’s easily weldable, and can be ground smooth for easy transitions. The rail can be extended to long travel lengths.
The linear rail’s most notable attribute is its ability to withstand overhung loads. The rail can also handle moment and horizontal loads.
editor by CX 2023-04-12