Product Description
MHC Series High-performance Multi-cylinder Hydraulic Cone Crusher Machine
Description:
The MHC series Multi-cylinder Hydraulic Cone Crusher is 1 of the top adcanced cone curshers in China, which is develped and manufactured by our company. This machine is a high-class product combined with mechanical technology, electrical technology, hydraulic technology and advanced crushing technology. The machine adopts high strengh casting-steel frame, alloy forging main shaft and high presion straight bevel gear driving structure, combined with multi-chambers selection and automation control system, which fulfills the performance and advantages. It can be widely used in secondary and fine crushing work for all kinds of hard materials and rocks to meet customers’ various needs for crushing.
Features:
HIGH PRODUCTIVITY
Combined with optimal crushing chamber, large eccentricity, optimal swing frequency and laminating crushing principle, this machine keeps the constant value of discharge opening in crushing process by using preloading technology of hydraulic cylinder, which makes the machine’s performance more stable, getting much greater throughput, higher productivity and better product shape, meantime minimize the unit energy consumption.
AUTOMATION
Automation control system can achieve the overloading protection, iron-passing protection, dischage openning adjustment and cavity clearing, and can also constantly monitor these conditions such as oil temperature, oil flow, oil pressure motor load and discharge opening size, etc., which ensure the machine work stably.
HIGH LOADING CAPACITY
Optimization design of strong frame construction and high-strengh cantilevel fixed shaft structure, unique hydrodynamic lubrication design of copper bush, smart and reliable overload protection system, which ensure the machine have long-term and stable operation under extremely bad conditions such as hard rock crushing.
WIDE APPLICABILITY
There are 2 types of cone crusher: standard type and short head type. There are several types of chamber can be chosen for each type. Different chambers can be changed easily by replacing the liner, pulley and adapter ring to meet different production process and application. The adjusting of products’ classifying can be achieved by adjusting the driving shaft speed to maximize the equipment’s value in use.
LOW RUNNING NOISE AND LOW VIBRATION
The driving structure of high precision straight bevel gear has advantages of low running noise, high driving ratio and long durability. Low vibration itself and flexibility supporting of the steel structure ensure minimum vibration which is caused by transmission from machine to foundation and low foundation cost.
LOW INSTALLATION COST
MHC series cone crushers has advantage of low installation height compared to peer products and the integral steel base frame ensure easy installation, short time-cost and minimum installation cost.
LOW RUNNING COST
The liner use ratio and durability can be increased by special crushing chamber, liner structure and liner material. The standard positive pressure dustproof system ensures pure lubrication oil all the time, which extends the service life and low the cost of labor because of less frequent lubrication oil change. Most of the parts can be disassembled in top and side which is safe, convenient and efficient.
Technical Specifications:
| Model | Max. Power (kw) |
Throughput Capacity(t/h) | ||||||
| CSS (mm) |
6 | 8 | 10 | 13 | 16 | 19 | ||
| MHC200 | 160 |
|
60-75 | 70-90 | 85-115 | 115-145 | 135-175 | 145-185 |
| MHC300 | 220 | 75-95 | 100-130 | 110-140 | 145-180 | 170-215 | 190-230 | |
| MHC400 | 315 | 105-140 | 135-170 | 180-225 | 215-275 | 250-320 | ||
| MHC500 | 400 | 135-170 | 170-220 | 225-290 | 270-345 | 310-400 | ||
| MHC800 | 630 | 240-335 | 315-420 | 375-500 | 420-540 | |||
| Model | Max. Power (kw) |
Throughput Capacity(t/h) | ||||||
| CSS (mm) |
22 | 25 | 32 | 38 | 45 | 51 | ||
| MHC200 | 160 |
|
155-195 | 165-215 | 185-230 | 205-245 | ||
| MHC300 | 220 | 220-260 | 225-275 | 245-320 | 300-375 | 345-430 | ||
| MHC400 | 315 | 275-345 | 285-365 | 315-425 | 350-480 | 400-540 | 455-615 | |
| MHC500 | 400 | 340-425 | 360-450 | 400-530 | 425-585 | 500-670 | 560-770 | |
| MHC800 | 630 | 465-590 | 490-725 | 545-790 | 585-920 | 670-990 | 765-1100 | |
Note: CSS represents discharge opening size. The above capacity is based on limestone with bulk density 1.6t/m3. This capacity will be affected by factors such as selected eccentricity, crushing ratio, material hardness, feed particle size composition, moisture and slit content etc. For more detailed information please contact us.
Structure:
Discharging Granularity Curves:
Note: The figures on the curves are for the discharging opening size and analysis of square hole.
Dimensions:
Applications:
Workshop:
Three basic types of pulleys, their applications and ideal mechanical advantages
There are 3 basic types of pulleys: movable, fixed and compound. Each has its advantages and disadvantages, and you should be able to judge which type is best for your needs by looking at the table below. Once you have mastered the different types of pulleys, you can choose the right pulley for your next project. Now that you have mastered the 3 basic types, it is time to understand their applications and ideal mechanical advantages.
describe
The stress characteristics of a pulley depend on its size and construction. These stresses are derived by comparing the stress characteristics of different pulley designs. Stress criteria include static and fatigue strength analyses and specify maximum stress ranges. Stresses are calculated in a 3D stress field, including radial, tangential and axial stresses. The stress characteristics of pulleys are critical to the design and manufacture of industrial machines.
The principal stresses on the pulley shell are distributed in the tangential and hoop directions, close to the centerline of the pulley. If the pulley has a wide face, the axial stress occurring near the shell/disk junction can be large. The stress distribution was determined using British Standard BS5400 Part 10: Stresses at the shell and end disc connections for infinite fatigue life.
Another type of composite is a pulley with a belt section. Such structures are well known in the art. The corresponding help chapters for these elements contain detailed descriptions of the internal structure of these components. Chamfers between pulleys can also be defined using multiple tapers, with a smaller taper extending from midpoint 44 to large diameter 42. Additionally, the pulley can have multiple taper angles, and as the pulley moves away, the taper angle is from the center.
type
A pulley system uses a rope to move the object and 1 side of the rope to lift the load. The load is attached to 1 end of the pulley, while the other end can move freely in space. The force applied to the free end of the rope pulls the load up or down. Because of this, the mechanical advantage of the movable pulley is 2 to one. The greater the force applied to the free end of the rope, the greater the amount of movement achieved.
There are 3 common types of pulleys. The cast-iron variety has a rim at the front and a hub at the back. The arms of the pulley can be straight or curved. When the arms contract and yield instead of breaking, they are in tension. The top of the pulley centers the belt in motion and is available in widths ranging from 9mm to 300mm.
The rope, hub and axle are mounted on the pulley. They are common and versatile mechanical devices that make it easier to move or lift objects. Some pulleys change the direction of the force. Others change the magnitude. All types of pulleys can be used for a variety of different applications. Here are some examples. If you’re not sure which type to choose, you can find more resources online.
application
The applications for pulleys are almost limitless. This simple machine turns complex tasks into simple ones. They consist of a rope or chain wrapped around a wheel or axle. Using ropes, 1 can lift heavy objects without the enormous physical exertion of traditional lifting equipment. Some pulleys are equipped with rollers, which greatly magnifies the lifting force.
When used properly, the pulley system can change the direction of the applied force. It provides a mechanical advantage and allows the operator to remain separate from heavy objects. They are also inexpensive, easy to assemble, and require little lubrication after installation. Also, once installed, the pulley system requires little maintenance. They can even be used effortlessly. Despite having many moving parts, pulley systems do not require lubrication, making them a cost-effective alternative to mechanical lifts.
Pulleys are used in many applications including adjustable clotheslines in different machines, kitchen drawers and motor pulleys. Commercial users of pulley systems include cranes. These machines use a pulley system to lift and place heavy objects. They are also used by high-rise building washing companies. They can easily move a building without compromising its structural integrity. As a result, many industries rely on technology to make elevators easier.
Ideal mechanical advantage
The ideal mechanical advantage of a pulley system is the result of rope tension. The load is pulled to the center of the pulley, but the force is evenly distributed over the cable. Two pulleys will provide the mechanical advantage of 2 pulleys. The total energy used will remain the same. If multiple pulleys are used, friction between pulleys and pulleys reduces the return of energy.
Lever-based machines are simple devices that can work. These include levers, wheels and axles, screws, wedges and ramps. Their ability to work depends on their efficiency and mechanical superiority. The ideal mechanical advantage assumes perfect efficiency, while the actual mechanical advantage takes friction into account. The distance traveled by the load and the force applied are also factors in determining the ideal mechanical advantage of the pulley.
A simple pulley system has an MA of two. The weight attached to 1 end of the rope is called FA. Force FE and load FL are connected to the other end of the rope. The distance that the lifter pulls the rope must be twice or half the force required to lift the weight. The same goes for side-by-side pulley systems.
Materials used in manufacturing
While aluminum and plastic are the most common materials for making pulleys, there are other materials to choose from for your timing pulleys. Despite their different physical properties, they all offer similar benefits. Aluminum is dense and corrosion-resistant, and plastic is lightweight and durable. Stainless steel is resistant to stains and rust, but is expensive to maintain. For this reason, aluminum is a popular choice for heavy duty pulleys.
Metal can also be used to make pulleys. Aluminum pulleys are lightweight and strong, while other materials are not as durable. CZPT produces aluminium pulleys, but can also produce other materials or special finishes. The list below is just representative of some common materials and finishes. Many different materials are used, so you should discuss the best options for your application with your engineer.
Metals such as steel and aluminum are commonly used to make pulleys. These materials are relatively light and have a low coefficient of friction. Steel pulleys are also more durable than aluminum pulleys. For heavier applications, steel and aluminum are preferred, but consider weight limitations when selecting materials. For example, metal pulleys can be used in electric motors to transmit belt motion.
cost
Replacing a tensioner in a car’s engine can cost anywhere from $90 to $300, depending on the make and model of the car. Cost can also be affected by the complexity of the pulley system and how many pulleys are required. Replacement costs may also increase depending on the severity of the damage. The cost of replacing pulleys also varies from car to car, as different manufacturers use different engines and drivetrains.
Induction motors have been an industrial workhorse for 130 years, but their cost is growing. As energy costs rise and the cost of ownership increases, these motors will only get more expensive. New technologies are now available to increase efficiency, reduce costs and improve safety standards.
The average job cost to replace an idler varies from $125 to $321, including labor. Parts and labor to replace a car pulley can range from $30 to $178. Labor and parts can cost an additional $10 to $40, depending on the make and model of the car. But the labor is worth the money because these pulleys are a critical part of a car’s engine.
