Yamawa/YMW ZELX Series Aerospace Taps for Stainless Steels, Nickel base & Titanium Alloys Spiral-Pointed Plug & Spiral Fluted Bottoming CNC High-Performance Taps (Made in Japan) Buy it Now : https://lnkd.in/eTGVDtW5 ☎ Phone: 401-490-1141 📧 e-mail: sales@cecs.us 🔗 Website: www.cecs.us 🔗 e-Commerce site: https://store.cecs.us 🔗eBay Store: https://lnkd.in/eaTJCa8J ☞ ZELX SS Series for Stainless Steels ☞ ZELX NI Series for Nickel base alloys ☞ ZELX TI Series for Titanium alloys ✔Features of ZELX SS ⁕ Custom blended vanadium high speed steel for high wear resistance ⁕ Ideal cutting edge design to prevent welding ⁕ Suitable surface treatment to prevent welding ✔Features of ZELX NI ⁕ Stainless Steels>30RC ⁕ Tools Steels and Mold Steels>30RC ⁕ Nickel Based Alloys, Inconel 718, Inconel X-750, Inconel 625 ⁕ Monel, Rene, Hastelloy, Waspalloy ⁕ Taps have an oxide and nitride surface toughening treatment. PM High Speed Steel ✔Features of ZELX TI ⁕ Suitable surface treatment to prevent welding and enhance wear resistance. ⁕ Optimum flute design to evacuate chips smoothly for each work material. ⁕ Ideal cutting edge design and thread relief for high heat resistance. ⁕ Premium PM High Speed Steel for high heat and wear resistance The demands for tapping into heat resistant alloys and stainless steels are increasing rapidly in the Aerospace Industry. The most common heat resistant alloys are Nickel base alloys, such as A286, Inconel, Hastelloy, Waspalloy, and Titanium alloys. There are considerable difficulties in tapping these materials due to their material features which can easily cause severe damage to taps. YAMAWA has the best line of taps for such a severe tapping conditions.
CECS OF CT LLC-Distributor for Aerospace Manufacturing & Metalworking Industrial Tools’ Post
More Relevant Posts
-
Alloys are mixtures of metals or metals and non-metals, offering enhanced properties compared to their individual components. Some common alloys and their advantages include: 1. Stainless Steel (Iron, Chromium, Nickel): - Corrosion resistance, durability, and hygiene. 2. Titanium Alloy (Titanium, Aluminum, Vanadium): - High strength-to-weight ratio, corrosion resistance, and biocompatibility. 3. Aluminum Alloy (Aluminum, Copper, Magnesium): - Lightweight, corrosion resistance, and improved strength. 4. Copper Alloy (Copper, Zinc, Tin): - Improved strength, corrosion resistance, and electrical conductivity. 5. Bronze Alloy (Copper, Tin): - High corrosion resistance, durability, and low friction. 6. Brass Alloy (Copper, Zinc): - Corrosion resistance, decorative appearance, and acoustic properties. 7. Inconel Alloy (Nickel, Chromium, Iron): - High-temperature resistance, corrosion resistance, and strength. 8. Monel Alloy (Nickel, Copper): - Corrosion resistance, high strength, and resistance to acidic environments. Alloys offer various advantages, including: - Improved strength and durability - Enhanced corrosion resistance - Increased high-temperature resistance - Improved electrical conductivity - Reduced weight - Aesthetic appeal - Biocompatibility By combining metals and non-metals, alloys exhibit unique properties, making them essential materials in various industries, such as aerospace, automotive, construction, and consumer goods.
To view or add a comment, sign in
-
The family of High-Leaded Tin Bronzes contains a variety of alloys. Here are a few common ones: C93200 (SAE 660): This is one of the most popular bearing materials. It is known for its excellent machinability, good hardness, and reasonable strength and wear resistance. It is widely used in general-purpose bearings, bushings, and automotive applications. C93400: Similar to C93200, this alloy has slightly different lead content, offering a balance between machinability and mechanical properties for specific applications. C93500: This alloy offers a slightly higher hardness and strength compared to C93200, with a trade-off in machinability. It's suitable for applications requiring a bit more wear resistance. C93700: Is commonly used in applications requiring reliable performance under conditions of moderate pressure and speed, such as in bearings, bushings, and wear plates. The high lead content in C93700 provides lubricity, enhancing its suitability for such applications. C93800: Known for its good machinability and wear resistance, this alloy is used in various applications, including bushings and bearings, where higher lead content is beneficial. C94000: This alloy is less common but offers a unique balance of properties, including good machinability and resistance to wear, for specific industrial applications. C94300: With a higher lead content, this alloy is designed for use in applications requiring excellent machinability and lubricity under moderate loads and speeds. Leaded Bronze #alloys are characterized by their varying compositions of copper, tin, lead, and sometimes other elements such as zinc, which are added to achieve desired mechanical properties. The high lead content in these bronzes provides excellent machinability and excellent anti-friction properties, making them ideal for bearings, bushings, and similar components. #copper #copperalloys #leadedbronze #highleadedtinbronze #metallurgy #engineering #bushings #bearings
To view or add a comment, sign in
-
What Are the Differences in Application Fields Between 6061 and 7005 Aluminum Alloys? 6061 is the designation for an aluminum alloy primarily alloyed with 1% magnesium and 0.6% silicon. 7005 is also an aluminum alloy designation, mainly alloyed with 4.5% zinc and 1.4% magnesium. T6 refers to a heat treatment process; for example, 6061-T6 is a 6061 frame that has undergone T6 heat treatment, which increases the strength of the aluminum. 7005 T6: Tensile strength is 51,000 PSI 6061 T6: Tensile strength is 45,000 PSI 7005 T6: Yield strength is 42,000 PSI 6061 T6: Yield strength is 40,000 PSI From this, it's clear that 7005 aluminum has higher strength than 6061 aluminum. However, 6061 aluminum offers better ductility than 7005. Thus, it's not accurate to say one is better than the other; both have their unique characteristics. 7005 is a commonly used aluminum material for frames, while T6 denotes a nominal 20-hour aging treatment, with T4 being a 10-hour aging treatment. Characteristics of 6xxx Series Aluminum: This series has medium strength, good plasticity, and excellent corrosion resistance, especially with low susceptibility to stress corrosion cracking. It also has excellent weldability and cold working properties, making it a versatile and promising alloy. Characteristics of 7xxx Series Aluminum: This is another commonly used alloy, rich in variety. It contains zinc and magnesium, with 7075 being the strongest aluminum alloy commonly used. However, it cannot be welded, and its corrosion resistance is relatively poor. It is often used for CNC machining. In this series, zinc is the primary alloying element, with a small amount of magnesium added to allow the material to be heat-treated for very high strength properties. Based on these characteristics, 6xxx series aluminum is more suitable for frames or other aluminum products that require welding. In contrast, the 7xxx series, represented by 7075, is better suited for components like cranksets that are one-piece molded and do not require welding, such as crank discs and handlebars. #aluminum #6063aluminum #7005aluminum #automotive #extruder
To view or add a comment, sign in
-
What alloys are used for die casting? Alloys Used in Die Casting 1.Aluminum Alloys Characteristics: Lightweight, corrosion-resistant, good thermal conductivity. Applications: Widely used in automotive, aerospace, and electronic products. 2.Zinc Alloys Characteristics: Excellent fluidity, easy to process, cost-effective. Applications: Commonly used for manufacturing small, complex parts, such as appliances and automotive components. 3.Magnesium Alloys Characteristics: Very good strength-to-weight ratio and mechanical properties. Applications: Often used in aerospace and automotive industries to reduce structural weight. 4.Copper Alloys Characteristics: Excellent wear resistance and electrical conductivity. Applications: Typically used for electrical components and parts with high strength requirements. 5.Cast Iron Characteristics: Good wear resistance and high strength. Applications: Mainly used in components for heavy machinery and equipment. These alloys are widely used in various industries for die-cast products due to their unique properties.
To view or add a comment, sign in
-
Do you know Beryllium titanium composite? Beryllium titanium composite (Be/Ti composite) is a composite material composed of titanium alloy and beryllium wire. In the 1970s, beryllium titanium alloy composite was used in the manufacture of aviation industry engines through research in the United States. It mainly uses the high temperature resistance and impact resistance of titanium alloy and the high modulus, low density and high strength of beryllium wire, as well as the obvious metal ductility of both in the temperature range of 450~750℃. It is produced by using the usual metal pressure processing technology, and single or multiple metal beryllium rods are inserted into the titanium alloy matrix material for extrusion. The beryllium wire reinforced titanium alloy composite was obtained. The proportional limit of the material is 137 ~ 275MPa, the tensile strength is 755~1160MPa, the elongation is 1% ~ 3%, and the modulus is 123 ~ 247GPa. There are two kinds of beryllium titanium composites: Ti-50Be and Ti-60Be. The tensile strength of Ti-50Be at room temperature is 848MPa, the elastic modulus is 1924MPa, and the elongation is 1.5%. Ti-50Be has a tensile strength of 765MPa and an elastic modulus of 1806MPa at room temperature
To view or add a comment, sign in
-
Senior Product Marketing Specialist of Ferro Alloys for steelmaking foundry//FESI//Nitried FECR//CASI//FESIBA//GPC//MN FLAKES//FESIMG// OFF GRADE SILILCON Servicing POSCO,JSW Since 2017
nitride ferro chrome used for production of special steels Nitride ferrochrome (FeCrN) is commonly used as an alloying agent in the production of special steels due to its ability to impart desirable properties to the steel. Nitride ferrochrome contains chromium and nitrogen as its primary constituents, along with iron and potentially other trace elements. The addition of nitride ferrochrome to steel can result in several beneficial effects: Improved Hardness: Nitride ferrochrome increases the hardness of the steel, making it more resistant to wear and abrasion. This is particularly useful in applications where the steel is subjected to high levels of mechanical stress. Enhanced Corrosion Resistance: Chromium in nitride ferrochrome forms a protective oxide layer on the surface of the steel, which enhances its resistance to corrosion. This is crucial in environments where the steel is exposed to moisture, chemicals, or other corrosive agents. Increased Strength: Nitride ferrochrome can improve the tensile strength and toughness of the steel, making it suitable for applications requiring high strength-to-weight ratios or impact resistance. Temperature Resistance: Nitride ferrochrome can contribute to the steel's ability to withstand high temperatures, making it suitable for use in elevated temperature environments such as automotive exhaust systems or industrial furnaces. Improved Machinability: In some cases, the addition of nitride ferrochrome can improve the machinability of the steel, making it easier to process and fabricate into finished components. Overall, the use of nitride ferrochrome in the production of special steels allows manufacturers to tailor the properties of the steel to meet specific performance requirements for diverse applications across industries such as automotive, aerospace, tooling, and engineering. To learn more about our #nitrideferrochrome and other ferro alloys, please comment below or email me at lisa@ferrosialloy.com. You can also reach me on Whatsapp at 8618624885692 #chenggang #metallurgy #ferroalloys #steelmaking #ferrosilicon #nitrideferrochrome
To view or add a comment, sign in
-
When we talk about casting, the type of metal alloy used can make a HUGE difference in how strong and long-lasting the final product is. Here’s a rundown of how various alloys affect durability and performance: 1. Iron Alloys: Grey iron: This is commonly used for its good machinability and wear resistance. It's great for things like engine blocks and brake discs. However, it's not very strong in extreme situations. Ductile Iron: This type is tougher and more flexible than grey iron. It can handle more stress and is less likely to crack, making it ideal for parts like crankshafts and heavy-duty gears. 2. Aluminium Alloys: Lightweight and Strong: Aluminium alloys are lightweight yet strong, which makes them perfect for automotive and aerospace parts where weight savings are important. Corrosion Resistant: They don’t rust easily, so they’re good for parts exposed to the elements, like outdoor equipment and marine components. 3. Steel Alloys: High Strength: Steel alloys are super strong and can handle a lot of pressure and stress. They’re used in construction equipment, bridges, and tools. 4. Copper Alloys: Bronze: Bronze is an alloy of copper and tin. It's very tough and resistant to wear and corrosion, making it suitable for bearings, bushings, and ship propellers. So it’s important for manufacturers to choose the right alloy and make sure their parts perform well in their intended applications. How do you decide the right alloy for you? www.vrsolus.com #centrifugalcasting #casting #machinemanufacturing | Kunal Pandya
To view or add a comment, sign in
-
❤Pros and Cons of Powder Metallurgy Gears❤ Powder metallurgy is a process technology that uses metal powders (or mixtures of metal and non-metal powders) to manufacture metal materials, composite materials, and various types of products through forming and sintering. Powder metallurgy gears are widely used in various automotive engines. Advantages: ♠Fewer manufacturing processes, sometimes several parts can be integrated into one; ♠Material utilization rate is over 95%; ♠Powder metallurgy gears have excellent repeatability because they are molded by molds. One set of molds can press tens of thousands or even hundreds of thousands of gear blanks; ♠The roughness of the pressing surface is very good for easy removal of blanks from the sub-mold. Disadvantages: ♠Must be produced in batches, MOQ ≥ 5000pcs per model ♠The size of the pressed part is limited, generally the diameter cannot exceed 110mm ♠Gear structure limitations: Due to pressing and mold reasons, it is generally not suitable for producing worm gears, helical gears with helix angles greater than 35°, and herringbone gears. Helical gears are generally recommended to be designed within 15°. ♠Thickness limitations: The cavity depth and press stroke must be 2-2.5 times the thickness of the gear, considering the uniformity of the longitudinal density of the gear height. Therefore, the thickness of powder metallurgy gears is also important. Finidatech's PM powders mainly focus on iron alloy powders and copper powders. For more detailed product information, please contact our product manager. #metallurgy #powdermetallurgy #PM #PMPowder #Finidatech #Finida #metallurgygears
To view or add a comment, sign in
-
RBI ENGINEER/INSPECTION ENGINEER/API PLANT INSPECTOR /CORROSION ENGINEER with API510, API570, API653, API571,API 580, CSWIP 3.1, ISO 9001:2015 LEAD AUDITOR(CQI&IRCA)and NDT-2, Diploma & Degree in MECHANICAL ENGINEERING.
Brief about COMPOSITION and Property Linkage in the STAINLESS STEEL family of alloys! Alloying elements play a crucial role in stainless steel, enhancing its properties and making it suitable for various applications. Here are some common alloying elements and their effects: 1. *Chromium (Cr)*: Provides corrosion resistance, oxidation resistance, and high-temperature strength. Minimum 10.5% Cr is required for stainless steel. 2. *Nickel (Ni)*: Improves corrosion resistance, ductility, and weldability. Nickel content varies from 3-22% depending on the grade. 3. *Molybdenum (Mo)*: Enhances resistance to pitting, crevice corrosion, and high-temperature oxidation. Typically added in amounts of 2-4%. 4. *Carbon (C)*: Affects strength, hardness, and weldability. Low carbon content (L-grade) reduces carbide precipitation, improving weldability. 5. *Manganese (Mn)*: Replaces some nickel, reducing costs. Also, improves high-temperature strength and hardness. 6. *Silicon (Si)*: Enhances high-temperature oxidation resistance and strength. 7. *Copper (Cu)*: Added to some grades for improved corrosion resistance in specific environments. 8. *Niobium (Nb)*: Stabilizes carbon, preventing carbide precipitation and improving weldability. 9. *Titanium (Ti)*: Also stabilizes carbon and improves weldability. 10. *Nitrogen (N)*: Increases strength, particularly at high temperatures. These alloying elements can be combined in various ways to produce different stainless steel grades, each with unique properties and applications. Some common grades include: - 304 (18-8): General-purpose, corrosion-resistant grade - 316 (18-10): Improved corrosion resistance, especially in marine environments - 410: Martensitic grade with high strength and hardness - 321: Titanium-stabilized grade for high-temperature application
To view or add a comment, sign in
-
#High-Temperature Alloy Hot Extrusion Machine: Revolutionizing Modern Manufacturing The manufacturing industry is undergoing a transformative phase, driven by advancements in technology and materials science. One of the critical innovations in this sector is the high-temperature alloy hot extrusion machine. This sophisticated piece of equipment is redefining how high-performance alloys are processed, offering unparalleled efficiency, precision, and quality in producing complex components. #Understanding High-Temperature Alloy Hot Extrusion Hot extrusion is a metal forming process where a billet (a solid block of metal) is heated to a high temperature and then forced through a die to create parts with a specific cross-sectional profile. This process is especially crucial for high-temperature alloys—materials designed to withstand extreme environments, such as those found in aerospace, automotive, and power generation industries. These alloys typically contain elements like nickel, cobalt, and titanium, which provide exceptional strength, corrosion resistance, and thermal stability.
To view or add a comment, sign in
111 followers
Specialist in LinkedIn Media Management, Archivist/ Project Consultant for the Ministry of Planning and Budget
2moAgradecimento por compartilhar