Tag Archives: cnc machine 5 axis

China supplier Sumore CE Approved Made in Shanghai China Vertical Milling Machine 5 Axis CNC Vmc with Great quality

Product Description

Product Description

Factory direct Sale High Precision Small VMC CNC Machining Center SMC8450
(VMC from small to big size, the web pages are limited, so please contact us for more details)

As 1 new product of independent design & development, SMC8450 is a multi-purpose machine which could mill surface & drill holes. This machine adopts domestic/overseas branded numerical control system and realizes full-screen edition in Chinese. Spindle adopts imported frequency converters, which could fulfill variable speed control & constant linear speed cutting functions; machining body adopts ultrasonic frequency hardening treatment; both X-axle & Z-axle adopts step/servo motor, which could process feeding motion by directly connecting shaft coupling & ball screws.

With high power, pleasant rigidity, high precision & storage, high price-quality ratio and long cycle life, the machine is widely applied to instruments, meters, light industries, electronics, home appliances, medical instruments, aeronautics & astronautics and etc. industries, it is 1 small-medium precision & complex machine for processing various materials (especially non-ferrous metals & stainless steel) as well as an ideal equipments for large automation production.

This machine could process holes below ∮16, milling plane below 18 and milling depth below 3mm.

.

Product Parameters

Model SMC8450
Worktable Size 800X260mm
Travel(Longitudinal X/Horizontal Y/Vertical Z) 500X320X450mm
Main Motor Power   3.7KW
Spindle Max. Rotating Speed Servo Spindle 6000rpm (optional 8000rpm 10000rpm)
Z Motor Torque 7.7N.m
X Motor Torque 6N.m
Y Motor Torque 6N.m
Spindle Taper BT40
Distance of Spindle Axis to Xihu (West Lake) Dis.way Plane 360mm
Distance of Spindle End to Worktable 90-470mm
The Vertical Permissible Error of Spindle Axis to Worktable Plane ≤0.02mm
Positioning Accuracy 0.01mm
Repeated Positioning Accuracy 0.02mm
Machine Overall Dimension   2600*1950*2400mm
Net/Gross Weight 2200/2300kgs
Packing size 2270x1880x2500mm

Company Profile

As the professional and experienced manufacturer of lathe, mill , drill , cnc and other tools ,ZheJiang SUMORE Industrial Group has been in this filed for more than 20 years.

We have got the certificates of CE, GS ,Rohs , CSA ,UL ,etc . Also we have been in business with GSK ,Siemens ,Faunc and other famous companies within 50 countries all over the world.

Whether you need the standard or the customerised products , please contact us directly . Our professional and experienced engineers and after sale service team will meet your needs.

Hope to cooperate with you!

How to Calculate Stiffness, Centering Force, Wear and Fatigue Failure of Spline Couplings

There are various types of spline couplings. These couplings have several important properties. These properties are: Stiffness, Involute splines, Misalignment, Wear and fatigue failure. To understand how these characteristics relate to spline couplings, read this article. It will give you the necessary knowledge to determine which type of coupling best suits your needs. Keeping in mind that spline couplings are usually spherical in shape, they are made of steel.
splineshaft

Involute splines

An effective side interference condition minimizes gear misalignment. When 2 splines are coupled with no spline misalignment, the maximum tensile root stress shifts to the left by 5 mm. A linear lead variation, which results from multiple connections along the length of the spline contact, increases the effective clearance or interference by a given percentage. This type of misalignment is undesirable for coupling high-speed equipment.
Involute splines are often used in gearboxes. These splines transmit high torque, and are better able to distribute load among multiple teeth throughout the coupling circumference. The involute profile and lead errors are related to the spacing between spline teeth and keyways. For coupling applications, industry practices use splines with 25 to 50-percent of spline teeth engaged. This load distribution is more uniform than that of conventional single-key couplings.
To determine the optimal tooth engagement for an involved spline coupling, Xiangzhen Xue and colleagues used a computer model to simulate the stress applied to the splines. The results from this study showed that a “permissible” Ruiz parameter should be used in coupling. By predicting the amount of wear and tear on a crowned spline, the researchers could accurately predict how much damage the components will sustain during the coupling process.
There are several ways to determine the optimal pressure angle for an involute spline. Involute splines are commonly measured using a pressure angle of 30 degrees. Similar to gears, involute splines are typically tested through a measurement over pins. This involves inserting specific-sized wires between gear teeth and measuring the distance between them. This method can tell whether the gear has a proper tooth profile.
The spline system shown in Figure 1 illustrates a vibration model. This simulation allows the user to understand how involute splines are used in coupling. The vibration model shows 4 concentrated mass blocks that represent the prime mover, the internal spline, and the load. It is important to note that the meshing deformation function represents the forces acting on these 3 components.
splineshaft

Stiffness of coupling

The calculation of stiffness of a spline coupling involves the measurement of its tooth engagement. In the following, we analyze the stiffness of a spline coupling with various types of teeth using 2 different methods. Direct inversion and blockwise inversion both reduce CPU time for stiffness calculation. However, they require evaluation submatrices. Here, we discuss the differences between these 2 methods.
The analytical model for spline couplings is derived in the second section. In the third section, the calculation process is explained in detail. We then validate this model against the FE method. Finally, we discuss the influence of stiffness nonlinearity on the rotor dynamics. Finally, we discuss the advantages and disadvantages of each method. We present a simple yet effective method for estimating the lateral stiffness of spline couplings.
The numerical calculation of the spline coupling is based on the semi-analytical spline load distribution model. This method involves refined contact grids and updating the compliance matrix at each iteration. Hence, it consumes significant computational time. Further, it is difficult to apply this method to the dynamic analysis of a rotor. This method has its own limitations and should be used only when the spline coupling is fully investigated.
The meshing force is the force generated by a misaligned spline coupling. It is related to the spline thickness and the transmitting torque of the rotor. The meshing force is also related to the dynamic vibration displacement. The result obtained from the meshing force analysis is given in Figures 7, 8, and 9.
The analysis presented in this paper aims to investigate the stiffness of spline couplings with a misaligned spline. Although the results of previous studies were accurate, some issues remained. For example, the misalignment of the spline may cause contact damages. The aim of this article is to investigate the problems associated with misaligned spline couplings and propose an analytical approach for estimating the contact pressure in a spline connection. We also compare our results to those obtained by pure numerical approaches.

Misalignment

To determine the centering force, the effective pressure angle must be known. Using the effective pressure angle, the centering force is calculated based on the maximum axial and radial loads and updated Dudley misalignment factors. The centering force is the maximum axial force that can be transmitted by friction. Several published misalignment factors are also included in the calculation. A new method is presented in this paper that considers the cam effect in the normal force.
In this new method, the stiffness along the spline joint can be integrated to obtain a global stiffness that is applicable to torsional vibration analysis. The stiffness of bearings can also be calculated at given levels of misalignment, allowing for accurate estimation of bearing dimensions. It is advisable to check the stiffness of bearings at all times to ensure that they are properly sized and aligned.
A misalignment in a spline coupling can result in wear or even failure. This is caused by an incorrectly aligned pitch profile. This problem is often overlooked, as the teeth are in contact throughout the involute profile. This causes the load to not be evenly distributed along the contact line. Consequently, it is important to consider the effect of misalignment on the contact force on the teeth of the spline coupling.
The centre of the male spline in Figure 2 is superposed on the female spline. The alignment meshing distances are also identical. Hence, the meshing force curves will change according to the dynamic vibration displacement. It is necessary to know the parameters of a spline coupling before implementing it. In this paper, the model for misalignment is presented for spline couplings and the related parameters.
Using a self-made spline coupling test rig, the effects of misalignment on a spline coupling are studied. In contrast to the typical spline coupling, misalignment in a spline coupling causes fretting wear at a specific position on the tooth surface. This is a leading cause of failure in these types of couplings.
splineshaft

Wear and fatigue failure

The failure of a spline coupling due to wear and fatigue is determined by the first occurrence of tooth wear and shaft misalignment. Standard design methods do not account for wear damage and assess the fatigue life with big approximations. Experimental investigations have been conducted to assess wear and fatigue damage in spline couplings. The tests were conducted on a dedicated test rig and special device connected to a standard fatigue machine. The working parameters such as torque, misalignment angle, and axial distance have been varied in order to measure fatigue damage. Over dimensioning has also been assessed.
During fatigue and wear, mechanical sliding takes place between the external and internal splines and results in catastrophic failure. The lack of literature on the wear and fatigue of spline couplings in aero-engines may be due to the lack of data on the coupling’s application. Wear and fatigue failure in splines depends on a number of factors, including the material pair, geometry, and lubrication conditions.
The analysis of spline couplings shows that over-dimensioning is common and leads to different damages in the system. Some of the major damages are wear, fretting, corrosion, and teeth fatigue. Noise problems have also been observed in industrial settings. However, it is difficult to evaluate the contact behavior of spline couplings, and numerical simulations are often hampered by the use of specific codes and the boundary element method.
The failure of a spline gear coupling was caused by fatigue, and the fracture initiated at the bottom corner radius of the keyway. The keyway and splines had been overloaded beyond their yield strength, and significant yielding was observed in the spline gear teeth. A fracture ring of non-standard alloy steel exhibited a sharp corner radius, which was a significant stress raiser.
Several components were studied to determine their life span. These components include the spline shaft, the sealing bolt, and the graphite ring. Each of these components has its own set of design parameters. However, there are similarities in the distributions of these components. Wear and fatigue failure of spline couplings can be attributed to a combination of the 3 factors. A failure mode is often defined as a non-linear distribution of stresses and strains.

China supplier Sumore CE Approved Made in Shanghai China Vertical Milling Machine 5 Axis CNC Vmc with Great qualityChina supplier Sumore CE Approved Made in Shanghai China Vertical Milling Machine 5 Axis CNC Vmc with Great quality

China Custom 4 5 Axis CNC Milling Machine Manufacturer 7126 Vertical Machining Center Sp8126 near me manufacturer

Product Description

Product Description

SP8126 4 5 axis cnc milling machine manufacturer 7126 vertical machining center  NEW 3 4th VMC Vertical cnc metal milling machine center mini small CNC machining center with 800X260MM table Factory direct Sale High Precision Small VMC Vertical CNC Machining Center New Condition Automatic Smallest 4 Axis Vertical CNC Milling Center Machine SMC8450
(VMC from small to big size, the web pages are limited, so please contact us for more details)

As 1 new product of independent design & development, SMC8450 is a multi-purpose machine which could mill surface & drill holes. This machine adopts domestic/overseas branded numerical control system and realizes full-screen edition in Chinese. Spindle adopts imported frequency converters, which could fulfill variable speed control & constant linear speed cutting functions; machining body adopts ultrasonic frequency hardening treatment; both X-axle & Z-axle adopts step/servo motor, which could process feeding motion by directly connecting shaft coupling & ball screws.

With high power, pleasant rigidity, high precision & storage, high price-quality ratio and long cycle life, the machine is widely applied to instruments, meters, light industries, electronics, home appliances, medical instruments, aeronautics & astronautics and etc. industries, it is 1 small-medium precision & complex machine for processing various materials (especially non-ferrous metals & stainless steel) as well as an ideal equipments for large automation production.

This machine could process holes below ∮16, milling plane below 18 and milling depth below 3mm.

.

Product Parameters

Model SMC8450
Worktable Size 800X260mm
Travel(Longitudinal X/Horizontal Y/Vertical Z) 500X320X450mm
Main Motor Power   3.7KW
Spindle Max. Rotating Speed Servo Spindle 6000rpm (optional 8000rpm 10000rpm)
Z Motor Torque 7.7N.m
X Motor Torque 6N.m
Y Motor Torque 6N.m
Spindle Taper BT40
Distance of Spindle Axis to Xihu (West Lake) Dis.way Plane 360mm
Distance of Spindle End to Worktable 90-470mm
The Vertical Permissible Error of Spindle Axis to Worktable Plane ≤0.02mm
Positioning Accuracy 0.01mm
Repeated Positioning Accuracy 0.02mm
Machine Overall Dimension   2600*1950*2400mm
Net/Gross Weight 2200/2300kgs
Packing size 2270x1880x2500mm

Company Profile

As the professional and experienced manufacturer of lathe, mill , drill , cnc and other tools ,ZheJiang SUMORE Industrial Group has been in this filed for more than 20 years.

We have got the certificates of CE, GS ,Rohs , CSA ,UL ,etc . Also we have been in business with GSK ,Siemens ,Faunc and other famous companies within 50 countries all over the world.

Whether you need the standard or the customerised products , please contact us directly . Our professional and experienced engineers and after sale service team will meet your needs.

Hope to cooperate with you!

Types of Splines

There are 4 types of splines: Involute, Parallel key, helical, and ball. Learn about their characteristics. And, if you’re not sure what they are, you can always request a quotation. These splines are commonly used for building special machinery, repair jobs, and other applications. The CZPT Manufacturing Company manufactures these shafts. It is a specialty manufacturer and we welcome your business.
splineshaft

Involute splines

The involute spline provides a more rigid and durable structure, and is available in a variety of diameters and spline counts. Generally, steel, carbon steel, or titanium are used as raw materials. Other materials, such as carbon fiber, may be suitable. However, titanium can be difficult to produce, so some manufacturers make splines using other constituents.
When splines are used in shafts, they prevent parts from separating during operation. These features make them an ideal choice for securing mechanical assemblies. Splines with inward-curving grooves do not have sharp corners and are therefore less likely to break or separate while they are in operation. These properties help them to withstand high-speed operations, such as braking, accelerating, and reversing.
A male spline is fitted with an externally-oriented face, and a female spline is inserted through the center. The teeth of the male spline typically have chamfered tips to provide clearance with the transition area. The radii and width of the teeth of a male spline are typically larger than those of a female spline. These specifications are specified in ANSI or DIN design manuals.
The effective tooth thickness of a spline depends on the involute profile error and the lead error. Also, the spacing of the spline teeth and keyways can affect the effective tooth thickness. Involute splines in a splined shaft are designed so that at least 25 percent of the spline teeth engage during coupling, which results in a uniform distribution of load and wear on the spline.

Parallel key splines

A parallel splined shaft has a helix of equal-sized grooves around its circumference. These grooves are generally parallel or involute. Splines minimize stress concentrations in stationary joints and allow linear and rotary motion. Splines may be cut or cold-rolled. Cold-rolled splines have more strength than cut spines and are often used in applications that require high strength, accuracy, and a smooth surface.
A parallel key splined shaft features grooves and keys that are parallel to the axis of the shaft. This design is best suited for applications where load bearing is a primary concern and a smooth motion is needed. A parallel key splined shaft can be made from alloy steels, which are iron-based alloys that may also contain chromium, nickel, molybdenum, copper, or other alloying materials.
A splined shaft can be used to transmit torque and provide anti-rotation when operating as a linear guide. These shafts have square profiles that match up with grooves in a mating piece and transmit torque and rotation. They can also be easily changed in length, and are commonly used in aerospace. Its reliability and fatigue life make it an excellent choice for many applications.
The main difference between a parallel key splined shaft and a keyed shaft is that the former offers more flexibility. They lack slots, which reduce torque-transmitting capacity. Splines offer equal load distribution along the gear teeth, which translates into a longer fatigue life for the shaft. In agricultural applications, shaft life is essential. Agricultural equipment, for example, requires the ability to function at high speeds for extended periods of time.
splineshaft

Involute helical splines

Involute splines are a common design for splined shafts. They are the most commonly used type of splined shaft and feature equal spacing among their teeth. The teeth of this design are also shorter than those of the parallel spline shaft, reducing stress concentration. These splines can be used to transmit power to floating or permanently fixed gears, and reduce stress concentrations in the stationary joint. Involute splines are the most common type of splined shaft, and are widely used for a variety of applications in automotive, machine tools, and more.
Involute helical spline shafts are ideal for applications involving axial motion and rotation. They allow for face coupling engagement and disengagement. This design also allows for a larger diameter than a parallel spline shaft. The result is a highly efficient gearbox. Besides being durable, splines can also be used for other applications involving torque and energy transfer.
A new statistical model can be used to determine the number of teeth that engage for a given load. These splines are characterized by a tight fit at the major diameters, thereby transferring concentricity from the shaft to the female spline. A male spline has chamfered tips for clearance with the transition area. ANSI and DIN design manuals specify the different classes of fit.
The design of involute helical splines is similar to that of gears, and their ridges or teeth are matched with the corresponding grooves in a mating piece. It enables torque and rotation to be transferred to a mate piece while maintaining alignment of the 2 components. Different types of splines are used in different applications. Different splines can have different levels of tooth height.

Involute ball splines

When splines are used, they allow the shaft and hub to engage evenly over the shaft’s entire circumference. Because the teeth are evenly spaced, the load that they can transfer is uniform and their position is always the same regardless of shaft length. Whether the shaft is used to transmit torque or to transmit power, splines are a great choice. They provide maximum strength and allow for linear or rotary motion.
There are 3 basic types of splines: helical, crown, and ball. Crown splines feature equally spaced grooves. Crown splines feature involute sides and parallel sides. Helical splines use involute teeth and are often used in small diameter shafts. Ball splines contain a ball bearing inside the splined shaft to facilitate rotary motion and minimize stress concentration in stationary joints.
The 2 types of splines are classified under the ANSI classes of fit. Fillet root splines have teeth that mesh along the longitudinal axis of rotation. Flat root splines have similar teeth, but are intended to optimize strength for short-term use. Both types of splines are important for ensuring the shaft aligns properly and is not misaligned.
The friction coefficient of the hub is a complex process. When the hub is off-center, the center moves in predictable but irregular motion. Moreover, when the shaft is centered, the center may oscillate between being centered and being off-center. To compensate for this, the torque must be adequate to keep the shaft in its axis during all rotation angles. While straight-sided splines provide similar centering, they have lower misalignment load factors.
splineshaft

Keyed shafts

Essentially, splined shafts have teeth or ridges that fit together to transfer torque. Because splines are not as tall as involute gears, they offer uniform torque transfer. Additionally, they provide the opportunity for torque and rotational changes and improve wear resistance. In addition to their durability, splined shafts are popular in the aerospace industry and provide increased reliability and fatigue life.
Keyed shafts are available in different materials, lengths, and diameters. When used in high-power drive applications, they offer higher torque and rotational speeds. The higher torque they produce helps them deliver power to the gearbox. However, they are not as durable as splined shafts, which is why the latter is usually preferred in these applications. And while they’re more expensive, they’re equally effective when it comes to torque delivery.
Parallel keyed shafts have separate profiles and ridges and are used in applications requiring accuracy and precision. Keyed shafts with rolled splines are 35% stronger than cut splines and are used where precision is essential. These splines also have a smooth finish, which can make them a good choice for precision applications. They also work well with gears and other mechanical systems that require accurate torque transfer.
Carbon steel is another material used for splined shafts. Carbon steel is known for its malleability, and its shallow carbon content helps create reliable motion. However, if you’re looking for something more durable, consider ferrous steel. This type contains metals such as nickel, chromium, and molybdenum. And it’s important to remember that carbon steel is not the only material to consider.

China Custom 4 5 Axis CNC Milling Machine Manufacturer 7126 Vertical Machining Center Sp8126 near me manufacturer China Custom 4 5 Axis CNC Milling Machine Manufacturer 7126 Vertical Machining Center Sp8126 near me manufacturer

China Best Sales Lansun 5 Axis CNC Steel CZPT Cutting Machine Plasma Tubes Grooving Cutter with Hot selling

Product Description

Automatic Pipe Cutter Steel Pipe Cutting Machine
Suitable for cutting the cylinder branch, two, 3 or more layer saddle cutting of the main pipe.
ZLQ seriers CNC Steel pipe cutter is special CNC equipment which is used for cutting metal pipe automatically. It can reslize auto program and auto CNC nesting work for any complicated joint type of intertube and pipe and non-inter tube. And can cut any type welding bevel at 1 time. This product is widely used for steel structure, ship building, bridge and heavy machine industries.

Cutting technical specifications:
1. Cutting steel type: Round & square
2. Figures can be cut: Variety of graphics by outspreading intersecting line, can be with bevel
3. Control Axes: 3-4-5-6 axies, bevel cutting with 6 spindle and six-interlocking.
4. Diameter: 30-1000mm or customize (bigger dia. )
5. Thickness of the pipe: Flame: 5-200mm, plasma: 1-60mm
6. Bevel cutting range: Flame 60degree, plasma 30 , 45degree.
7. Cutting way: Plasma or /and gas
8. Pipe max length: ≥ 6m
9. Pipe clamping method: Chuck
10. Power-driven: High-precision AC servo+dedicated planetary reducer
11. Control System: A dedicated intersecting line cutting system: 6-axis controlled, with quantitative intersecting line cutting macro library
performance and precision mechanical movement indicators

ZLQ-65 intersection Cutting Machine CNC positioning accuracy , repeatability reach JB / T 5102-99 standard , cutting up JB/T10045.3-1999 quality standards , cutting roughness Ra ≤ 12.5μm.
Requirements of the moving parts in the work process run smoothly and without noticeable vibration ( beat ) phenomenon .
1 , the workpiece rotary drive

       Drive System Precision gear box,:         gear transmission
       Speed :                                0.1-25 rpm / min
       Japanese CZPT servo :              A5 Series AC servo system
       Reset Accuracy:                         ± 0.5mm
       Adjustment range:                       6-1000

2 , CZPT the car moved axially along the workpiece
       Precision Drive System:         ZheJiang Planetary gear box , gear , rack gear
       Effective stroke:                12000mm CZPT car
       Japanese CZPT servo:      A5 Series AC servo system
       Reset Accuracy :               ± 0.5mm

3 , CZPT fan axial plane workpiece swing axle

       Precision Drive System:          ZheJiang Planetary gear box , gear , rack gear
       Swing angle :                   30 ° -150 °
       Japanese CZPT servo :      A5 Series AC servo system
       Positioning accuracy of ± 0.3 °
4 , CZPT the car moves up and down shaft

       Drive system :                  linear guide, ball screw drive to pay
       CZPT the car up and down stroke determine:        the form of the cutter ( cutting diameter compliance requirements )
       Japanese CZPT servo:      A5 Series AC servo system
       Reset Accuracy:                ± 0.2mm
5 , the workpiece CZPT fan oscillating axle radial plane
       drive system:                     Curved rack ( arms drive )
       Swing angle:                      30 ° -150 °
       Japanese CZPT servo:         A5 Series AC servo system
       Positioning accuracy :              ± 0.3 °

6, the auxiliary measurement axis: profiling measurements and the pipe surface to prevent collisions with the torch

7 , the CZPT moves back and forth along the tube axis radial
       Drive system:                               linear guide, rack size
       Move forward and backward stroke:           500mm
       Japanese CZPT servo:                   A5 Series AC servo system
       Mobile accuracy:                            ± 0.2mm

Structure & cutting ability of CNC  pipe cutting machine:

Pictures from cutomer’s site:

Certificates:

 NO.  ITEM  PARAMETERS
 1.  pipe diameter  Φ=30~300mm Φ=60~600mm Φ=80~800mm 
 2.  Cutting mode  Flame & plasma 
 3.  Flame cutting thickness  δ 5mm-180mm
 4.  Plasma cutting pipe thickness  1-32mm
 5.  Guid rail  15,000mm
 6.  Effective cutting pipe length  12,000mm
 7.  pipe ovality  ≤1%
 8.  Cutting speed  V≤5000mm/min
 9.  translational speed V0=10~6000 mm/min
 10.  Cutting torch axial direction swing angle  α=±45°  Maxα=±60°
 11.  Cutting torch  radial direction  swing angle  β=±45°
 12. Loading capacity  3,000Kg
     
 kinematic axis  Axis choice  6 axis
 X axis:  Pipe rotating axis  YES
 Y axis:  Torch along pipe axial direction horizontal migration   YES
 A axis:  torch long pipe axial direction vertical swing   YES
 Z axis:  Torch  vertical movement   YES
 B axis:  torch along pipe  radial direction  horizontal swing   YES
 w axis:  torch along pipe  radial direction  horizontal migration   YES

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Stiffness and Torsional Vibration of Spline-Couplings

In this paper, we describe some basic characteristics of spline-coupling and examine its torsional vibration behavior. We also explore the effect of spline misalignment on rotor-spline coupling. These results will assist in the design of improved spline-coupling systems for various applications. The results are presented in Table 1.
splineshaft

Stiffness of spline-coupling

The stiffness of a spline-coupling is a function of the meshing force between the splines in a rotor-spline coupling system and the static vibration displacement. The meshing force depends on the coupling parameters such as the transmitting torque and the spline thickness. It increases nonlinearly with the spline thickness.
A simplified spline-coupling model can be used to evaluate the load distribution of splines under vibration and transient loads. The axle spline sleeve is displaced a z-direction and a resistance moment T is applied to the outer face of the sleeve. This simple model can satisfy a wide range of engineering requirements but may suffer from complex loading conditions. Its asymmetric clearance may affect its engagement behavior and stress distribution patterns.
The results of the simulations show that the maximum vibration acceleration in both Figures 10 and 22 was 3.03 g/s. This results indicate that a misalignment in the circumferential direction increases the instantaneous impact. Asymmetry in the coupling geometry is also found in the meshing. The right-side spline’s teeth mesh tightly while those on the left side are misaligned.
Considering the spline-coupling geometry, a semi-analytical model is used to compute stiffness. This model is a simplified form of a classical spline-coupling model, with submatrices defining the shape and stiffness of the joint. As the design clearance is a known value, the stiffness of a spline-coupling system can be analyzed using the same formula.
The results of the simulations also show that the spline-coupling system can be modeled using MASTA, a high-level commercial CAE tool for transmission analysis. In this case, the spline segments were modeled as a series of spline segments with variable stiffness, which was calculated based on the initial gap between spline teeth. Then, the spline segments were modelled as a series of splines of increasing stiffness, accounting for different manufacturing variations. The resulting analysis of the spline-coupling geometry is compared to those of the finite-element approach.
Despite the high stiffness of a spline-coupling system, the contact status of the contact surfaces often changes. In addition, spline coupling affects the lateral vibration and deformation of the rotor. However, stiffness nonlinearity is not well studied in splined rotors because of the lack of a fully analytical model.
splineshaft

Characteristics of spline-coupling

The study of spline-coupling involves a number of design factors. These include weight, materials, and performance requirements. Weight is particularly important in the aeronautics field. Weight is often an issue for design engineers because materials have varying dimensional stability, weight, and durability. Additionally, space constraints and other configuration restrictions may require the use of spline-couplings in certain applications.
The main parameters to consider for any spline-coupling design are the maximum principal stress, the maldistribution factor, and the maximum tooth-bearing stress. The magnitude of each of these parameters must be smaller than or equal to the external spline diameter, in order to provide stability. The outer diameter of the spline must be at least 4 inches larger than the inner diameter of the spline.
Once the physical design is validated, the spline coupling knowledge base is created. This model is pre-programmed and stores the design parameter signals, including performance and manufacturing constraints. It then compares the parameter values to the design rule signals, and constructs a geometric representation of the spline coupling. A visual model is created from the input signals, and can be manipulated by changing different parameters and specifications.
The stiffness of a spline joint is another important parameter for determining the spline-coupling stiffness. The stiffness distribution of the spline joint affects the rotor’s lateral vibration and deformation. A finite element method is a useful technique for obtaining lateral stiffness of spline joints. This method involves many mesh refinements and requires a high computational cost.
The diameter of the spline-coupling must be large enough to transmit the torque. A spline with a larger diameter may have greater torque-transmitting capacity because it has a smaller circumference. However, the larger diameter of a spline is thinner than the shaft, and the latter may be more suitable if the torque is spread over a greater number of teeth.
Spline-couplings are classified according to their tooth profile along the axial and radial directions. The radial and axial tooth profiles affect the component’s behavior and wear damage. Splines with a crowned tooth profile are prone to angular misalignment. Typically, these spline-couplings are oversized to ensure durability and safety.

Stiffness of spline-coupling in torsional vibration analysis

This article presents a general framework for the study of torsional vibration caused by the stiffness of spline-couplings in aero-engines. It is based on a previous study on spline-couplings. It is characterized by the following 3 factors: bending stiffness, total flexibility, and tangential stiffness. The first criterion is the equivalent diameter of external and internal splines. Both the spline-coupling stiffness and the displacement of splines are evaluated by using the derivative of the total flexibility.
The stiffness of a spline joint can vary based on the distribution of load along the spline. Variables affecting the stiffness of spline joints include the torque level, tooth indexing errors, and misalignment. To explore the effects of these variables, an analytical formula is developed. The method is applicable for various kinds of spline joints, such as splines with multiple components.
Despite the difficulty of calculating spline-coupling stiffness, it is possible to model the contact between the teeth of the shaft and the hub using an analytical approach. This approach helps in determining key magnitudes of coupling operation such as contact peak pressures, reaction moments, and angular momentum. This approach allows for accurate results for spline-couplings and is suitable for both torsional vibration and structural vibration analysis.
The stiffness of spline-coupling is commonly assumed to be rigid in dynamic models. However, various dynamic phenomena associated with spline joints must be captured in high-fidelity drivetrain models. To accomplish this, a general analytical stiffness formulation is proposed based on a semi-analytical spline load distribution model. The resulting stiffness matrix contains radial and tilting stiffness values as well as torsional stiffness. The analysis is further simplified with the blockwise inversion method.
It is essential to consider the torsional vibration of a power transmission system before selecting the coupling. An accurate analysis of torsional vibration is crucial for coupling safety. This article also discusses case studies of spline shaft wear and torsionally-induced failures. The discussion will conclude with the development of a robust and efficient method to simulate these problems in real-life scenarios.
splineshaft

Effect of spline misalignment on rotor-spline coupling

In this study, the effect of spline misalignment in rotor-spline coupling is investigated. The stability boundary and mechanism of rotor instability are analyzed. We find that the meshing force of a misaligned spline coupling increases nonlinearly with spline thickness. The results demonstrate that the misalignment is responsible for the instability of the rotor-spline coupling system.
An intentional spline misalignment is introduced to achieve an interference fit and zero backlash condition. This leads to uneven load distribution among the spline teeth. A further spline misalignment of 50um can result in rotor-spline coupling failure. The maximum tensile root stress shifted to the left under this condition.
Positive spline misalignment increases the gear mesh misalignment. Conversely, negative spline misalignment has no effect. The right-handed spline misalignment is opposite to the helix hand. The high contact area is moved from the center to the left side. In both cases, gear mesh is misaligned due to deflection and tilting of the gear under load.
This variation of the tooth surface is measured as the change in clearance in the transverse plain. The radial and axial clearance values are the same, while the difference between the 2 is less. In addition to the frictional force, the axial clearance of the splines is the same, which increases the gear mesh misalignment. Hence, the same procedure can be used to determine the frictional force of a rotor-spline coupling.
Gear mesh misalignment influences spline-rotor coupling performance. This misalignment changes the distribution of the gear mesh and alters contact and bending stresses. Therefore, it is essential to understand the effects of misalignment in spline couplings. Using a simplified system of helical gear pair, Hong et al. examined the load distribution along the tooth interface of the spline. This misalignment caused the flank contact pattern to change. The misaligned teeth exhibited deflection under load and developed a tilting moment on the gear.
The effect of spline misalignment in rotor-spline couplings is minimized by using a mechanism that reduces backlash. The mechanism comprises cooperably splined male and female members. One member is formed by 2 coaxially aligned splined segments with end surfaces shaped to engage in sliding relationship. The connecting device applies axial loads to these segments, causing them to rotate relative to 1 another.

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