Industry status and price trend As a high-end high-temperature material, TZM alloy (molybdenum titanium zirconium alloy) continues to grow in demand in the aerospace, semiconductor and energy fields. The global market presents an oligopoly pattern, with major manufacturers concentrated in industrial powers such as the United States, Germany and Japan. China has achieved domestic substitution in some mid-to-high-end products. Price influencing factors: TZM Raw material fluctuations: Molybdenum prices account for 40-50% of the cost, and molybdenum price fluctuations in 2023 will significantly affect alloy prices Capacity restrictions: High-end product capacity is limited, and special specifications can reach a premium of 30-50% Application expansion: The semiconductor industry’s demand for high-purity TZM has increased by more than 15% annually In the past five years, TZM metal prices have shown a “W-shaped” trend and are currently stable at US$140-180/kg. It is expected to maintain an annual growth rate of 5-8% from 2024 to 2025. Product Core Value Analysis The high price of TZM alloy is due to its irreplaceable performance advantages: The strength at high temperature of 1200°C is twice that of conventional molybdenum alloys The recrystallization temperature is as high as 1400°C Excellent thermal conductivity (138W/(m·K)) and dimensional stability Process determines value: Process Cost coefficient Key advantage Conventional sintering 1.0x basic performance Hot isostatic pressing 1.5-2.0x Density ≥99.5% Electron beam melting 2.0-2.5x Ultra-high purity Life cycle cost advantage: Aviation parts reduce weight by 30%, and fuel efficiency is significant Semiconductor thermal field life is 5-8 times that of graphite Glass furnace maintenance cycle is extended by 2-3 times Purchase time: Prices are usually lower in Q2 each year Follow the trend of LME molybdenum futures Follow the production capacity dynamics of major manufacturers TZM alloy is a typical high-value functional material. Purchasing decisions should go beyond unit price considerations and comprehensively evaluate the full-cycle value of performance, life and service. Establishing strategic cooperation with suppliers with strong technical capabilities is an effective way to achieve cost optimization. Keywords：tzm material tzm alloy tzm metal tzm price tzm alloy price

Molybdenum wire is an essential consumable for wire cutting. It is expensive, but it is often broken by the workpiece during processing, which is really a headache! But don’t worry, today I will share a few tips to help you easily avoid the embarrassing situation of molybdenum wire being broken! 1.Use a magnet to suck the workpiece: When cutting halfway, use a magnet to suck the workpiece, which is simple and effective! 2. Fix with a clip: According to the actual processing situation, choose a suitable clip to clamp the workpiece to ensure stability. 3.Programming tips: When programming, hit the lead in the L3 direction to reduce the risk of wire breakage. 4.Cutting of oversized pieces: For large workpieces, you can leave a 0.25MM margin, knock it down with a sledgehammer, cut a large circle or square, and use a file to trim the scar. 5.Program plus D empty back to zero: After cutting to the end, pause , put molybdenum wire in the knife gap, you can put more, so as to effectively prevent the workpiece from falling directly and breaking the molybdenum wire. As long as you master these little tricks, you can greatly reduce the possibility of molybdenum wire being broken. Of course, there are still many experiences worth learning and exchanging during the processing process. As a molybdenum wire manufacturers, I hope everyone can learn more, exchange with each other, summarize experience, and make progress together! Keywords： molybdenum wire molybdenum wire factory

B30 copper-nickel alloy is a high-performance copper-based alloy. Due to its excellent corrosion resistance, high strength and good processing performance, it is widely used in petrochemical, marine engineering, pharmaceutical and other fields. This article will deeply analyze the performance and market situation of B30 copper-nickel alloy pipe from the aspects of technical parameters, industry standards, material selection misunderstandings, etc., and explore its price influencing factors. 1. Technical parameters of B30 copper-nickel alloy pipe The chemical composition of B30 copper-nickel alloy is mainly composed of copper (Cu) and nickel (Ni), usually containing about 75% copper and 20% nickel, and the rest are trace alloying elements. This composition makes it perform well in moderately corrosive environments, especially in environments containing chloride ions. According to the ASTMB929 standard, the typical performance parameters of B30 alloy are as follows: Tensile strength: ≥515MPa Yield strength: ≥275MPa Elongation: ≥30% Corrosion resistance: Excellent in seawater, brine and industrial solutions Conductivity: The conductivity is about 70%IACS (International Annealed Copper Standard) According to the AMS4965 standard, B30 alloy has good hot working properties and is suitable for cold and hot working and welding. 2. Industry standards and international market In the international market, the price of B30 copper-nickel alloy is affected by many factors, including raw material price fluctuations, market demand changes, and production costs. Here are some key points: Raw material prices: The price fluctuations of copper and nickel have a direct impact on the production cost of B30 alloy. For example, the copper price of the London Metal Exchange (LME) and the nickel price of Shanghai Nonferrous Network are important references for the global market. Market supply and demand: Investment fluctuations in the petrochemical industry directly affect the demand for B30 alloy. In recent years, with the recovery of the global energy industry, the demand for B30 alloy has increased. International trade: Due to the high production concentration of B30 alloy, the international price difference is large. For example, the price difference between the US market and the Chinese market may reach 5-10%. 3. Material selection misunderstandings When choosing B30 copper-nickel alloy, you need to pay attention to the following three common misunderstandings: Confusing alloy grades: B30 and copper-nickel alloys such as B10 have significant differences in composition and performance. When selecting materials, the alloy grade must be clarified to avoid substandard performance due to confusion. Ignoring the use environment: B30 alloy may not be as suitable as

When choosing a molybdenum rod supplier, you need to consider the following key factors: ‌1．Qualification and reputation: First, confirm whether the supplier has relevant certifications and licenses, including national mining licenses and ISO quality management system certifications. These certifications and licenses guarantee the legitimacy of the supplier and the quality of the product. In addition, checking customer reviews and feedback is also an important way to understand the true strength of the supplier, which can help buyers make more informed decisions. ‌2．Product quality and reliability: It is very important to ensure that the source of the purchased molybdenum rod raw materials is reliable. High-quality raw materials are the basis for ensuring the quality of the final product. Therefore, it is necessary to strictly control the supply chain, select manufacturers with a stable and high-quality supply of raw materials, and understand the supplier’s quality control system, including various testing standards and processes in the production process. It is also a point that cannot be ignored when choosing a supplier. ‌3．Price and service: Price transparency is one of the key factors in choosing a molybdenum rod supplier. Manufacturers with clear prices and no hidden costs should be selected, which can effectively avoid subsequent economic disputes. At the same time, excellent after-sales service and technical support are also important indicators for measuring the quality of supplier services. ‌4．Product performance and application areas‌: Molybdenum rods of different diameters have different performances. For example, for every 10mm increase in diameter, the thermal conductivity of the molybdenum rod will decrease by about 5W/m·K, but the bending strength will increase by 15%. This characteristic makes the 45mm diameter molybdenum rod an ideal choice for high-temperature hot pressing molds. ‌ In addition, there is a matching rule between the surface treatment process and the diameter. Small-diameter molybdenum rods are mostly polished, while large-diameter molybdenum rods are suitable for black oxidation. ‌ ‌5．Industry standards and specifications‌: Understanding and following relevant industry standards is the key to ensuring product quality. For example, GBT3462-2017 “Molybdenum Bars and Molybdenum Slabs” is a national standard formulated by China for molybdenum and molybdenum alloy materials, which regulates the chemical composition, physical properties, dimensional tolerances and inspection methods of molybdenum bars and molybdenum slabs. Keywords: molybdenum rod molybdenum rod supplier molybdenum rod factory molybdenum rod for sale molybdenum rod price molybdenum rod stock molybdenum rod suppliers buy molybdenum rod china molybdenum rod molybdenum rod china

As a plate made of molybdenum and copper through a specific process, molybdenum copper plate has shown wide application potential in many fields due to its unique physical and chemical properties. From the perspective of physical properties, first of all, molybdenum copper alloy inherits the high melting point characteristics of molybdenum and can maintain stable performance in high temperature environments. This feature gives it a significant advantage in fields that need to withstand high temperature environments, such as aerospace and chemical equipment. At the same time, copper, as an excellent thermal conductive material, combined with molybdenum, makes molybdenum copper alloy have excellent thermal conductivity. This feature is particularly important in fields such as electronic packaging, which can effectively improve the heat dissipation efficiency of equipment and ensure the stable operation of equipment. In addition to high melting point and good thermal conductivity, molybdenum copper alloy also has good electrical conductivity. This feature makes it have a wide range of application prospects in application scenarios that require electrical conductivity, such as electrodes and electric heating elements in the electronics industry. In addition, molybdenum copper alloy also has high strength and hardness, and can withstand large loads and stresses, which provides strong support for its use in the manufacture of high-temperature bearings and catalyst carriers. In terms of chemical properties, molybdenum-copper alloy exhibits excellent chemical stability. It can resist corrosion from most acidic and alkaline substances, which makes it widely used in the chemical industry. Whether it is the manufacture of corrosion-resistant chemical equipment or other occasions that need to withstand chemical corrosion, molybdenum-copper alloy can provide reliable protection. In summary, molybdenum-copper plate, as a high-performance alloy material, shows broad application prospects in many fields. In the field of aerospace, molybdenum-copper plate has become an important structural material and thermal protection material due to its light weight, high strength and good thermal conductivity. In the electronics industry, molybdenum-copper plate has become the preferred material in the field of electronic packaging due to its adjustable thermal expansion coefficient and good electrical and thermal conductivity. In the chemical industry, the chemical stability of molybdenum-copper plate enables it to resist corrosion and is suitable for the manufacture of various chemical equipment. In addition, molybdenum-copper plate is also used to manufacture high-temperature bearings, electrodes, electric heating elements and catalyst carriers, etc., providing strong support for scientific and technological progress and industrial upgrading in many industries. Keywords：molybdenum alloy molybdenum

Discovery and industrial application Titanium was discovered by Gregor of Britain in 1791, and then in 1795, German chemist Klaprus named this newly discovered metal after the Greek god Titans, which is translated into “titanium” in Chinese. This metal is abundant on the earth, with as many as 140 known titanium minerals, but ilmenite and rutile are mainly used in industry. China’s ilmenite reserves lead the world, accounting for 28%. Titanium is widely used in many fields due to its unique properties, such as high and low temperature resistance, strong acid and alkali resistance, high strength and low density. For example, it was selected by NASA as a special material for rockets and satellites, and it also plays a key role in major projects such as my country’s Yutu, J-20 and Shandong aircraft carrier. After entering the civilian field in the 1980s, titanium was hailed as the “honorary metal king” in the food industry because of its natural antibacterial and biophilic properties. China’s titanium industry started in the 1950s, and sponge titanium and titanium processing plants were built in the mid-1960s, marking China’s rise in the titanium industry. After entering the 21st century, China’s titanium industry has ushered in new development opportunities, and its production capacity has ranked among the top in the world. Pure titanium and titanium alloys Pure titanium, also known as industrial pure titanium or commercial pure titanium, is graded according to the content of impurity elements. It exhibits excellent stamping process performance and welding performance, and is insensitive to heat treatment and tissue type. Under the condition of meeting a certain plasticity, pure titanium also has a certain strength, which is mainly affected by the content of interstitial elements oxygen and nitrogen. For example, the performance indicators of 99.5% industrial pure titanium are as follows: density is 4.5g/cm³, melting point reaches 1800°C, thermal conductivity is 15.24W/(M.K), tensile strength σb is 539MPa, elongation is 25%, cross-sectional shrinkage is 25%, elastic modulus is 1.078×10⁵MPa, and hardness is HB195. Titanium alloy is an alloy composed of other elements added to titanium. Although the history of this metal is relatively short, with only sixty or seventy years of discovery, titanium alloy has occupied an indispensable position in key components such as aircraft engines, rockets, and missiles due to its light weight, high strength, high temperature resistance and corrosion resistance. It is worth noting that titanium has two isomorphous crystal structures. Below 882°C,

Molybdenum wire has become an indispensable key material in many industrial fields due to its unique physical and chemical properties in the precious metal market. Regarding the question of “how much does molybdenum wire cost per kilogram”, in fact, the price of molybdenum wire is usually calculated by 10,000 meters or kilograms, rather than the traditional kilogram. Its price is affected by multiple factors such as market supply and demand, purity, production process, and international metal price fluctuations, so the specific price will fluctuate. Generally speaking, the price of high-quality molybdenum wire may range from hundreds of yuan to thousands of dollars per 10,000 meters, which will be quite considerable when converted into kilograms (assuming that one kilogram is approximately equal to 5,000 meters, which needs to be calculated according to the specifications of the molybdenum wire). Next, let’s take a closer look at the main application areas of molybdenum wire: Electronic components: Molybdenum wire is widely used in the manufacture of electronic components such as thermocouples, vacuum circuit breakers, vacuum electrical appliances, etc. due to its excellent conductivity and high temperature resistance. In high temperature and high pressure environments, molybdenum wire can maintain stable performance to ensure the normal operation of electronic equipment. Fiber heating: In fiber optic communication and laser manufacturing, molybdenum wire is used as a heating material, and its high temperature resistance and good thermal conductivity provide a stable and reliable solution for fiber heating. High temperature furnaces: Molybdenum wire plays an important role as a heating element in high temperature furnaces, such as high temperature furnaces, vacuum furnaces, etc. Its high melting point and chemical stability enable molybdenum wire to work stably for a long time under extreme conditions, meeting various high temperature heating needs. Semiconductor and LED manufacturing: In semiconductor substrate manufacturing and LED production, molybdenum wire is used as a heating element or electrode material to improve product quality and production efficiency by precisely controlling temperature. Aerospace and military: In the field of aerospace, molybdenum wire and its alloys are used as structural materials and heating elements in high temperature environments, providing important guarantees for the stability and safety of aircraft. At the same time, in military equipment, molybdenum wire is also widely used due to its excellent performance. Automobile manufacturing: In the process of automobile manufacturing, molybdenum wire is used for spraying automobile parts to improve the wear resistance and corrosion resistance of parts and extend the service life

The manufacturing process of molybdenum plate mainly includes cutting, punching and heat treatment. First of all, molybdenum plate cutting is the first step in molybdenum plate processing. Common cutting methods include mechanical cutting, flame cutting and plasma cutting. Mechanical cutting is the cutting of molybdenum plate by mechanical equipment. Common equipment includes shearing machine, punching machine, etc. It is suitable for thicker molybdenum plates. Plasma cutting is the cutting of molybdenum plate by high-temperature plasma arc, which is suitable for thinner molybdenum plates. Secondly, punching is the process of processing holes at designated positions on molybdenum plates. Common punching methods include punch punching and laser punching. Punch punching is the punching of holes on molybdenum plates by punching equipment, which is suitable for holes with larger diameters. Laser punching is the processing of molybdenum plates by laser, which is suitable for small diameter holes and holes with complex shapes. Finally, heat treatment is one of the important links in molybdenum plate processing, and its content includes annealing, quenching, tempering and other steps. Heat treatment can change the internal structure of molybdenum plate, improve its strength, hardness, toughness and other properties to meet the needs of different applications. Finally, the production process of molybdenum plate needs to go through multiple steps of processing and treatment to obtain high-quality molybdenum plate products. Keywords：molybdenum plate molybdenum plate factory molybdenum plate manufacturers molybdenum plate price molybdenum plate suppliers china molybdenum plate wholesale molybdenum plate

Unveiling the secret of 44% nickel content: CuNi44 copper-nickel alloy plate has become the hidden champion of marine engineering and petrochemical industry with its hard-core performance of 320MPa tensile strength and resistance to medium salt spray corrosion. Beware of the work hardening trap when selecting, and the 44% nickel ratio has balanced the cost and corrosion resistance. The reason behind the rise of domestic prices to US$26./KG is the leap in processing performance brought about by the breakthrough of heat treatment process. CuNi44 copper-nickel alloy plate is a high-performance copper-based alloy. It is widely used in marine engineering, petrochemical industry, architectural decoration and other fields due to its excellent corrosion resistance, good processing performance and medium strength. This article will comprehensively analyze the CuNi44 copper-nickel alloy plate from the aspects of technical parameters, industry standards, material selection misunderstandings, technical disputes, etc. 1. Technical parameters of CuNi44 copper-nickel alloy plate CuNi44 is a typical copper-nickel alloy, which is mainly composed of copper (Cu) and nickel (Ni), of which the nickel content is about 44%. This ratio gives CuNi44 alloy unique physical and chemical properties. The following are its main technical parameters: Chemical composition: Copper (Cu): balance Nickel (Ni): 44% Impurity elements: ≤1.5% (including iron, manganese, silicon, etc.) Physical properties: Density: 8.8g/cm³ Thermal conductivity: about 330W/m·K Electrical conductivity: about 70%IACS (International Annealed Copper Standard) Mechanical properties: Tensile strength (σb): about 320MPa Yield strength (σ0.2): about 180MPa Elongation (δ5): about 40% Corrosion resistance: Excellent corrosion resistance in moderate salt spray environment. Good resistance to moisture, acidic gases and organic compounds. Processing performance: It has good cold and hot processing performance and can be processed by stamping, stretching, bending and other forming processes. 2. Industry standards and specifications The production and application of CuNi44 copper-nickel alloy plates must comply with relevant industry standards. The following are two commonly used industry standards: ASTMB137: American Society for Testing and Materials standard, which specifies the chemical composition, mechanical properties and corrosion resistance requirements of copper-nickel alloy plates. AMS4667: Aerospace material specification, suitable for the manufacture and testing of high-performance copper-nickel alloy plates. 3. Material selection misunderstandings When selecting CuNi44 copper-nickel alloy plates, the following three misunderstandings are prone to occur: Excessive pursuit of high nickel content: Although the increase in nickel content can improve the corrosion resistance of the alloy, excessive nickel content will lead to increased material costs and decreased processing performance. The 44% nickel content of