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The ball mill bearing bush, also known as the bearing housing or bearing pedestal or slide shoes bearing bush, is an important component that supports the mill's rotating motion and helps to transmit the loads generated during the grinding process. The bearing bush houses the bearings that allow for smooth rotation of the mill's shaft. Tongli, as a professional cement ball mill equipment supplier, provides various types of ball mill bearing bush with different specifications and materials. Tongli ball mill bearing bush steel casting has a mature casting process and strong machining strength.
The ball mill bearing bush, also known as the bearing housing or bearing pedestal or slide shoes bearing bush, is an important component that supports the mill's rotating motion and helps to transmit the loads generated during the grinding process. The bearing bush houses the bearings that allow for smooth rotation of the mill's shaft. Tongli, as a professional cement ball mill equipment supplier, provides various types of ball mill bearing bush with different specifications and materials. Tongli ball mill bearing bush steel casting has a mature casting process and strong machining strength. Tongli steel casting is made of high-quality mild carbon steel and 304 stainless steel that is fresh out from our own fabrication workshop in which the quality of the raw material is strictly controlled. What features about the bearing bush is it has an alloy surface and Tongli also designed a high pressure oil system that makes the ball mill actually floating on the bearing bush not in direct contact, please check out the video above for detail.
The basic structure of a ball mill consists of a cylindrical shell rotating around its axis, partially filled with grinding media such as steel or ceramic balls. The inner surface of the cylindrical shell is usually lined with abrasion-resistant materials such as manganese steel or rubber to protect the shell from the abrasive nature of the grinding media and the processed material.
Mill Shell: The foundation of the ball mill, the mill shell, is a sturdy cylindrical structure crafted from premium-grade steel. This robust shell encases the grinding process, confining it within a controlled environment. Tongli heavy machinery is equipped with a large annealing furnace of 6.5x6.5x20m and a 6.5x6.5x20m large sandblasting room, which can conduct overall heat treatment and sandblasting on the ball mill to ensure the service life and appearance of the ball mill.Trunnion: The trunnion (hollow shaft) of the ball mill is a key part of the cement machinery, which is a special type of steel casting. It mainly plays the role of supporting and connecting the cylinder in the weight of the whole machine, and is the passage for the material to enter and exit.
Bearing Bush: Ball mill bearing bush ensures the smooth rotation of the ball mill and empowers the ball mill to maintain optimal grinding conditions. It is equipped with a forced lubrication system and also cooling system.
Transmission connection: Tongli’s ball mill is equipped with a transmission connection, which is welded on the cylinder and machined together with the ball mill shell to avoid assembly errors and ensure the concentricity of the ball mill.
Girth Gear: The ball mill girth gear is a large gear ring encircling the ball mill, usually mounted on the shell of the ball mill. It is driven by a pinion gear, and together they form the primary drive unit to rotate the ball mill. The girth gear is casted and machined Tongli, the quality is assured.
Hood Cover: The discharge hood of the ball mill is installed at the discharge end of the ball mill, and there is a screen inside. After grinding, the material with a qualified size will enter the discharge hood through the screen and enter the next process. There is a vent on the upper part of the discharge hood, and a discharge funnel on the lower part.
Diaphragm: The ball mill diaphragm (compartment plate) is fan-shaped plate or bow-shaped grate plate fixed in the ball mill with bolts. Its function is to divide the ball mill into two or more chambers, the material moves to the next compartment through the holes on the grate plate. The function of the compartment plate is to prevent the grinding media running from one compartment to another compartment, so that the materials can be reasonably finely ground.
Liner: The function of the liner is to protect the shell of the ball mill and the trunnion, some special-shaped liners can also design to lift the grinding media to a certain position. According to the shape of the liner, it can be divided into flat liner, beaded liner, corrugated liner, ribbed liner, stepped liner, etc.
Ball mill transmission: Central drive ball mill refers to the arrangement of the driving mechanism for the mill. In a central drive configuration, the motor and gearbox are positioned at the center of the mill, usually between the grinding chamber and the mill shell. This design is in contrast to an edge or end drive configuration where the motor and gearbox are situated at one of the ends of the mill. Central drive transmission systems typically involve a motor that powers a gearbox, which then transfers the rotational energy to the mill's main shaft. The central drive design can provide advantages in terms of power distribution and efficiency compared to other drive arrangements. It can also offer better control over the mill's operation.
PLC control system: A Grinding Plant PLC (Programmable Logic Controller) system refers to the automation technology used in a cement grinding plant to control and monitor the various processes involved in cement grinding. PLCs are specialized digital computers used in industrial automation and control systems. They are capable of handling multiple input and output devices to execute control functions in real-time.
The steps of making bearing bush are as follows, you can also check out the bearing bush making process on our Youtube channel.
Mold Preparation: The pattern is used to create a mold, which is a negative impression of the bearing bush. This is done by placing the pattern in a casting flask and packing it with molding sand. The sand is carefully packed around the pattern to create a cavity that matches the gear's shape.
Metal Pouring: Once the mold is ready, molten metal is poured into the cavity. The type of metal used depends on factors like the application, load, and environmental conditions. Typically, bearing bushs are made from cast steel, alloy steel, or ductile iron.
Cooling and Solidification: After the metal is poured into the mold, it cools and solidifies, taking on the shape of the bearing bush. This process can take some time, and the cooling rate can affect the final properties of the casting.
Shakeout and Cleaning: Once the metal has solidified, the mold is broken open, and the casting is removed. The casting may have excess sand and other debris attached to it, which needs to be removed through shakeout and cleaning processes.
Machining: The casting is not yet ready for use as a bearing bush. It often requires machining to achieve the desired dimensions, surface finish, and accuracy. Machining operations can include turning, milling, drilling, and grinding.
Heat Treatment: Depending on the material and desired properties, the bearing bush might undergo heat treatment processes such as quenching and tempering to enhance its mechanical properties, such as strength and hardness.
Quality Control: Throughout the manufacturing process, quality control checks are performed to ensure that the bearing bush meets specified standards. This may involve dimensional measurements, non-destructive testing, and visual inspections.
Specification: | Capacity:(t/day) | Rpm: (r/min) | Grinding media(t) | Power: (kw) | Weight: (tons) |
Φ2.4x10 | 19~22 | 20 | 55 | 700 | 110 |
Φ2.4x12 | 23~25 | 20.8 | 65 | 900 | 115 |
Φ2.4x13 | 24~26 | 19.1 | 67 | 900 | 125 |
Φ2.6x13 | 26~28 | 18.8 | 85 | 1100 | 165 |
Φ3.0x11 | 35~40 | 18.8 | 120 | 1350 | 195 |
Φ3.0x12 | 35~40 | 18.8 | 120 | 1350 | 210 |
Φ3.0x13 | 38~42 | 18.4 | 130 | 1500 | 225 |
Φ3.2x13 | 50~55 | 18.4 | 150 | 1800 | 235 |
Φ3.5x11.5 | 55~60 | 18.4 | 150 | 1800 | 240 |
Φ3.5x13 | 65~70 | 16.6 | 165 | 2500 | 255 |
Φ3.8x13 | 70~75 | 16.6 | 195 | 2500 | 270 |
Φ4.0x13 | 80~85 | 15.6 | 210 | 3550 | 285 |
Φ4.2x13 | 80~90 | 15.6 | 220 | 3550 | 300 |
Φ4.6x13 | 110~120 | 14.9 | 235 | 4800 | 310 |
Φ4.6x14 | 120~130 | 14.9 | 250 | 4800 | 330 |
Note: * Mill diameter refers to the inner diameter, while the mill length refers to the effective grinding length.
Modern intelligent processing base integrating R&D, production and sales.
Zhejiang Tongli Heavy Machinery Manufacturing Co., Ltd (Formerly known as Tongxiang Coal&Mining Machinery Factory) established in year 1958 is a member of the Chinese National Building Material Machinery Association. Tongli is on the vendor list of designated production enterprise of the Ministry of Coal Industry. ISO9001、ISO14001、ISO45001 certified, accredited as High-tech & new technology enterprise of Zhejiang Province. With 65+ years of experience, Tongli has earned first class R&D and manufacturing capabilities, dedicated to provide satisfactory manufacturing equipments for global customers.
After years of development, there are more than 650+ sets of heavy machinery manufacturing equipments in our workshop, some of them are as follows:
65+ Years of Experience Founded in 1958 Tongli is a leading company specialized in the design and manufacture of complete ball mill systems in the global market. | Versatility Tongli ball mill can hanle a wide range of materials, including raw materials, cement clinker, and additives, making is highly versatile for different cement production. | Patented Design Tongli held independent intellectual property rights, developed core technologies of mechanical, and electrical systems provide high reliability at all events. | Reliability Tongli ball mill, its quality is time proven and well recognized by global customers, all the metal castings are produced in our foundry we provide one step solution to fabricaction and metal casting. |
What is the difference between ball mill and vertical roller mill?
Both ball mills and vertical roller mills plays a vital role in the cement grinding plant. Ball mills are versatile and cost-effective, suitable for various materials and simple to maintain. On the other hand, vertical roller mills offer superior energy efficiency and particle size control, making them ideal for cement and ore grinding applications. The choice between the two depends on specific requirements, budget constraints, and technical expertise.
What is the difference between rotary kiln and vertical roller mill?
The rotary kiln and vertical roller mill are both essential pieces of equipment in the cement manufacturing process, but they serve different purposes and are used at different stages of the process.
The rotary kiln is a large cylindrical vessel used for calcining raw materials at high temperatures. It's a core component of the cement manufacturing process and is responsible for transforming raw materials, particularly limestone and clay, into clinker. In the rotary kiln, the raw materials are heated to temperatures exceeding 1400°C (2552°F), where chemical reactions occur that result in the formation of clinker nodules. And they need to be ground into a fine powder to produce cement. This final grinding process is often performed using a vertical roller mill. The clinker is mixed with gypsum and possibly other additives to create the final cement product.
Vertical Roller Mill (VRM): The vertical roller mill is a grinding machine that grinds materials into fine powders, after the raw material is crushed by the crusher, it enters the vertical roller mill. It is typically used for grinding raw materials, clinker, and additives in the cement manufacturing process. The VRM operates by applying hydraulic pressure and vertical force to the grinding rollers, which then grind the materials between the rollers and the grinding table. This grinding process results in a fine powder that is later used as a key ingredient in the production of cement which is important for the subsequent chemical reactions in the rotary kiln.