INNOVACERA | technical ceramic solutions

  The orifice plate is the opening where ions enter the mass spectrometer, one of the key components in the mass spectrometer. The function of the orifice plate is to have a voltage applied to it and to help prevent ions from clumping together.     The good orifice plate should be included below factors 1. Detachable heater It uses an MCH heater which is the abbreviation of metal ceramic heaters. It refers to a ceramic heating element in which a meta tungsten or molybdenum manganese paste is printed on a ceramic casting body and laminated by hot pressing and then co-fired at 1600°C, in a hydrogen atmosphere to co-sinter ceramic and metal.   MCH ceramic heating element is high-efficiency, environmentally friendly, and energy-saving.   MCH Heater has the advantages Energy-saving, high thermal efficiency, unit heat power consumption is 20-30% less than PTC; The surface is safe and non-charged, with good insulation performance, can withstand the withstand voltage test of 4500V/1S, no break

In the vast landscape of advanced materials, Boron Nitride Ceramics (BNCs) are a remarkable class of compounds renowned for their exceptional thermal stability, chemical inertness, and lightweight properties. Among the myriad applications that leverage these unique characteristics,   Boron Nitride Ceramic Evaporation Boat Sets   have emerged as indispensable tools in high-temperature processing industries, particularly in semiconductor manufacturing, vacuum metallization, and advanced coating technologies. The Essence of Boron Nitride Ceramics Boron Nitride (BN) , a compound of boron and nitrogen, exists in various crystalline forms, each with distinct properties. Among them, hexagonal boron nitride (h-BN) and cubic boron nitride (c-BN) are the most commonly utilized in ceramic applications. BNCs, particularly those made from pyrolytic processes, exhibit unparalleled resistance to extreme temperatures, making them ideal candidates for use in environments where conventional materials wo

Alumina Ceramic (Al₂O₃) Advanced Ceramics are used in electronics and technology. It has unique properties that make it serve important insulative, sensor, resistive, capacitive, magnetic functions, and electrooptic in electrical and electronic circuitry. In this article, we will explore the applications of Advanced Ceramics in Electronics and Technology.   1. Properties of Advanced Ceramics in Electronics and Technology Advanced Ceramics are known for their excellent electrical and thermal properties. They have high thermal conductivity, which makes them ideal for heat sinks, helping to dissipate heat from electronic components. They also have high dielectric strength, which makes them suitable for electronic components such as resistors, capacitors, and insulators.     2.Advanced ceramic materials with high electrical performance Alumina:  Alumina Ceramic (Al₂O₃)  are a common ceramic material used in electronic components. It has high dielectric strength, and high thermal conductivi

  1. Protective Materials During the steel smelting process, it can be used as a protective material to protect metal materials. For example, in the continuous casting process,  Boron Nitride (BN)  can be used as a protective slag to effectively prevent slag inclusion defects in castings and reduce the wear of the tundish and crystallizer. In addition, BN can also be used as a filter material for molten metal to filter out impurities and gases in the metal and improve its quality and purity.   2. Thermal materials Due to its high thermal conductivity and good thermal stability, this material can be used as a thermal material in the metallurgical industry.   For example, in the steel smelting process, BN can be used as the main material for high-temperature equipment such as crucibles and thermocouple sleeves and has good high-temperature oxidation resistance and high-temperature strength.   In addition, it can also be used as a lining material for high-temperature furnaces to improve t

  Ceramic reflector   is designed to reflect and direct light efficiently with various applications. Compared with traditional reflectors made of metals like aluminum, our ceramic reflectors are crafted with advanced ceramic materials 99 Alumina ceramic which has several advantages: 1. Optical Properties: Alumina has high reflectivity in certain wavelengths. It can control the diffusion of light more precisely and control light distribution and efficiency, which makes ceramic reflectors suitable for optical systems, specialized lighting applications, and scientific instruments.   2. Thermal Stability: compared with metals, Al2O3 has higher thermal stability which can withstand much higher temperatures without deforming or losing their reflective properties. It makes ceramic reflectors an ideal component where heat resistance is crucial, such as in industrial furnaces, high-intensity lighting, and automotive headlights.   3. Electrical Insulation: 99 Alumina is an excellent electrical i

  INNOVACERA presented a new material, High-temperature Magnesia Zirconia, also called   Magnesium Stabilized Zirconia Ceramic . It is a great refractory and insulating material due to high oxygen ion conductivity, strength and toughness, and good thermal shock resistance. it has a clean melt at temperatures above 1900’C and above and is specially manufactured for melting superalloys and precious metals. its superior thermal shock resistance to temperatures reaching up to 2200℃.   The Magnesia Stabilized Zirconia has a 1-18% porosity, so it’s different from normal MgO-ZrO2. This material is often used as sizing nozzles in continuous casting, ladle slide plates, setter plates in the metal powder industry, and gas atomizing nozzles.   Sizing nozzle for molten steel The sizing nozzle made of Magnesia Zirconia has very high properties including high mechanical strength, very good thermal shock resistance, good corrosion resistance, erosion resistance, and low thermal expansion.   The sizin

INNOVACERA is glad to offer new standard filament assemblies, a critical component in mass spectrometry applications for the analytical and medical industries.   Principle of mass spectrometer filament Mass spectrometer filament is also called ion source filament or cathode filament. It is mainly made of high melting point metals such as  tungsten (W)  or molybdenum. Its function is similar to that of ordinary filaments. It mainly produces electron emission under high pressure and excites gaseous molecules into ions, thereby generating the charge-to-mass ratio signal required for mass spectrometry.     These filament supports are manufactured using 96% alumina, selected for its good electrical insulation and high-temperature stability. Customers can choose between two and four-pin options, with the pins brazed into the alumina insulator ready for filament welding. Our brazing process makes the filament considerably more resistant to higher temperatures, around 700°C compared with stand