China Hot selling Mineral Beneficiation/Washing Process, Ferrous Metal Spiral Screw Classifier, High Quality Screw Classifier with Best Sales

Product Description

Mineral Beneficiation/Washing Process,
Ferrous Metal Spiral Screw Classifier, High Quality Screw Classifier

Introduction of Gold Separator Machine, Double Screw Spiral Classifier
Spiral classifier is mainly used in metal beneficiation production line to classify minerals according to their different sedimentation velocity. Screw classifiers can be divided into high weir type, low weir type and sank type according to the height of the weir.
Our spiral classifiers are widely used in the distribution of ore in closed circuits with ball mills, grading ore and fine slit in gravity mills, grading granularity and flow of metal ore-dressing, and de-sliming and dehydrating in washing. Advantages are simple structure, reliable working condition and convenient operation.

According to the principle that different grains are with different specific gravity and sedimentation rate in the liquid, the fine ore flows in the water and the coarse ore sinks in the bottom. The classifier that has machine grading by discharging from the top can filtrate the materials and send coarse materials to the feeding mouth and discharge the fine material from the pipe. The seat of the machine adopts channel steel and body adopts armor plate and the spiral axle adopts wrought iron, so it’s durable. The lifting equipments have 2 types, by electricity and hand.

Advantages of Gold Separator Machine, Double Screw Spiral Classifier
1. Energy saving.
2. Adjustable particle size.
3. Applicable for wide range of industries.
4. Simple to control the purity of ore sand.
5. Compact structure and reliable operation.
6. Easy to maintain and low repair rate for adopting tile lining.
7. Concise operation for adopting the technology of inverter control.

Classification of Gold Separator Machine, Double Screw Spiral Classifier

Spiral classifiers are mainly classified into high weir single and double spiral classifier, low weir single and double spiral classifier, and immersed single and double screw classifier. Nowadays, low weir type 1 is not very common, high weir type and immersed type are preferable.

Working Principle of Gold Separator Machine, Double Screw Spiral Classifier

1. Spiral classifier is a type of classifying machine that classifies materials based the principle that the solid particles with different sizes and proportions have different falling speed in the liquid, and fine ore particles float in the water and coarse ore particles sink to the bottom of the chute and the coarse ore particles are pushed by the spiral to the upper part and discharged.
2. Screw classifiers are CZPT to filter the powdery particle crushed by the grinding mill and whirl the coarse particles with the spiral to the feeding mouth of the grinding mill and discharge the filtered fine particles.
3. The pedestal of spiral classifiers is made of U-steel, and the rack is welded with steel plate. The water feeding head and spindle nose of the spiral shaft are made of cast iron with wear-resisting and durable property and the lifting device is divided into power-operated type and manual-operated type

Parameters of Gold Separator Machine, Double Screw Spiral Classifier

Type Model Spiral 
Spiral rotate 
Motor Power
(kw )
Angle of inclination
Overflow Sand
Driving Lifting
 single spiral classifier
FLG-5 500 4500 8.5-15.5 22 143-261 1.1 1.5 14-18 1.6
FLG-7 750 5500 4.5-9.9 65 256-564 3 2.2 14-18 2.9
FLG-10 1000 6500 3.6-7.6 85 473-1026 5.5 3 14-18 4.4
FLG-12 1200 6500 6 155 1170-1600 5.5 4 14-18 9.4
FLG-15 1500 8400 2.5-6 235 1140-2740 7.5 4 14-18 11.7
FLG-20 2000 8400 3.6-5.5 400 3890-5940 11/15 15×2 14-18 21.5
FLG-24 2400 10500 3-5 580 6800 22 22×2 14-18 33.5
FLG-30 3000 12500 2-4 890 11650 30 3×2 14-18 37
double spiral
2FLG-12 1200 6500 6 310 2340-3200 5.5×2 3×2 14-18 15.8
FLG-15 1500 8400 2.5-6 470 2800-5480 7.5×2 4×2 14-18 22.1
FLG-20 2000 8400 3.6-5.5 800 7780-11880 15×2   14-18 36.4
FLG24 2400 9500 3.67 1160 13600 18.5×2 2.2 14-18 48.9
FLG-30 3000 12500 3.2 1785 23300 30×2 2.2 14-18 73.0
Sunken single spiral FLC-10 1000 8400 6-7.4 75 473-1026 5.5 3 14-18 6.0
FLC-12 1200 8400 5-7 120 1170-1630 7.5 4 14-18 11.0
FLC-15 1500 10500 2.5-6 185 1140-2740 7.5 4 14-18 15.3
FLC-20 2000 11500 3.6-5.5 320 3890-5940 11/15 1.5×2 14-18 29.1
FLC-24 2400 10500 3.64 455 6800 22 2.2×2 14-18 35.3
FLC-30 3000 14300 3.2 705 11650 30 3×2 14-18 43.5
Sunken double helix classifier 2FLC-12 1200 8400 6 240 1770-2800 7.5×2 3×2 14-18 19.6
2FLC-15 1500 10500 2.5-6 370 2280-5480 11×2 4×2 14-18 27.5
2FLC-20 2000 12900 3.6-5.5 800 7780-11880 15×2   14-18 5.0
2FLC-24 2400 11130 3.67 910 13700 37×2   14-18.5 65.3
2FLC-30 3000 14300 3.2 1410 23300 45×2   14-18.5 84.9

HangZhou HengXing Heavy Equipment Co.,Ltd

HangZhou CZPT is a joint stock corporation integrating scientific research, manufacture, marketing and exporting with the main target at the large and medium sized series of heavy duty equipments for mining, ore selecting, wall materials, formed coal, metallurgy and ect. The company located at HangZhou National High-Tech Development Zone.

We are specialized in the research, development, and production of industrial crushing, powder grinding, mineral processing equipments and other related devices. These products include CZPT Crushers, Jaw Crushers, Cone Crushers, Hammer Crushers, and Sand making Machines, Sand Washing machines, Rod Mills, Powder making Machines, Ore Dressing Machines, Briquette Machines and complete Cement Output Lines. Our products have been sold to areas of Southeast Asia, East Europe, South America, the Middle East and Africa etc, and more foreign markets will be promoted in future.


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.

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.

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.


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.

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 Hot selling Mineral Beneficiation/Washing Process, Ferrous Metal Spiral Screw Classifier, High Quality Screw Classifier     with Best SalesChina Hot selling Mineral Beneficiation/Washing Process, Ferrous Metal Spiral Screw Classifier, High Quality Screw Classifier     with Best Sales