Machinery & Parts

Precision alloy 1J33, 1J36 , and 1J46 are high-performance magnetic alloys widely known for their excellent magnetic properties and mechanical strength. These alloys feature high magnetic permeability, low coercivity, and stable performance across a broad temperature range, making them ideal for various industrial and electronic applications. With their superior ability to efficiently transmit and concentrate magnetic fields, these alloys are critical in industries that require precise magnetic control and reliable performance. Key Features of 1J33, 1J36, and 1J46 Alloys High Magnetic Permeability: 1J33, 1J36, and 1J46 alloys exhibit high magnetic permeability, which allows for efficient transmission and concentration of magnetic fields, ensuring optimal performance in magnetic applications. Low Coercivity: These alloys have low coercivity, meaning they can easily be magnetized and demagnetized without losing their magnetic properties over time, ensuring reliable performance in fluctuating magnetic environments. Good Temperature Stability: The alloys maintain stable magnetic properties even under varying temperature conditions, ensuring consistent performance in a wide temperature range. Excellent Mechanical Properties: With their robust mechanical strength, these alloys can withstand high stress and mechanical forces, ensuring durability and reliability in demanding environments. Precision Fabrication: 1J33, 1J36, and 1J46 alloys are highly machinable, allowing for the precise fabrication of components in various forms, including round bars, rods, and wires. Applications of 1J33, 1J36, and 1J46 Alloys These magnetic alloys are used in numerous industries that require stable and precise magnetic control. Common applications include: Electronics: In the electronics industry, 1J33, 1J36, and 1J46 alloys are used in the manufacturing of magnetic sensors, inductors, and transformers. Their high permeability and low coercivity make them ideal for applications that require efficient magnetic field transmission. Instrumentation: These alloys are used in precision instruments where accurate magnetic responses are essential. Their stability over time ensures reliable performance, even under fluctuating operational conditions. Aerospace: In aerospace applications, 1J33, 1J36, and 1J46 alloys are used in specialized magnetic components where both high reliability and performance are required, such as in magnetic actuators and sensors. Automotive: These alloys are used in automotive systems that require magnetic components, such as electric motors, sensors, and actuators, where high performance and durability are necessary. Power Generation: In power generation, the alloys are employed in transformers and other magnetic components that require consistent performance under high- stress conditions.

GH3536 high temperature alloy rod is a high-performance nickel-based superalloy primarily strengthened by the solid solution of chromium and molybdenum. This alloy, with a density of approximately 8.3 g/cm³, exhibits outstanding mechanical, physical, and chemical properties, making it an ideal choice for applications requiring superior heat and corrosion resistance, particularly in the chemical industry. Key Features of GH3536 Rod High-Performance Nickel-Based Superalloy: GH3536 rod is composed of nickel, iron, and chromium, providing superior strength and durability. The addition of molybdenum enhances its resistance to corrosion and oxidation, making it ideal for harsh industrial environments. Excellent Mechanical Properties: The tensile strength at room temperature exceeds 915 MPa, with a yield strength above 584 MPa. These high mechanical properties allow the alloy to withstand considerable stress and load, making it ideal for heavy-duty applications. Thermal Stability: The melting temperature of GH3536 ranges from 1260 to 1355 °C, ensuring stability in high-temperature environments. Its thermal conductivity at 100 °C is approximately 13.38 W/(m·°C), while its specific heat capacity is 372.6 J/(kg·°C). Outstanding Corrosion and Oxidation Resistance: GH3536 rod performs well in environments with temperatures ranging from 600 to 1200 °C, offering excellent resistance to oxidation and corrosion, particularly in chemical and petrochemical environments. Good Processability: GH3536 rod exhibits excellent formability, both in cold and hot working conditions, and can be welded using various processes such as TIG welding, plasma arc welding, and manual arc welding, making it easy to work with in fabrication and construction. Applications of GH3536 Rod Due to its superior properties, GH3536 rod is widely used in industries that demand high performance under extreme conditions. Common applications include: Chemical Industry: GH3536 is extensively used in the chemical industry for manufacturing components such as heat exchangers, reactor vessels, and piping systems, where resistance to high temperatures and corrosive environments is critical. Petrochemical Industry: In petrochemical processing, this alloy is used for producing components exposed to extreme heat and aggressive chemical environments, such as furnace tubes, distillation columns, and reformers. Power Generation: GH3536 rod is used in power plants, particularly in boiler components and steam turbines, where high temperature stability and mechanical strength are essential for long-term performance. Aerospace: The alloy is used in high-performance aerospace components such as engine parts and exhaust systems, where both heat resistance and mechanical strength are vital for safe and efficient operations. Marine and Offshore Applications: Due to its excellent resistance to corrosion and oxidation, GH3536 rod is used in marine equipment, including valves, pumps, and fittings, where exposure to seawater and other corrosive environments is common.

GH2747, GH747, and Nimonic80A are high-performance nickel-based alloys specifically designed for use in high-temperature applications such as aircraft engine rotors, gas turbines, and other critical aerospace components. These alloys are known for their excellent oxidation resistance, high-temperature strength, and superior mechanical properties, making them essential for demanding industries like aviation, aerospace, and power generation. Key Features of GH2747, GH747, and Nimonic80A Alloy Bars High-Temperature Strength: GH2747, GH747, and Nimonic80A alloys can withstand extreme temperatures up to 1000°C and beyond, making them ideal for components exposed to high heat, such as turbine blades and engine rotors. Corrosion and Oxidation Resistance: These alloys excel in resisting oxidation and corrosion, even under high-temperature and high-pressure conditions, ensuring the longevity and reliability of components in aggressive environments. Good Creep Resistance: GH2747 and other similar alloys exhibit excellent creep resistance, ensuring minimal deformation under sustained high temperatures and loads. Superior Mechanical Properties: These alloys have outstanding tensile strength, yield strength, and fatigue resistance, which are critical for components subjected to dynamic stresses. Weldability and Machinability: The alloys are highly weldable and machinable, allowing for ease of fabrication and customization to meet the precise needs of aerospace and industrial applications. Manufacturing Process of GH2747 Alloy Bars The manufacturing process of GH2747, GH747, and Nimonic80A alloys involves several stages to ensure the final product meets the rigorous demands of high- temperature applications: Melting: High-purity raw materials are melted in an electric arc or induction furnace. The molten metal is refined to remove impurities and achieve the desired chemical composition. Casting: The alloy is cast into ingots. These ingots are then heat-treated to homogenize the material and eliminate segregation. Forging: The ingots are hot-forged at temperatures above 1100°C, which refines the microstructure and improves the mechanical properties of the alloy. Hot Rolling: After forging, the material is hot-rolled to reduce thickness and achieve the required final dimensions. Annealing: The rolled bars are annealed at temperatures between 900-950°C to relieve internal stresses and improve ductility. Finishing: The final step involves cutting the bars to the required lengths and applying necessary surface treatments, such as grinding or polishing, to protect the alloy from environmental factors.

12 Ton Underground Mine Locomotive Powered by Lithium Battery Battery electric locomotive is a kind of track traction equipment powered by batteries, which is generally used in mines. There are two types of battery electric locomotives, explosion-proof type and ordinary type. The explosion- proof type is mainly used in coal mines. There are also many options in terms of speed regulation and braking methods. Speed control methods include resistance speed control, chopping speed control and frequency conversion speed control. Braking methods include pure mechanical braking, hydraulic braking and compressed air braking. In addition, electric braking can also be selected as an auxiliary braking method. Adhesive / total weight (t) : 12 ton Track gauge (mm) : 600.762.900 Traction (KN) : 16.48 Max. Traction (KN) : 29.43 Speed(km/h) : 8.7 Battery Voltage (V) : 192V Battery Capacity (Ah) : 560 Power (KW) : 22 KWx2 Dimensions Length(mm) : 5100 Width(mm) : 1050,1212or 1350 Height(mm) : 1800 Wheelbase (mm) : 1220 Wheel diameter (mm) : 680 Min Curve radius (m) : 10 Controller : Resistencia or IGBT Braking method : Mechanical

Minimum Order: 1 bags

Incoloy Alloy 825 Wire is a high-performance, nickel-chromium alloy renowned for its exceptional high-temperature performance. It is particularly well- suited for applications that demand a material capable of enduring extreme heat without sacrificing structural integrity. This makes the Incoloy Alloy an ideal choice for manufacturing compressor disks and other high-temperature components in industries such as chemical processing and marine. In addition to its high-temperature capabilities, Incoloy Alloy is highly regarded for its weldability, making it perfect for industrial applications requiring easy joining or repair through traditional welding techniques. The Incoloy Wire is particularly effective in machine manufacturing and other fields where robust and durable materials are essential. Another key attribute of Incoloy Alloy is its excellent thermal conductivity of 11.5 W/m·K. This property ensures the material efficiently transfers heat, making it ideal for applications like heat exchangers or thermal systems. Whether you are looking to enhance the performance of heat-related equipment or improve overall system efficiency, Incoloy Alloy provides a reliable solution. In summary, Incoloy Alloy offers a combination of high strength, corrosion resistance, high-temperature performance, and thermal conductivity, making it an outstanding choice for a variety of demanding industrial applications. Key Features High-Temperature Resistance: With its excellent ability to withstand temperatures up to 900°C (1652°F), Incoloy Alloy 825 maintains its structural integrity in extreme heat conditions. Superior Weldability: Incoloy Alloy 825 can be easily welded using traditional methods, which simplifies manufacturing processes in industries like chemical and marine applications. Thermal Conductivity: With a thermal conductivity of 11.5 W/m·K, Incoloy Alloy 825 efficiently transfers heat, making it ideal for applications in heat exchangers and other thermal systems. Corrosion Resistance: This alloy is known for its excellent resistance to oxidation and stress corrosion cracking, providing outstanding protection in harsh environments. Applications The Incoloy Alloy 825 is widely used in industries that demand high-performance materials capable of enduring extreme conditions. Some common applications include: Chemical Processing: The Incoloy Alloy 825 is used in components such as reactors, heat exchangers, and piping systems where resistance to both high temperatures and corrosive chemicals is essential. Marine Industry: With its exceptional resistance to seawater corrosion, Incoloy 825 is an ideal material for marine components such as heat exchangers, seawater pumps, and condenser tubes. Power Generation: Incoloy Alloy 825 is used in components exposed to high temperatures, such as gas turbines, steam generators, and other power generation equipment. Aerospace and Automotive: The alloy’s ability to withstand high-temperature environments and its excellent weldability make it perfect for aerospace engines and automotive parts. Advantages Outstanding High-Temperature Performance: The Incoloy Alloy 825 can withstand high temperatures up to 900°C (1652°F) while maintaining mechanical strength, making it an ideal choice for aerospace, chemical, and power generation industries. Superior Corrosion Resistance: Incoloy Alloy 825 provides excellent resistance to corrosion, oxidation, and stress corrosion cracking, even in aggressive environments like marine and chemical processing industries. Exceptional Weldability: The ease with which Incoloy Wire 825 can be welded makes it an excellent choice for applications requiring complex joins or repairs, reducing production time and costs. Enhanced Thermal Conductivity: With a thermal conductivity of 11.5 W/m·K, this alloy ensures efficient heat transfer, improving the performance and longevity of heat exchangers and other thermal equipment. Customizable and Versatile: Available in various forms, including wire, sheet, and plate, Incoloy Alloy 825 can be customized to suit a wide range of applications in industries such as chemical processing, marine, aerospace, and power generation.

Incoloy 800HT bars are high-performance alloy products primarily composed of nickel, iron, and chromium, specifically engineered for applications requiring exceptional high-temperature resistance and superior corrosion resistance. These alloy rods are well-regarded in a wide range of industries for their ability to withstand extreme conditions, including exposure to high heat, acidic gases, and oxidative environments. Incoloy 800H T bars are particularly favored for applications in the power generation, chemical processing, aerospace, and oil & gas industries, where reliability and durability are paramount. Key Properties of Incoloy 800HT Alloy Bar High-Temperature Resistance: Incoloy 800HT rods maintain exceptional strength and stability even at elevated temperatures, with the ability to endure conditions often exceeding 1,000°C (1,832°F). This property makes them ideal for use in high-temperature industrial applications like boilers, heat exchangers, and furnace components. Corrosion and Oxidation Resistance: The alloy’s high content of chromium and nickel provides robust protection against corrosion and oxidation in aggressive environments, including acidic, oxidizing, and sulfurous conditions. This corrosion resistance is a key factor in extending the service life of components used in chemical processing and marine applications. Excellent Mechanical Strength: Incoloy 800HT rods possess high tensile and yield strength, allowing them to withstand high mechanical stress in extreme environments. This durability makes them a preferred choice in industries where components are exposed to continuous high-pressure and high-temperature conditions. Thermal Stability and Creep Resistance: Incoloy 800HT is known for its ability to resist creep deformation and retain stability during prolonged exposure to high temperatures. This makes it an excellent choice for applications that demand long-term performance without degradation. Weldability and Machinability: These rods can be welded and machined using standard techniques, allowing for versatile fabrication of complex components without compromising the material's strength or integrity. Incoloy 800HT's workability contributes to its widespread use in various industries, from aerospace to petrochemical. Applications of Incoloy 800HT Alloy Bar Petrochemical and Refining Industries: Incoloy 800HT rods are commonly used in high-temperature applications like furnace tubes, heat exchangers, and piping systems. Their ability to withstand corrosive gases and acidic environments makes them ideal for petrochemical reactors and refining equipment. Power Generation: This alloy is essential in the production of boiler components, steam generators, and nuclear reactors, where resistance to high heat and mechanical stress is crucial. Incoloy 800HT helps maintain the integrity and efficiency of power plants under extreme operational conditions. Aerospace: Incoloy 800HT bars are used in aerospace components such as jet engine parts, exhaust systems, and heat exchangers. The alloy’s stability at high temperatures and resistance to oxidation make it a critical material in maintaining the performance of aircraft in high-stress, high-temperature environments. Marine and Chemical Processing Equipment: Incoloy 800HT rods are suitable for marine applications exposed to saltwater and brine, as well as in chemical processing environments that involve aggressive acids and other corrosive substances. The alloy’s resistance to corrosion ensures the longevity and reliability of valves, fittings, and other marine components. Oil and Gas Industry: Used in well tubing, casing, and completion equipment, Incoloy 800HT is ideal for harsh oil and gas extraction environments, particularly where resistance to sour gas and high-pressure conditions is required.

The 4J29 , 4J40, 4J42 Invar Kovar Precision Alloy Tube is a high-performance product designed for applications where dimensional stability is paramount. Crafted from precision alloys known for their exceptionally low thermal expansion properties, this tube maintains integrity under extreme temperature fluctuations. The 4J28, 4J29, 4J32, and 4J33 alloys are renowned for their ability to withstand temperature changes without significant deformation, making them perfect for use in industries that require precise dimensional control, such as electronics, aerospace, and engineering. These alloys also provide excellent corrosion resistance, ensuring reliable performance in harsh environments, while their durability enhances their service life in various industrial applications. With competitive manufacturing prices, this precision alloy tube offers an optimal balance of cost- effectiveness and high performance, without compromising on quality. Key Properties of 4J29, 4J40, 4J42 Precision Alloy Tube Low Thermal Expansion: The primary feature of 4J29, 4J40, and 4J42 alloys is their exceptionally low coefficient of thermal expansion. This property ensures that the alloy maintains its dimensions under extreme temperature changes, which is critical in applications where precision is crucial. High Dimensional Stability: This precision alloy retains its shape and size even when exposed to varying temperatures, making it ideal for industries like electronics, aerospace, and optics, where tight tolerances are essential. Corrosion Resistance: In addition to its thermal stability, this alloy offers excellent resistance to corrosion, including oxidation and chemical degradation. This makes it suitable for use in harsh or chemically aggressive environments, such as marine, chemical processing, and petrochemical industries. Durability and Longevity: The alloy's inherent strength and resistance to environmental wear extend the service life of components made from it, reducing maintenance costs and enhancing reliability in mission-critical applications. Excellent Fabrication Properties: The 4J series alloy is easy to fabricate and machine, enabling the creation of complex geometries without compromising its mechanical properties. Its weldability and machinability make it versatile in a wide range of fabrication processes. Applications of 4J29, 4J40, 4J42 Precision Alloy Tube Electronics Industry: This precision alloy is widely used in the electronics industry for components that require high dimensional stability, such as connectors, substrates, and semiconductor devices. Its ability to handle thermal expansion without deformation is crucial in the production of reliable electronic systems. Aerospace Industry: In aerospace, this alloy is used for precision-engineered parts in aircraft and spacecraft components, where high-temperature resistance and dimensional accuracy are critical for performance and safety. Optical Equipment: 4J29, 4J40, and 4J42 alloys are ideal for optical instruments that require high precision and stability across wide temperature ranges. The alloy helps maintain the accuracy of optical components, ensuring consistent performance in critical applications. Marine and Chemical Processing: Due to its corrosion resistance, this alloy is suitable for components in marine environments and chemical processing plants, where exposure to saltwater, acids, and other aggressive substances can cause degradation in many other materials. Petrochemical Industry: The alloy's ability to withstand harsh conditions, including exposure to high temperatures and aggressive chemicals, makes it valuable in petrochemical refining and related applications where long-lasting, reliable components are required.

Battery electric locomotive is a kind of track traction equipment powered by batteries, which is generally used in mines. There are two types of battery electric locomotives, explosion-proof type and ordinary type. The explosion- proof type is mainly used in coal mines. There are also many options in terms of speed regulation and braking methods. Speed control methods include resistance speed control, chopping speed control and frequency conversion speed control. Braking methods include pure mechanical braking, hydraulic braking and compressed air braking. In addition, electric braking can also be selected as an auxiliary braking method. Adhesive / total weight (t) : 5 t Track gauge (mm) : 500.600.762.900 Traction (KN) : 7.06 Max. Traction (KN) : 12.26 Speed(km/h) : 7 Battery Voltage (V) : 90 or 96 Battery Capacity (Ah) : 385 or 300AH Power (KW) : 7.5KWx2 Dimensions Length(mm) : 2860 Width(mm) : 920,1082 or 1220 Height(mm) : 1550 Wheelbase (mm) : 850 Wheel diameter (mm) : 520 Min Curve radius (m) : 6 Controller : Resistencia o IGBT Braking method : Mechanical or hydraulic brake

Minimum Order: 1 bags

Industrial 3D Printing is a technology that creates three-dimensional objects by stacking materials layer by layer. Combined with a one stop CNC Machining Service, it offers a complementary approach to traditional subtractive manufacturing (such as cutting and stamping), efficiently and flexibly producing complex structures and customized products. Core Features Highly customizable: Any shape can be designed according to demand, without molds, suitable for small batch or personalized production. Shortened production cycle: The time from design to prototyping is greatly compressed, suitable for rapid iteration. Material diversity: Supports high-performance materials such as metals, ceramics, composite materials, plastics, etc.

CNC prototype processing refers to a process that uses computer numerical control (CNC) technology to accurately create prototypes. As a one stop CNC Machining Service, it plays a vital role in product design and manufacturing. Prototypes are not only the physical embodiment of product design but are also used to verify product feasibility and improvement plans, helping to reduce development costs and risks. Core features of CNC Rapid Prototyping High precision CNC machining centre can achieve processing accuracy of ±0.01mm or even higher, suitable for parts with complex structures and strict tolerance requirements. Wide range of materials Supports metal (aluminum, steel, copper), plastic (ABS, PC, nylon), and even composite material processing.

In the field of parts processing, Brightstar relies on all-round advantages to provide reliable and cost-effective solutions. Lathe turning mainly uses lathes to cut and grind metals or other materials. As one stop CNC Machining Service, it involves mounting drills, reamers, screw taps, spanners, or knurling tools on the lathe machine to produce a variety of precisely manufactured parts with different structures. CNC Turning Capacities CNC lathe machines mainly use turning tools to turn workpieces. Typical CNC lathe turning operations include: Turning Facing Threading Groo , ving Cutting Knurling

Brightstar specializes in the processing of medium-sized and small parts with over 15 years of CNC machining experience and a wealth of process parameters and case studies. As one stop CNC Machining Service, we can quickly respond to the machining needs of various complex parts while ensuring consistent machining quality. Our team of process engineers and senior technicians, each with over 10 years of experience, provides comprehensive technical support, from design optimization and programming to machining implementation. Drawing Conversion & Programming After receiving customer drawings, our technical team first performs 3D modeling using specialized software such as UG and Mastercam, converting 2D drawings into a solid model. During the modeling process, they focus on key part dimensions, tolerance requirements, and assembly relationships to ensure the model fully complies with customer requirements. The programming phase utilizes parametric programming technology to automatically generate machining programs based on the part's machining process. For complex curved parts, the CAM software's toolpath optimization function reduces idle tool travel and improves machining efficiency. Furthermore, machining programs are verified using a virtual simulation system to check for tool collisions with parts and fixtures, eliminating machining risks in advance. Once programming is complete, the program is uploaded to a cloud database for easy access by various machining equipment.

In our factory, there are 12 units of DMU 950 and Hermle 5-axis machining equipment, which have held significant advantages in the field of precision machining. Equipped with a ruby probe automatic compensator, they can monitor the movement state of each axis of the CNC machine center and the tool position in real-time during the machining process. When the machine tool has slight deviations due to factors such as thermal deformation and mechanical wear, the ruby automatic compensator can quickly capture these changes and feed back the deviation data to the machine control system. The system then makes precise adjustments to the tool path or coordinate axis position according to the preset algorithm, ensuring that the machining always maintains a high-precision level. 5-axis Equipment Parameter Maximum stroke:  950*850*650 mm Rotate speed:  20,000 rpm Maximum workpiece size :  1200*1040*650mm Machining Accuracy:  ±0.01/100mm

An aluminum dross rotary furnace is a specialized piece of equipment used in the aluminum recycling industry to process and recover aluminum from dross, a byproduct generated during the melting of aluminum. Dross is a mixture of molten aluminum, aluminum oxides, and other impurities that forms on the surface of the melt when aluminum is exposed to air or furnace atmospheres. The rotary furnace is designed to separate and recover the valuable aluminum trapped within this dross, making it a critical tool for improving efficiency and profitability in aluminum recycling operations. The aluminum dross rotary furnace is a powerful and efficient tool that maximizes aluminum recovery, reduces operational costs, and supports sustainable recycling practices. Its ability to handle large volumes of dross with minimal energy and labor makes it indispensable in the modern aluminum industry.

Minimum Order: 1 bags