China Hot selling P Class Sp Class Interchangeable Linear Rail

Product Description

ZCF BRIEF INTRODUCTION:                                                                                       
ZCF PRECISION TECHNOLOGY(HangZhou) CO.,LTD. IS A PROFESSIONAL MANUFACTURER OFLINEARXIHU (WEST LAKE) DIS.,LINEAR MODULE AND BALL SCREW ETC.SHE IS LOCATED IN HangZhou CITY,ZheJiang ,CHINA.THE NEW FACTORY COVERS 33333 SQUARE CHINAMFG AND HOLDS A BUILDING AREA OF 16000 SQUARE CHINAMFG AT PRESENT. WITH OVER 10 YEARS’ EFFORT OF OUR WHOLE TEAM. AND ALSO TRUST AND SUPPORT FROM OUR RESPECTED CUSTOMERS. WE ARE SO LUCKY TO BECOME ONE STRONG BRAND IN CHINA, WHO MAKE INTERNATIONAL STHangZhouRD PRODUCTS.WE AIM SERVE CUSTOMERS WORLDWIDELY.

PRODUCTS PHOTOS:

CH SERIES BODY STRUCTURE:
 

1.ROLLING CYCLE SYSTEM: SLIDER, XIHU (WEST LAKE) DIS. RAIL, END COVER, STEEL BALL, BALL HOLDER;

2.LUBRICATION SYSTEM: OIL NOZZLE AND TUBING JOINT

3.DUST-PROOF SYSTEM: OIL SCRAPER, NEGATIVE DUST SEAL DUST-PROOF SHEET, XIHU (WEST LAKE) DIS. RAIL BOLT COVER, METAL SCRAPER

 

ACCURACY LEVEL
 

1. THE ACCURACY OF CH SERIES LINEAR XIHU (WEST LAKE) DIS.S CAN BE DIVIDED INTO FIVE LEVELS: COMMON, HIGH, PRECISION, SUPER-PRECISION AND ULTRA-PRECISION. CUSTOMERS CAN CHOOSE THE ACCURACY LEVEL ACCORDING TO THE ACCURACY REQUIREMENT OF EQUIPMENT.
 

2.  ACCURACY OF NON-INTERCHANGEABLE LINEAR XIHU (WEST LAKE) DIS.:

MODEL CH – 15, 20          unit : mm
ACCURACY LEVEL COMMON HIGH PRECISION HIGH-PRECISION ULTRA-PRECISION
(C) (H) (P) (SP) (UP)
TOLERANCE OF H ± 0.1 ± 0.03 0- 0.03 0- 0.015 0- 0.008
TOLERANCE OF N ± 0.1 ± 0.03 0- 0.03 0- 0.015 0- 0.008
TOLERANCE OF MUTUAL H 0.02 0.01 0.006 0.004 0.003
TOLERANCE OF MUTUAL N 0.02 0.01 0.006 0.004 0.003
MOTION PARALLELISM OF C ON A MOTION ACURACY
MOTION PARALLELISM OF D ON B MOTION ACURACY

 

MODEL CH – 25,30,35        unit : mm
ACCURACY LEVEL COMMON HIGH PRECISION HIGH-PRECISION ULTRA-PRECISION
(C) (H) (P) (SP) (UP)
TOLERANCE OF H ± 0.1 ± 0.04 0- 0.04 0- 0.02 0- 0.01
TOLERANCE OF N ± 0.1 ± 0.04 0- 0.04 0- 0.02 0- 0.01
TOLERANCE OF MUTUAL H 0.02 0.015 0.007 0.005 0.003
TOLERANCE OF MUTUAL N 0.03 0.015 0.007 0.005 0.003
MOTION PARALLELISM OF C ON A MOTION ACURACY
MOTION PARALLELISM OF D ON B MOTION ACURACY

 

MODEL CH – 45,55          unit : mm
ACCURACY LEVEL COMMON HIGH PRECISION HIGH-PRECISION ULTRA-PRECISION
  (C) (H) (P) (SP) (UP)
TOLERANCE OF H ± 0.1 ± 0.05 0- 0.05 0- 0.03 0- 0.02
TOLERANCE OF N ± 0.1 ± 0.05 0- 0.05 0- 0.03 0- 0.02
TOLERANCE OF MUTUAL H 0.03 0.015 0.007 0.005 0.003
TOLERANCE OF MUTUAL N 0.03 0.02 0.01 0.007 0.005
MOTION PARALLELISM OF C ON A MOTION ACURACY
MOTION PARALLELISM OF D ON B MOTION ACURACY

3. MOTION ACCURACY CHART

RAIL LENGTH (mm) ACCURACY LEVEL (µm)
C H P SP UP
~ 100 12 7 3 2 2
100 ~ 200 14 9 4 2 2
200 ~ 300 15 10 5 3 2
300 ~ 500 17 12 6 3 2
500 ~ 700 20 13 7 4 2
700 ~ 900 22 15 8 5 3
900 ~ 1,100 24 16 9 6 3
1,100 ~ 1,500 26 18 11 7 4
1,500 ~ 1,900 28 20 13 8 4
1,900 ~ 2,500 31 22 15 10 5
2,500 ~ 3,100 33 25 18 11 6
3,100 ~ 3,600 36 27 20 14 7
3,600 ~ 4,000 37 28 21 15 7

SELECTION CRITERIA

1. PRODUCT APPLICATIONS:

1). CH SERIES: GRINDING MACHINE, MILLING MACHINE, LATHE, DRILLING MACHINE, INTEGRATED PROCESSING MACHINE, EDM MACHINE, BORING MACHINE, WIRE CUTTING MACHINE, PRECISION

2). CE SERIES: INDUSTRIAL AUTOMATION MACHINERY, SEMICONDUCTOR MACHINERY, LASER ENGRAVING MACHINE, PACKAGING MACHINE;

3). CGN/CGW SERIES: PRINTER, MACHINE ARM, ELECTRONIC INSTRUMENT AND SEMICONDUCTOR EQUIPMENT.

 

2. SELECTION OF ACCURACY LEVEL:

C, H, P, SP, UP LEVELS DEPEND ON EQUIPMENT ACCURACY REQUIREMENTS.
 

3. SELECTION OF SIZE:

1). ACCORDING TO EXPERIENCE;

2). LOAD STATUS;

3). IF LINEAR XIHU (WEST LAKE) DIS.WAY IS USED IN CONJUNCTION WITH BALL SCREW, SELECT SIMILAR SIZE AS EXTERNAL DIAMETER OF THE SCREW. IF THE EXTERNAL DIAMETER OF THE SCREW IS 35 MM, SELECT CH35.

 

4. CALCULATING THE MAXIMUM LOAD OF SLIDER:

1). CALCULATING THE MAXIMUM EQUIVALENT LOAD OF A SINGLE SLIDER WITH REFERENCE TO THE LOAD CALCULATION TABLE

2). CONFIRMATION THAT THE STATIC SAFETY FACTOR OF THE SELECTED STRAIGHT-LINE XIHU (WEST LAKE) DIS. SHOULD EXCEED THE VALUE LISTED IN THE TABLE OF STATIC SAFETY FACTOR

LUBRICATION:

IF THE LINEAR XIHU (WEST LAKE) DIS. IS NOT PROPERLY LUBRICATED, THE FRICTION OF ROLLING PARTS WILL INCREASE, AND LONG-TERM USE WILL BECOME THE MAIN REASON FOR SHORTENING THE LIFE. LUBRICANTS PROVIDE THE FOLLOWING FUNCTIONS:

(1). REDUCE FRICTION OF ROLLING PARTS, PREVENT BURNS AND REDUCE WEAR;

(2). FORMING OIL FILM BETWEEN ROLLING SURFACE AND ROLLING SURFACE CAN PROLONG ROLLING FATIGUE LIFE;

(3). PREVENTING RUST.

 

1. GREASE LUBRICATION:

EACH GROUP OF LINEAR XIHU (WEST LAKE) DIS.WAYS CAN BE SEALED WITH LITHIUM SOAP-BASED GREASE TO LUBRICATE THE BEAD GROOVE TRACK BEFORE LEAVING THE FACTORY. ALTHOUGH THE GREASE IS NOT EASY TO LOSE, IN ORDER TO AVOID INSUFFICIENT LUBRICATION CAUSED BY LUBRICATION LOSS, IT IS SUGGESTED THAT CUSTOMERS SHOULD SUPPLEMENT THE GREASE ONCE MORE WHEN THE DISTANCE REACHES 100 KM. AT THIS TIME, GREASE CAN BE INJECTED INTO THE SLIDER BY MEANS OF THE OIL NOZZLE ATTACHED TO THE SLIDER. LUBRICATING GREASE IS SUITABLE FOR SITUATIONS WHERE THE SPEED IS NOT MORE THAN 60 M/MIN AND THE COOLING EFFECT IS NOT REQUIRED.
T : OIL INJECTION FREQUENCY (hour);  Ve : SPEED (m/min)
 

2. OIL (OIL) LUBRICATION:

IT IS RECOMMENDED THAT CUSTOMERS USE LUBRICATING OIL WITH A CONSISTENCY OF ABOUT 32-150 CHINAMFG TO LUBRICATE LINEAR XIHU (WEST LAKE) DIS.S. CHINAMFG CAN INSTALL THE TUBING JOINT AT THE ORIGINAL POSITION OF THE OIL DISCHARGE NOZZLE ACCORDING TO THE CUSTOMER’S NEEDS, SO THE CUSTOMER ONLY NEEDS TO CONNECT THE PRESET TUBING OF THE MACHINE TO THE TUBING JOINT. THE LOSS OF LUBRICATING OIL IS FASTER THAN THAT OF LUBRICATING GREASE. WHEN USING, ATTENTION MUST BE PAID TO THE ADEQUACY OF OIL SUPPLY. IF INSUFFICIENT LUBRICATION EASILY CAUSES ABNORMAL WEAR OF LINEAR XIHU (WEST LAKE) DIS.S AND REDUCES THEIR SERVICE LIFE, IT IS SUGGESTED THAT THE FREQUENCY OF LUBRICATING OIL SHOULD BE ABOUT 0.3CM3/HR. CUSTOMERS CAN USE IT ACCORDING TO THEIR USE CONDITIONS. LUBRICATING OIL IS SUITABLE FOR VARIOUS LOADS AND SPEEDS, BUT IT IS NOT SUITABLE FOR HIGH TEMPERATURE LUBRICATION BECAUSE OF ITS VOLATILITY.

DUST-PROOF DEVICE(OPTIONS)
 

1. DUST-PROOF DEVICE CODE:

IF YOU NEED THE FOLLOWING DUST-PROOF EQUIPMENT, PLEASE ADD THE CODE AFTER THE PRODUCT MODEL.

INSTALLATION OF LINEAR XIHU (WEST LAKE) DIS.WAY

THE INSTALLATION METHOD OF LINEAR XIHU (WEST LAKE) DIS. MUST BE SET ACCORDING TO THE OPERATING CONDITION OF THE MACHINE, SUCH AS THE DEGREE OF VIBRATION AND IMPACT FORCE, THE REQUIRED WALKING ACCURACY AND THE LIMITATION OF THE MACHINE.WHEN PAIRING NON-INTERCHANGEABLE LINEAR XIHU (WEST LAKE) DIS.S, ATTENTION SHOULD BE PAID TO THE DIFFERENCE BETWEEN THE REFERENCE RAIL AND THE DRIVEN RAIL. THE ACCURACY OF THE DATUM LEVEL ON THE SIDE OF THE DATUM RAIL IS HIGHER THAN THAT OF THE DRIVEN RAIL, SO IT CAN BE USED AS THE SUPPORTING SURFACE FOR THE BED INSTALLATION. THE REFERENCE RAIL IS MARKED WITH MA, AS SHOWN IN THE FIGURE.

 

1. FIXING METHODS

WHEN THE BED IS SUBJECTED TO VIBRATION AND IMPACT FORCE, THE XIHU (WEST LAKE) DIS. RAIL AND SLIDER MAY DEVIATE FROM THE ORIGINAL FIXED POSITION AND AFFECT THE ACCURACY. IN ORDER TO AVOID SIMILAR SITUATION, IT IS SUGGESTED TO USE THE FOUR FIXED WAYS LISTED BELOW TO FIX THE XIHU (WEST LAKE) DIS. RAIL AND SLIDER TO ENSURE THE ACCURACY OF THE MACHINE.

 

2. INSTALLATION OF LINEAR RAIL:

 

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Application: Machines
Material: S55c
Structure: Machine Table
Installation: All
Driven Type: N/a
Carrying Capacity: Weight Level
Samples:
US$ 100/Meter
1 Meter(Min.Order)

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Customization:
Available

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linear rail

Can you describe the various mounting options and installations for linear rails in different settings?

Linear rails can be mounted in various configurations to suit different settings and applications. The choice of mounting options depends on factors such as space constraints, load requirements, and the desired motion characteristics. Here are some common mounting options and installations:

1. Horizontal Mounting: Linear rails are horizontally mounted when the desired linear motion is along the horizontal axis. This configuration is commonly used in applications such as CNC machines, where the tool needs to move horizontally across the workpiece.

2. Vertical Mounting: Vertical mounting involves installing linear rails to support vertical linear motion. This configuration is prevalent in applications like vertical machining centers, where the spindle moves vertically to perform machining operations on the workpiece.

3. Inverted Mounting: Inverted mounting is where the linear rail is installed upside down. This configuration is suitable when space limitations or specific design requirements dictate the need for the rail to be positioned below the moving component. Inverted mounting is common in some types of robotic systems.

4. Parallel Mounting: Linear rails can be mounted in parallel to support multiple carriages or moving components. This configuration is beneficial in applications where synchronized linear motion is required, such as in certain types of material handling systems or conveyor belts.

5. Cantilever Mounting: Cantilever mounting involves mounting the linear rail with one end extending beyond a support structure. This configuration is used when access to one side of the linear motion is required, such as in loading and unloading stations on manufacturing lines.

6. Tandem Mounting: Tandem mounting involves mounting multiple linear rails in tandem to share the load and provide additional support. This configuration is suitable for applications with heavy loads or long travel distances, ensuring stability and preventing deflection.

7. Floating Mounting: Floating mounting allows for some degree of flexibility in the alignment of the linear rail. This is useful in applications where there may be minor misalignments or variations in the mounting surface.

The choice of mounting option depends on the specific requirements of the application, and engineers must carefully consider factors such as load distribution, accessibility, and alignment to ensure optimal performance and longevity of the linear rail system.

linear rail

How do innovations and advancements in linear rail technology impact their use?

Innovations and advancements in linear rail technology have a profound impact on their use, influencing performance, efficiency, and application possibilities. Here are key ways in which technological advancements impact the use of linear rails:

  • 1. Enhanced Precision: Advancements in manufacturing processes and materials contribute to higher precision in the design and production of linear rails. This results in improved accuracy and repeatability in linear motion applications, making them suitable for tasks requiring intricate and precise movements, such as in CNC machining and 3D printing.
  • 2. Increased Load Capacities: Ongoing innovations allow for the development of linear rails with increased load-bearing capabilities. This is particularly beneficial in industries and applications where heavy loads need to be moved with precision, such as in industrial automation and material handling systems.
  • 3. Integration of Smart Technologies: The integration of smart technologies, such as sensors and feedback systems, enhances the monitoring and control capabilities of linear rail systems. This facilitates real-time data collection, predictive maintenance, and improved overall system efficiency, particularly in automated and Industry 4.0 settings.
  • 4. Energy Efficiency: Innovations in lubrication systems and materials contribute to increased energy efficiency in linear rail operation. Reduced friction and optimized designs help minimize energy consumption, making linear rails more environmentally friendly and cost-effective over their lifespan.
  • 5. Customization and Modularity: Advanced manufacturing techniques enable greater customization and modularity in linear rail systems. Engineers can tailor linear rails to specific application needs, adjusting parameters such as length, load capacity, and material composition for optimal performance in diverse industrial and automation scenarios.
  • 6. Durability and Longevity: Continuous improvements in materials and surface treatments enhance the durability and longevity of linear rails. This is particularly beneficial in applications where reliability and minimal maintenance are critical, such as in aerospace testing equipment and high-precision manufacturing.

Overall, innovations in linear rail technology contribute to a broader range of applications, improved performance metrics, and the ability to meet the evolving needs of diverse industries. As technology continues to advance, the versatility and effectiveness of linear rails in various industrial and automation settings are likely to expand even further.

linear rail

How do linear rails differ from other linear motion components like linear guides or bearings?

While linear rails, linear guides, and bearings are all components used in linear motion systems, they differ in their design, functions, and applications:

Linear Rails: Linear rails typically consist of a long, rigid rail and a carriage that moves along the rail. The rail has a specially designed profile to provide guidance, and the carriage supports and carries the load. Linear rails are known for their ability to handle high loads, offer precise linear motion, and reduce friction for smooth movement.

Linear Guides: Linear guides encompass a broader category that includes linear rails. Linear guides refer to any mechanism that guides linear motion. Linear rails are a specific type of linear guide with a distinctive profile. Linear guides, in a general sense, can include other mechanisms like dovetail slides, boxway guides, and more, each with its own design and application.

Bearings: Bearings are components that reduce friction between moving parts and support radial or axial loads. While linear rails may incorporate bearings within their design, bearings, in a broader sense, can be standalone components used to support rotating or linear motion. Linear bearings, for example, specifically support linear motion and may be used independently or as part of a linear rail system.

In summary, linear rails are a specific type of linear guide with a defined rail and carriage design, whereas linear guides encompass a broader category. Bearings, on the other hand, are components that reduce friction and support loads, and linear bearings specifically cater to linear motion.

China Hot selling P Class Sp Class Interchangeable Linear Rail  China Hot selling P Class Sp Class Interchangeable Linear Rail
editor by Dream 2024-05-14