Business Services & Service Equipment

Lead Ingot Pb99.994 Lead is a soft and malleable metal that is considered as a heavy metal. With the Pb symbol and 82 atomic number, corrosion & low temperature resistant lead finds use in many sectors and products, from lead-acid batteries, cables, bearings, cathode ray tubes, weights to building construction industry, chemical industry and auto battery manufacturers. Compared to all stable elements, this metal has the highest atomic number. As a Lead Ingot Manufacturer, we strive hard to cater to the diverse and specific industrial requirements in a prompt and cost-effective manner.If you want to get more information, please feel free to contact us.   Application of Lead Ingot: The largest sector consuming lead is Battery, accounting for three-quarters of the total demand. Batteries are divided into following: 1. Starting-Lighting-Ignition or SLI batteries are currently consuming over half of the total lead that is in demand. These batteries are majorly used in light vehicles. Their usage is not limited to cars but also boats and golf carts. The demand of SLI batteries can be divided into original equipment and replacement. The replacement demand is surpassing original equipment demand by nearly about 4:1 in various markets. 2. Industrial batteries are currently consuming a quarter from the total lead production. This sector includes stationary and traction batteries, divided roughly 50:50. Stationary batteries primarily finds application in back up power supply systems whereas traction batteries finds use in motorised wheelchairs and forklift trucks. The remaining lead finds use in non-battery applications. Lead is supplied to several other industries to be used as a pure metal, as a chemical compound or alloyed with other metals, for following applications: It can be used for making lead pipes for the transport of corrosion chemicals and other material. It is used in paint industry as a lead-based pigment. It is used in cable industry as sheathing material for power cables. It also finds use in computer monitors, television screens, Poly Vinyl Chloride (PVC) stabilizers and other industrial products.

To give performers a better storage environment, as one of dry cabinet manufacturers, Dryzone provides quality dry cabinets for instruments like guitars for various artists. Our dehumidifier guitar dry cabinet can provide constant temperature and humidity for stable storage. Musical instrument deserves our love & care, the return is the sweet sound and awesome perfect performance. Guitar Dry Dehumidifier Cabinet Specifications HDL-190 Dry Cabinet for Guitar Capacity: 124L External Dimension: W400*D408*H895mm Internal Dimension: W398*D380*H823mm Shelves: 3units HDL-300 Dry Cabinet for Guitar Capacity: 255L External Dimension: W400*D528*H1375mm Internal Dimension: W398*D500*H1280mm Shelves: 3units HDL-300 Dry Cabinet for Guitar Guitar Dry Dehumidifier Cabinet Features As one of the professional dry cabinet manufacturers in China, Dryzone not only provides dry cabinets for guitars but also humidity storage cabinet for many other instruments. We can make customized commercial desiccant drying cabinets for different instruments of different sizes. The guitar dry cabinet prevents instruments from moisture damage, mildew- growing, wooden chapped, and sound damage. Dry Cabinet For Guitar Design Precise Digital display and controller to keep the fluctuation of humidity at less than +/-3%RH; Wooden musical instruments such as cello, violin, and guitar can be set at 50%RH in summer,40% in winter; Bronze Trumpet, saxophone, and cornet musical instruments can be set at 20% to prevent fungi and bad odor.

Minimum Order: 1 bags

Cameras need to put in temperature <10℃ or humidity <60%RH, then the mildew will stop growing, Dryzone camera storage cabinet is specially design for camera storage which could not only well protect the camera from moisture damage, but also protect the camera lens breaking. Good moisture resistance. Compared to camera bags with desiccant, the electronic dry box for camera gear has much better moisture-proof functions. Permanent moisture saves time and effort. Compared to the traditional plastic dry box which is easily broken and needs to change the desiccant frequently. The camera dry cabinet avoids such problems. Dehumidifier Dry Cabinet For Cameras & Lenses Specifications HDE-300 Drying Cabinet For Camera Capacity: 255L External Dimension: W400*D528*H1375mm Internal Dimension: W398*D500*H1280mm Shelves: 3units HDE-300 Drying Cabinet For Camera How Does a Camera Dry Cabinet Dehumidifier Work? Moisture is the enemy of cameras. High moisture levels can cause damage to the camera's internal components, such as condensation on the lens, rust on the metal parts, and fungus on the camera sensors. Protecting your camera against moisture is one of the main reasons why you need a dry box. Other reasons why you might need a dehumidifier cabinet for camera include: Protecting the camera from dust, dirt, and other debris. Keeping your camera organized. Keeping your camera safe from accidental damage. A dehumidifier box for camera uses either the desiccant or the thermoelectric cooling system to keep the moisture levels low. Desiccant boxes work by absorbing moisture from the surrounding air while cooling systems use Peltier's effect to reduce humidity levels. Most camera dehumidifier cabinets operate silently, and you can set the humidity level according to your preferences. Some models come with a hygrometer or a digital display that shows the current humidity level. Size Guideline When Buying a Dry Box for Camera Storage When buying a humidity control cabinet for camera, size is an important factor to consider. You want to make sure that the box you choose is big enough to accommodate your camera, lenses, and other accessories, while also being compact enough to fit in your storage space. Here are some size guidelines to help you choose the right dry box for your needs: Determine the size of your camera and accessories - Measure the dimensions of your camera body, lenses, and other accessories that you want to store in the dry box. This will help you determine the minimum size you need for the box. Choose a box that is at least 1.5 times the size of your camera and accessories - A good guideline is to choose a box that is at least 1.5 times bigger than your camera and accessories. This gives you enough space to store your camera with room to spare for future purchases. Consider the type of camera you have - The size of your camera and accessories will vary depending on whether you have a DSLR, mirrorless, or point-and-shoot camera. Consider the space you need for each type of camera when choosing the size of your dry box. Check the internal dimensions of the dry box - When shopping for a dry box, make sure to check the internal dimensions of the box rather than just the external dimensions. This will give you a more accurate idea of how much space you have to work with.

Minimum Order: 1 bags

At Dryzone, we understand that your electronic components are valuable assets, and we are dedicated to providing the best possible storage solutions for your needs. Invest in our electronic humidity control digital dry cabinets today and experience the peace of mind that comes with knowing your electronics are safe and secure. What is an electric dry box? An electronic dry box cabinet cases is a type of storage cabinet case that uses a heating and dehumidifying system to keep items inside a low-humidity environment. These boxes are ideal for storing moisture-sensitive items such as camera equipment, electronics, and other valuable items that need to be protected from moisture and humidity. Electric dry boxes typically have a built-in thermostat that ensures that the temperature inside the box stays constant, preventing the build-up of moisture. Some electric dry boxes also have a programmable timer so that you can set the amount of time the box is heated and dehumidified. Electric dry boxes are commonly used in industrial settings and by photographers, but they are also becoming increasingly popular for use in homes. They provide a safe and secure environment for storing important items and help to extend the lifespan of the items by protecting them from moisture and humidity. Advantages of using a dry box for electronic components over baking 1. Preservation of equipment: A dry cabinet helps to preserve the form, structure and electrical properties of electronic equipment. It prevents the oxidation and corrosion of metal surfaces from long-term exposure to moisture. 2. Time-saving: Baking electronic components requires a considerable amount of time that could be spent on other tasks. A dry cabinet requires minimal effort since there is no need for preheating or monitoring of the equipment as with baking. 3. Safety: One of the advantages of using a dry cabinet is that it eliminates the possibility of equipment damage that is inherent with baking. Baked electronic components may become brittle and fragile, leading to permanent damage or failure. In contrast, dry cabinets provide a safer environment and minimize risks associated with equipment handling. 4. Versatility: Dry cabinets are can be adjusted to a range of relative humidity levels in order to customize the environment to meet the specific needs of various electronic components. 5. Efficiency: dry storage cabinets for component storage provide efficient moisture control by eliminating the need to constantly monitor relative humidity levels of electronic components. Moreover, dry cabinets are energy efficient since they require less energy to maintain the required moisture control as compared to the constant heating required for baking services. 6. Extended life of components: Dry cabinets are highly beneficial for longer term storage of electronic components as they maintain the integrity of the equipment and prevent damage from exposure to the elements. Thus, they prolong the life of electronic components. Advantages of an Electronic dry cabinet box for camera The electronic dry box dehumidifier for camera is an essential accessory for any photography enthusiast or professional. It is a specially designed cabinet that helps protect your camera and lenses from moisture, dust, and fungus. This electronic cabinet uses an advanced dehumidifying technology to maintain a constant low humidity level, ensuring that your camera stays safe and dry at all times. The cabinet features a digital display screen that allows you to monitor the humidity levels and adjust them accordingly. It also has a locking mechanism to keep your camera and lenses secure. The cabinet is made of high-quality materials, including stainless steel and toughened glass, to provide durability and long-lasting protection to your camera equipment. With this electronic dry storage humidity cabinet box, you can be sure that your camera and lenses will remain in excellent condition for longer. It is an investment worth making for professional photographers or anyone who values their camera equipment. There are several advantages of an electronic dry cabinet box for cameras, including: 1. Protection: The primary advantage of the electronic dry cabinet box is that it offers protection to your camera and accessories from humidity, dust, and fungus, which can cause damage to your camera and lenses. 2. Prevents corrosion: High levels of humidity can cause corrosion in metal parts of your camera or lenses. By storing your camera equipment in a dry cabinet, you can prevent corrosion and extend the lifespan of your equipment. 3. Low maintenance: An electronic dry cabinet box requires minimal maintenance. It does not require replacement of desiccant or other consumables frequently, and the built-in dehumidifier ensures that you do not have to worry about continuous monitoring. 4. Saves money: By protecting your camera equipment from moisture, dust, and fungus, you can avoid costly repairs or replacements. 5. Easy access: The electronic dry cabinet box is designed for easy access to your camera equipment. It can store various camera accessories of different sizes and shapes, including lenses, camera bodies, batteries, and memory cards. 6. Energy-efficient: Electronic dry cabinet boxes are energy-efficient and consume far less energy than other types of dry boxes. In summary, electronic dry cabinet boxes provide a safe, secure, and low- maintenance storage solution that can protect your camera equipment and save you money in the long run. Slinger vs Ruggard dry cabinet Slinger dry cabinets and Ruggard dry cabinets are both designed to protect your camera gear, lenses, and other sensitive items from moisture, humidity, and dust. However, there are some key differences between the two. Slinger cabinets feature an LCD display that shows the current humidity level and temperature inside the cabinet, and they also have a built-in hygrometer for measuring humidity levels. The cabinets come in different sizes and are sometimes cheaper than Ruggard models. On the other hand, Ruggard dry cabinets are a bit more expensive but offer robust performance and top-of-the-line features. These cabinets feature LED lighting and also have a digital hygrometer to measure humidity levels. They come in different size variants too. Both cabinets use a thermoelectric cooling system to regulate the temperature inside the cabinet and keep the humidity at safe levels. Both cabinets are reliable and well-built, but the choice between them depends on your preference and budget. Looking for a reliable and secure way to store your electronic components? Look no further than our dry storage cabinets! Our cabinets are designed specifically for sensitive electronic equipment, featuring low humidity levels of 0-50% RH to prevent corrosion and damage to your components. With adjustable shelves and customizable configurations, our cabinets can be tailored to your unique needs and offer optimal organization and storage space for all of your electronic components.

Minimum Order: 1 bags

In semiconductors, optoelectronics, precision electronics, and other industries, many components and materials will be affected by moisture or oxidation when they are directly stored in ordinary environments. The physical structure of nitrogen N2 is stable, and the gas with a lower cost is just suitable to be used as the protective gas of the product. Thus, the nitrogen gas cabinet can protect the products that need to be stored in a nitrogen atmosphere. A nitrogen cabinet storage is a type of laboratory equipment that uses a flow of nitrogen gas to create an inert, oxygen-free environment within an enclosed space. The purpose of this is to protect sensitive materials or samples from exposure to oxygen or other contaminants that may negatively affect their stability, reactivity, or accuracy. The Dry Nitrogen Gas Cabinets are Mainly Composed of Three Parts: In the part, the surrounding of each door is composed of magnetic sealant strips, and there is also pressed sealant cotton around the glass to ensure the overall airtightness of the cabinet; The pipeline part, nitrogen pipeline-nitrogen flowmeter-nitrogen saving module QDN-pipe enters the dry nitrogen storage cabinet; The circuit part mainly includes a power supply, control panel, and power supply box. The Materials of Nitrogen Dry Box Storage Cold-rolled steel plus anti-static spray can meet the storage of products in an ordinary environment; Stainless steel (also divided into mirror and brushed stainless steel, click here for more about stainless steel desiccator cabinet ) is mainly used in clean rooms of class 100 and above or in corrosive environments; Working Process and Principle of Dry Nitrogen Storage Cabinets To create the nitrogen atmosphere, the dry nitrogen storage cabinets is connected to a nitrogen gas source, usually through a regulator that allows the user to control the flow rate and pressure of the gas. The gas is then fed into the cabinet through one or more small ports or diffusers located at the top of the cabinet. So we need to find out the humidity conditions required for product storage and then set the humidity value through the control panel. Turn on the QDN. As the nitrogen gas flows into the nitrogen dry box storage, it displaces the oxygen and other gases in the air, reducing the oxygen concentration to less than the setting value. Then the QDN auto-cut the N2 filling. This creates a stable, oxygen-free environment that is suitable for a variety of laboratory applications, including the storage of chemicals, electronics, or biological samples. Nitrogen enters the N2 cabinet, the air in the nitrogen storage cabinet is gradually diluted by nitrogen, and the humidity and oxygen content will gradually decrease. When nitrogen is continuously charged, the pressure in the cabinet will also rise, which will compress the sealing strip and make the original air quickly replaced.In addition, note that the pressure of the external nitrogen should not be too large, and the specific use should be adjusted according to the N2 cabinet specifications. What's the application of Dry Nitrogen Storage Cabinets Nitrogen gas storage cabinets have several applications in laboratory settings, including: Preservation of sensitive materials: Many materials, including chemicals, electronic components, and biological samples, can be sensitive to moisture, oxygen, or other contaminants in the air. By storing these materials in a N2 cabinet, they can be protected from exposure to these contaminants, preserving their integrity and stability over time. Chemical reactions: Some chemical reactions can be sensitive to oxygen or other gases in the air, and require an oxygen-free environment to proceed properly. Nitrogen cabinets can be used to create these environments, allowing researchers to conduct experiments with greater precision and control. Semiconductor manufacturing: In the production of electronic components, such as microchips and printed circuit boards, it is important to avoid exposure to moisture and other contaminants that can damage the materials. Nitrogen cabinets can be used to create a controlled, clean environment for manufacturing these components, improving their reliability and performance. DNA sequencing: In DNA sequencing, it is important to maintain the stability and integrity of the DNA samples throughout the sequencing process. Nitrogen cabinets can be used to store and protect these samples, ensuring accurate and reliable results. Overall, nitrogen desiccant storage cabinets are an essential tool for researchers and scientists who need to protect sensitive materials and maintain a controlled environment for their experiments and processes. If you want to buy a dehumidifying dry cabinet, please contact us.

Minimum Order: 1 bags

Dryzone Nitrogen desiccator cabinet is 1-50% RH adjustable and it has two series, one is the CQB series which is an ESD paint structure, and one is the CQS series which is stainless steel structure and CQS series could comply with clean room demand. Both series are equipped with QDN (nitrogen saving module). Our large nitrogen dry box desiccator features precise humidity and temperature control, reliable ESD protection, and low power consumption. Specifications of Baking Nitrogen Desiccator Cabinet CQB-1200-6 Nitrogen Desiccator Cabinet Outside Dimension W1200*D695*H1820MM Internal Dimension W1198*D645*H1618MM Capacity 1250L Shelves 5 shelves Color Black ESD Paint 106~109Ω (surface resistance) Voltage 230V/110V CQB-600 Nitrogen Desiccator Box Outside Dimension W600*D695*H1820MM Internal Dimension W598*D645*H1618MM Capacity 624L Shelves 5 shelves Color Black ESD Paint 106~109Ω (surface resistance) Voltage 230V/110V CQB-400 Nitrogen Dry Box Desiccator Outside Dimension W600*D695*H1274MM Internal Dimension W598*D645*H1071MM Capacity 413L Shelves 3 shelves Color Black ESD Paint 106~109Ω (surface resistance) Voltage 230V/110V CQB-575 Nitrogen Desiccator Cabinet with Good Price Outside Dimension W905*D823*H1050MM Internal Dimension W903*D773*H869MM Capacity 607L Shelves 3shelves Color Black ESD Paint 106~109Ω (surface resistance) Voltage 230V/110V CQB-315 Nitrogen Large Desiccator Cabinet Outside Dimension W905*D475*H1050MM Internal Dimension W903*D425*H869MM Capacity 334L Shelves 3shelves Color Black ESD Paint 106~109Ω (surface resistance) Voltage 230V/110V CQB-157 Nitrogen Stainless Steel Desiccator Outside Dimension W600*D672*H1820MM Internal Dimension W448*D425*H869MM Capacity 165L Shelves 3shelves Color Black ESD Paint 106~109Ω (surface resistance) Voltage 230V/110V CQS-1200-6 Nitrogen Stainless Steel Desiccator Cabinet Outside Dimension W1200*D695*H1820MM Internal Dimension W1198*D645*H1618MM Capacity 1250L Shelves 5 shelves Color Silver white Material Stainless steel (304) structure Voltage 230V/110V Now the price of dehumidifier dry cabinet is reasonable, if you want to buy dry cabinet storage, please contact us.

Minimum Order: 1 bags

Dryzone n2 dry box has a fast recovery time which is important for some industry demand, especially the Semicon industry. Our N2 cabinets use the humidity value to control the N2 filling, and they are equipped with QDN(Nitrogen Saving Module) which could save 40-60% RH N2 compared to traditional nitrogen dry box, and we could also upgrade your traditional nitrogen cabinet or dry cabinet with our NC-2 (Nitrogen Controller Module) to help you save the N2 or dry air if you are in need. Our Dryzone dry nitrogen box is the perfect solution. Equipped with advanced features such as low-humidity control, adjustable shelves, and anti-static protection, this cabinet ensures optimal performance and protection. NITROGEN CABINET FOR SALE Dryzone Nitrogen Desiccator Cabinet CQS-1200-6 Nitrogen Cabinet Humidity Range: 1~50%RH, adjustable Outside Dimension: W1200*D672*H1820MM Internal Dimension: W1198*D644*H1618MM Nitrogen Filling Module: QDN*1 Loading Capacity of Shelf: 80 kgs/per shelf Capacity: 1250L Shelves: 5 pcs, adjustable Color: Silver Structure: SUS 304 Display Precision: ±3%RH;±1°C Resolution: 0.1%RH; 0.1°C Power Consumption: Ave. 20W/h; Max. 50W HOW DOES DRYZONE NITROGEN CABINET WORK COMPARE TO TRADITONAL NITROGEN CABINET? Dryzone nitrogen cabinet adopts an intelligent FUZZY micro-computer induction system. After setting the humidity value, the microcomputer will automatically sense, and when the humidity exceeds, nitrogen will be added. Otherwise, it will stop N2 filling, which can really achieve the effect of energy saving. And have the N2 delay filling design when opening the door to fetch goods, in this way to avoid unnecessary loss of nitrogen, abandon the traditional use of a real-time controller and magnetic valve to sense the intake time of the opening and closing door, set a fixed time for N2 filling, tend to cause the loss of N2. Other than the traditional moisture prevention by using desiccant, you could also choose the Dryzone nitrogen control cabinet which just fills N2 to remove the moisture. The principle is the moisture is HO2 which is in the air, by filling N2 and setting the humidity value in the LED, the nitrogen will squeeze the air in the nitrogen desiccator cabinet and remove the humidity in the air and once the humidity reaches your setting value, it will stop N2 filling. And compare to the traditional dry box cabinet, the nitrogen control cabinet always has a faster recovery time. N2 Cabinet Specifications CQB-315 Nitrogen Cabinet Outside Dimension: W905*D475*H1050MM Internal Dimension: W903*D425*H869MM Capacity: 334L Shelves: 3shelves Power Consumption: 55w/h(Ave);150w/h(Max) Color: Black ESD Paint: 106~109Ω N2 Cabinet Specifications CQS-1200-6 Nitrogen Cabinet Outside Dimension: W1200*D695*H1820MM Internal Dimension: W1198*D645*H1618MM Capacity: 1250L Shelves: 5 shelves Power Consumption: 105w/h(Ave);300w/h(Max) Color: Siver White Voltage: 230V/110V Nitrogen Control Cabinet FAQs  What you need to prepare if you buy a dry nitrogen box?  Better to have nitrogen pipe in your factory. If not, ask Dryzone, one of the pro dry cabinet manufacturers in China, for help. If I already have a traditional nitrogen cabinet or a N2 dry box made by other brand, could it be upgraded?  Yes, by adding our NC-2(nitrogen controller module) we could upgrade your humidity storage cabinet and help you save the N2. If you already have a Dryzone nitrogen dry storage cabinet, could it be upgraded to nitrogen cabinet?  Yes, normally all our nitrogen desiccator cabinets will leave some room for upgrade, just come to us for further info.

Minimum Order: 1 bags

While floating through the molten tin, the combination of gravity and surface tension results in smooth and flat surfaces on both sides. a) Smooth and flat surface and good vision. b) Excellent optical performance. c) Stable chemical properties. d) Resistant to acid, alkaline, and corrosion. Specification of Float Window Optical windows are an essential component of many optical systems, including lasers, cameras, telescopes, and microscopes. They allow light to enter or exit an optical system while providing a barrier to dust, moisture, and other contaminants. There are various types of optical windows available, including sapphire, quartz, and borosilicate glass. Material Float Glass Diameter 1 to 500 mm Diameter Tolerance +0/-0.02 mm Thickness Tolerance ±0.01 mm Surface Quality 10-5 Surface Figure λ/10 Parallelism 1 Minute Coating Uncoated, AR, HR, Beamsplitter, etc. Types of optical window glass for your needs: Quartz window Sapphire glass window ZnSe selenide window Germanium IR window Si window borosilicate glass windows Bk7 window What are Float Glass Optical Windows? Float glass is a type of glass that is manufactured by floating molten glass on a bed of molten tin. This process results in a uniform thickness and a flat surface, making it an ideal material for optical windows. Float glass optical windows are made from a high-quality, low-iron glass that has excellent optical properties. Advantages of Float Glass Optical Windows Float glass optical windows offer several advantages over other types of optical windows. Some of the benefits include: High Transmission Float glass optical windows have excellent optical properties, providing high transmission of visible and infrared light. Low Birefringence Birefringence is the property of a material that causes light to split into two polarizations. Float glass optical windows have low birefringence, making them suitable for applications that require polarization control. Cost-Effective Float glass optical windows are more cost-effective than other types of optical windows, such as sapphire or quartz. High Durability Float glass optical windows are highly durable and can withstand harsh environments and temperature fluctuations. Applications of Float Glass Optical Windows Float glass optical windows are used in a wide range of applications, including: Laser Systems Float glass optical windows are commonly used in laser systems as protective windows or beam splitters. Microscopy Float glass optical windows are used in microscopy to protect the lens from dust and other contaminants. Industrial Applications Float glass optical windows are used in industrial applications that require high durability, such as sensors, displays, and cameras. Selection Criteria for Float Glass Optical Windows When selecting float glass optical windows, several factors should be considered, including: Material The quality of the float glass material should be assessed to ensure that it meets the required optical and mechanical properties. Coatings Float glass optical windows can be coated with various materials, such as anti- reflection coatings, to improve their optical performance. Thickness The thickness of the optical window should be determined based on the application requirements, such as the required transmission or durability. Size The size of the optical window should be selected based on the dimensions of the optical system and the required field of view. Surface Quality The surface quality of the optical window should be evaluated to ensure that it meets the required specifications, such as roughness and flatness. Environmental Conditions The environmental conditions, such as temperature and humidity, should be taken into consideration when selecting float glass optical windows to ensure that they can withstand the intended operating conditions. Manufacturing Process of Float Glass Optical Windows Float glass optical windows are manufactured using the following process: Raw materials, including silica sand, soda ash, limestone, and dolomite, are mixed and melted in a furnace at a temperature of around 1500°C. The molten glass is then poured onto a bed of molten tin, forming a uniform layer of glass that is cooled gradually. The cooled glass is then cut into the required sizes and shapes using diamond- tipped tools. The optical windows are then polished to achieve the required surface quality. Cleaning and Maintenance of Float Glass Optical Windows Float glass optical windows require proper cleaning and maintenance to ensure their long-term performance. Here are some tips for cleaning and maintaining float glass optical windows: Cleaning Use a soft, lint-free cloth or a microfiber cloth to clean the optical window. Avoid using paper towels or abrasive materials, as they can scratch the surface of the window. Apply a small amount of a gentle cleaning solution, such as isopropyl alcohol or lens cleaning solution, to the cloth. Gently wipe the surface of the optical window in a circular motion, starting from the center and moving towards the edges. Use a dry cloth to remove any remaining cleaning solution. Maintenance Store the optical windows in a clean, dry environment to avoid contamination and damage. Inspect the optical windows regularly for any signs of damage or wear, such as scratches or cracks. Handle the optical windows with care, using gloves or other protective equipment to avoid fingerprints or smudges. Avoid exposing the optical windows to extreme temperatures or humidity, as this can affect their optical properties. FAQs Float glass optical windows are a cost-effective and high-quality option for many optical applications. They offer excellent optical properties, low birefringence, and high durability. When selecting float glass optical windows, it is important to consider factors such as material, coatings, thickness, size, surface quality, and environmental conditions. Proper cleaning and maintenance of float glass optical windows can ensure their long-term performance and reliability. What is float glass? Float glass is a type of glass that is manufactured by floating molten glass on a bed of molten tin. What are the advantages of float glass optical windows? Float glass optical windows offer high transmission, low birefringence, cost- effectiveness, and high durability. What are some applications of float glass optical windows? Float glass optical windows are used in laser systems, microscopy, and various industrial applications. How should I clean float glass optical windows? Use a soft, lint-free cloth and a gentle cleaning solution, such as isopropyl alcohol or lens cleaning solution. How can I maintain float glass optical windows? Store them in a clean, dry environment, handle them with care, and inspect them regularly for damage or wear. If you are looking for a reliable custom optics supplier, please contact us, and we will be your best partner.

Minimum Order: 100

Boro Glass for Sale Borosilicate is the alternative for borofloat 33 (BF33). Therefore, this kind of glass is called high borosilicate glass. Our Borosilicate window has high transmittance in the visible and near-infrared regions, making it ideal for a wide range of optical applications. It boasts a unique combination of excellent optical clarity and durability, allowing it to perform well in harsh environments. Borosilicate Window Characteristics & Specification Borosilicate glass windows are widely used in a variety of applications due to their high thermal and chemical resistance, as well as their excellent optical properties. They are commonly used in scientific and industrial settings for applications such as microscopy, spectroscopy, and chemical processing. Material Borosilicate Diameter 1 to 500 mm Diameter Tolerance +0/-0.02 mm Thickness Tolerance ±0.01 mm Surface Quality 10-5 Surface Figure λ/10 Parallelism 1 Minute Coating Uncoated, AR, HR, Beamsplitter, etc. Our product is designed with exceptional heat resistance and thermal shock resistance, making it ideal for high-temperature environments. With its excellent resistance to chemical damage, you can rest assured that our custom borosilicate glass window is built to last. With TC Optik's Borosilicate window, you can expect superior performance and reliability - all at a competitive price point. Whether you're involved in research, development or industrial applications, our boron silicate glass window is the perfect solution for your optical needs. Types of optical window glass for your needs: Fused quartz glass Custom sapphire windows ZnSe focus lens Germanium window Silicon window BK7 fused silica Float glass optical windows Borosilicate glass' high-temperature resistance is very great and it can make a popular material for laboratory equipment. Its low temperature tolerance makes it an ideal choice for many different uses. Borosilicate glass has several unique properties, including low thermal expansion. Its high heat resistance enables scientists to study tiny organisms. It is a popular telescope material because it can withstand extremely high temperatures and a range of temperature variations. It is best suited for applications that require an extremely high level of security. Advantages and Benefits of Borosilicate Glass Windows Optical Properties Borosilicate glass windows have excellent optical properties, with a high level of transparency in both the visible and near-infrared (NIR) regions. They have a refractive index of around 1.5, making them an ideal material for use in optical systems that require minimal refraction or reflection. Physical Properties Borosilicate glass windows are known for their high thermal and chemical resistance. They have a low coefficient of thermal expansion, which means that they can withstand rapid temperature changes without cracking or breaking. They are also resistant to chemical corrosion, making them ideal for use in harsh chemical environments. Borosilicate Glass Uses What is borosilicate glass used for? Borosilicate glass is very strong and cheap. So it is widely used in different areas. Borosilicate has a low temperature, so it is a good choice for different applications. Because borosilicate glass has high-temperature resistance, it is best for telescope material. Its durability makes it a perfect material for lab equipment. It can be molded into tubes and drawn into custom shapes. borosilicate glass is also very good for scientific instruments, such as microscopes, and testing machines. borosilicate glass is durable enough to withstand high heat and corrosive materials. It is dishwasher-safe and microwave safe Borosilicate glass used for Microscopy Borosilicate glass windows are commonly used in microscopy applications, where their high transparency and low refractive index make them ideal for use in optical systems. They are often used in fluorescence microscopy, where their low autofluorescence helps to reduce background noise. Borosilicate glass used for pectroscopy Borosilicate glass windows are also used in spectroscopy applications, where their high transparency and low refractive index make them ideal for use as beamsplitters or windows for sample chambers. They are often used in Fourier transform infrared (FTIR) spectrometers, where they are used as beamsplitters or windows for sample chambers. Borosilicate glass used for Chemical Processing Borosilicate glass windows are used in chemical processing applications due to their high resistance to chemical corrosion. They are often used as sight glasses in chemical reactors or as windows for chemical processing equipment. FAQs of Boro Glass What is borosilicate glass made of? A: Borosilicate glass is made of silica and boron trioxide. What is the coefficient of thermal expansion of borosilicate glass? A: The coefficient of thermal expansion of borosilicate glass is very low, which means that it can withstand rapid temperature changes without cracking or breaking. Can borosilicate glass be used in harsh chemical environments? A: Yes, borosilicate glass is highly resistant to chemical corrosion, making it ideal for use in harsh chemical environments. What is the refractive index of borosilicate glass? A: The refractive index of borosilicate glass is around 1.5. What is the typical thickness of boro silicate glass windows? A: Borosilicate glass windows are available in thicknesses ranging from a few millimeters to several centimeters, depending on the application. As a borosilicate glass supplier, we will do our best to meet all the needs of customers. If you are looking for a reliable custom optics manufacturer, please contact us, and we will be your best partner.

Minimum Order: 100

Silicon has a low 2.329 g/cm3 density which is half the density of Germanium, making it ideal for weight-sensitive applications, such as silicon windows. Silicon's price is much better compared with Germanium. Many military brand companies choose TC Optics Silicon lenses or windows. Silicon Window Specifications Silicon (Si) windows are widely used in a variety of scientific and industrial applications due to their excellent optical properties, particularly in the infrared (IR) region. Silicon has a high refractive index and a low absorption coefficient in the mid-IR range, making it an ideal material for use in IR spectroscopy and imaging applications. Silicon windows are also used in high- power laser systems and as protective windows for thermal imaging cameras. Material Silicon/silica Diameter 1 to 500 mm Diameter Tolerance +0/-0.02 mm Thickness Tolerance ±0.01 mm Surface Quality 10-5 Surface Figure λ/10 Parallelism 1 Minute Coating Uncoated, AR, HR, Beamsplitter, etc. Types of optical window glass for your needs: Fused silica window Sapphire optical window ZnSe window Germanium window Silicon window Borosilicate glass for sale Float glass optical windows Properties and Characteristics of Silicon Windows Optical Properties of Si windows Silicon windows have a high refractive index of about 3.4 and a low absorption coefficient in the mid-IR range, making them an ideal material for use in IR spectroscopy and imaging applications. They have a broad transmission range from 1-8 μm and are particularly useful in the 1-5 μm range. Silicon window transmission Silicon windows have high transmittance in the visible and near-infrared regions. Their transmission rate ranges from 50% to 95%, depending on the thickness of the silicon material and the specific wavelength being transmitted. They have high transmittance in the range of 1-7 µm, which is the near-infrared region, and some silicon windows can transmit light up to 14 µm, making them suitable for use in some mid-infrared applications as well. Silicon windows are often used in spectroscopy, microscopy, and other instrumentation applications where high transmission in the visible and near-infrared range is required. They are also highly resistant to temperature changes and mechanical stress, making them suitable for use in harsh environments. Physical Properties of Si Windows Silicon windows are a relatively hard material with a Knoop hardness of about 1150. They have a density of 2.33 g/cm3 and a thermal conductivity of about 149 W/mK, making them highly thermally conductive and resistant to thermal shock. Applications of Silicon Windows Infrared Spectroscopy and Imaging Si windows are commonly used in infrared spectroscopy and imaging applications due to their high transmittance in the mid-IR range. They are often used in Fourier transform infrared (FTIR) spectrometers, where they are used as beamsplitters or as windows for sample chambers. High-Power Laser Systems Si windows are also used in high-power laser systems, where they are used as protective windows or lenses due to their high thermal conductivity and low absorption coefficient in the visible and near-IR range. Thermal Imaging Cameras Si windows are used as protective windows in thermal imaging cameras, where they are used to protect the sensitive infrared detector from dust and other contaminants while allowing infrared radiation to pass through. Handling and Maintenance of Silicon Windows Silicon windows should be handled with care to avoid scratching or other damage to the surface. They can be cleaned using a mild detergent and water solution or with isopropyl alcohol. It is important to use a soft, lint-free cloth or a lens cleaning tissue to avoid scratching the surface. FAQs of silica windows What is the transmission range of Silica windows? A: Silica windows have a broad transmission range from 1-8 μm and are particularly useful in the 1-5 μm range. Can Silica windows be used in high-power laser systems? A: Yes, Silica windows have a low absorption coefficient in the visible and near-IR range, making them an ideal choice for use in high-power laser systems. What is the refractive index of Silicon? A: The refractive index of Silicon is about 3.4. What is the thermal conductivity of Silicon? A: The thermal conductivity of Silicon is about 149 W/mK. What is the typical thickness of Silica windows? A: Silica windows are available in thicknesses ranging from a few millimeters to several centimeters, depending on the application. As one of optical windows manufacturers, we will do our best to meet all the needs of customers.

Minimum Order: 100

At TC Optics germanium window suppliers, you can expect superior performance, reliability and longevity - all at an unbeatable price point. Germanium (Ge) is in the range of 2-12 μm. Germanium is the most commonly used for making optical lenses and optical windows in high-efficiency infrared imaging systems. Due to the wide transmission range and opacity of visible light, Germanium is very suitable for infrared lasers and optical systems for the manufacture of optical components. Germanium's high refractive index and minimal surface curvature make it an ideal material for making low-power imaging systems. Specification of Ge Window Germanium (Ge) windows are widely used in a variety of scientific and industrial applications due to their excellent optical properties, particularly in the infrared (IR) region. Germanium has a high refractive index and a low absorption coefficient in the mid-IR range, making it an ideal material for use in IR spectroscopy and imaging applications. Germanium windows are also used in high-power laser systems and as protective windows for thermal imaging cameras. Material Germanium Diameter 1 to 500 mm Diameter Tolerance +0/-0.02 mm Thickness Tolerance ±0.01 mm Surface Quality 10月5日 Surface Figure λ/10 Parallelism 1 Minute Coating Uncoated, AR, HR, Beamsplitter, etc. Germanium IR window is a type of infrared window made from Germanium material. It is transparent to long-wave infrared radiation and has a high refractive index, making it ideal for use in infrared optics. Germanium IR window can transmit light in the wavelength range of 2-16 µm, which is in the far-infrared to mid-infrared region. This transparency property makes it ideal for use in infrared imaging systems, as well as in spectroscopy and remote sensing devices. Germanium IR window can be used in harsh environments, as it is highly resistant to thermal or mechanical shock due to its high thermal conductivity. Overall, Germanium IR window is a versatile material with excellent optical, thermal and mechanical properties, making it an ideal choice for a wide range of infrared applications. Types of optical window glass for your needs: Fused silica window Sapphire optical window ZnSe window bk7 fused silica Silicon window Borosilicate glass for sale Float glass optical windows Whether you're involved in research, development, or industrial applications, our custom optical window is the answer to your laser processing needs. Properties and Characteristics of Germanium Windows Optical Properties (germanium window transmission) Germanium windows have a high refractive index of about 4.0 and a low absorption coefficient in the mid-IR range, making them an ideal material for use in IR spectroscopy and imaging applications. They have a broad transmission range from 2-16 μm and are particularly useful in the 2-12 μm range. Germanium windows have high transmittance in the infrared region, particularly in the 2-16 µm wavelength range. Their transmission rate reaches up to 70% at 2 µm, 50% at 4 µm, 27% at 8 µm and 14% at 12 µm. Germanium windows are commonly used in thermal imaging applications, as well as in infrared spectroscopy and remote sensing systems. They are well-suited for use in applications that require high thermal resistance and high refractive index in the infrared region. Physical Properties Germanium windows are a relatively soft material with a Knoop hardness of about 780. They have a density of 5.33 g/cm3 and a thermal conductivity of about 59 W/mK, making them thermally conductive and resistant to thermal shock. Applications of Germanium Windows Infrared Spectroscopy and Imaging Germanium windows are commonly used in infrared spectroscopy and imaging applications due to their high transmittance in the mid-IR range. They are often used in Fourier transform infrared (FTIR) spectrometers, where they are used as beamsplitters or as windows for sample chambers. High-Power Laser Systems Germanium windows are also used in high-power laser systems, where they are used as protective windows or lenses due to their high thermal conductivity and low absorption coefficient in the visible and near-IR range. Thermal Imaging Cameras Germanium windows are used as protective windows in thermal imaging cameras, where they are used to protect the sensitive infrared detector from dust and other contaminants while allowing infrared radiation to pass through. Handling and Maintenance of Germanium Windows Germanium windows should be handled with care to avoid scratching or other damage to the surface. They can be cleaned using a mild detergent and water solution or with isopropyl alcohol. It is important to use a soft, lint-free cloth or a lens cleaning tissue to avoid scratching the surface. FAQs of GE windows What is the transmission range of Germanium windows? A: Germanium windows have a broad transmission range from 2-16 μm and are particularly useful in the 2-12 μm range. Can Germanium windows be used in high-power laser systems? A: Yes, Germanium windows have a low absorption coefficient in the visible and near-IR range, making them an ideal choice for use in high-power laser systems. What is the refractive index of Germanium? A: The refractive index of Germanium is about 4.0. What is the thermal conductivity of Germanium? A: The thermal conductivity of Germanium is about 59 W/mK. What is the typical thickness of Germanium windows? A: Germanium windows are available in thicknesses ranging from a few millimeters to several centimeters, depending on the application. As an optics manufacturing company, we will do our best to meet all the needs of customers.

Minimum Order: 100

Our ZnSe Window is made with high-quality Zinc Selenide material, making it ideal for use in laser systems. The window ensures high transmittance in the infrared region, allowing for precise and accurate laser processing. Znse focus lens, znse laser lens is well-suited for optical elements in high-resolution thermal imaging equipment. ZnSe also transmits some visible light, unlike Germanium and silicon, thereby allowing for visual optical alignment. However, zinc selenide window is quite soft and will scratch easily. ZnSe window has an index of refraction of 2.403 at 10.6 µm. ZnSe Window Specification Zinc selenide (ZnSe) windows are a popular choice for a wide range of applications due to their excellent optical properties, including high transmittance in the mid-infrared (IR) region and low absorption in the visible and near-IR regions. They are commonly used in scientific, medical, and industrial applications where optical clarity and high transmission are critical. Material CVD ZnSe Diameter 1 to 500 mm Diameter Tolerance +0/-0.02 mm Thickness Tolerance ±0.01 mm Surface Quality 10-5 Surface Figure λ/10 Parallelism 1 Minute Coating Uncoated, AR, HR, Beamsplitter, etc. Our product is designed to withstand extreme heat, radiation and chemicals, ensuring durability and long-lasting performance. It comes in a range of sizes to cater for varying laser system configurations. Types of optical window glass for your needs: Fused silica window Sapphire optical window BK7 window Germanium window Silicon window Borosilicate glass for sale Float glass optical windows With TC Optik's optical Window, you can expect superior performance, reliability and longevity - all at an unbeatable price point. Whether you're involved in research, development or industrial applications, our custom optical window is the answer to your laser processing needs. Get in touch with us today to learn more about our ZnSe Window and how it can benefit your laser system applications. Properties and Characteristics of ZnSe Selenide Windows Zinc Selenide windows are the best choice for a variety of IR applications and high-power CO2 laser systems. ZnSe has low IR absorption and high resistance to thermal application area. Zinc Selenide windows are best for thermal imaging. Zinc selenide windows are used in infrared imaging applications in scientific, military or search and rescue applications. ZnSe has a high index of refraction which requires an anti-reflection coating to achieve high transmission.ZnSe has good transmission from 3um-12um.Long wavelength transparency is crucial for imaging room temperature objects, which radiate at a peak wavelengths of approximately 10 µm with very low intensity. Optical Properties ZnSe windows have a high transmittance of over 90% in the mid-infrared (IR) region, making them an ideal material for use in IR spectroscopy and imaging applications. They also have low absorption in the visible and near-IR regions, making them an ideal choice for high-power laser applications. Physical Properties ZnSe windows have a low thermal expansion coefficient and a high thermal conductivity, which makes them an ideal choice for applications that require high thermal stability. They also have a low density and high hardness, which makes them resistant to scratching and other forms of damage. Applications of ZnSe Windows Infrared Spectroscopy ZnSe windows are commonly used in infrared spectroscopy, where their high transmittance in the mid-IR region allows for accurate measurements of molecular vibrations and other spectral features. Medical Imaging ZnSe windows are also used in medical imaging applications, such as in endoscopes and other medical devices, where their high transmittance in the mid-IR region allows for detailed imaging of internal tissues and organs. Laser Systems ZnSe windows are used in high-power laser systems, such as CO2 lasers, where their low absorption in the visible and near-IR regions allows for efficient transmission of laser energy. Industrial Applications ZnSe windows find use in a variety of industrial applications, including gas analysis, semiconductor processing, and environmental monitoring, where their high transmittance and thermal stability make them an ideal choice. Cleaning, Handling and Maintenance of ZnSe Windows Proper handling and maintenance are important for maintaining the optical quality of ZnSe windows and ensuring their long-term reliability. It is important to avoid touching the surface of the window with bare hands or other objects, as this can leave oils or other contaminants on the surface that can degrade the optical quality. ZnSe windows should be cleaned using a mild detergent and water solution or with isopropyl alcohol, and it is important to use a soft, lint-free cloth or a lens cleaning tissue to avoid scratching the surface. ZnSe is very soft material, so we should very careful about it. It requests professional people to make it clean. It is also a toxic material. Great care must be taken in handling and cleaning the material. Wear gloves at all times to avoid the risk of contamination. Hold only the edge to prevent scratches. Wash hands after use. when holding the optics by its edges. wipe the surface gently with a damp cotton ball. Do not rub, and do not exert pressure. use only surgical quality cotton balls. ZnSe focus lens VS ZnSe laser lens ZnSe focus lens and ZnSe laser lens are both made of the same material, Zinc Selenide, which is commonly used in laser optics due to its high transmittance in the infrared region. ZnSe focus lens is designed to focus the laser beam to a precise spot on the material being processed. It is used in laser cutting, engraving and marking machines where accuracy and precision are critical. The focus lens is adjustable, allowing the operator to adjust the focal length to match the thickness of the material being processed. ZnSe laser lens, on the other hand, is a protective cover that is placed over the laser cavity to protect it from dust and debris. It is also used to block stray light from entering the cavity and interfering with the laser beam. In summary, ZnSe focus lens is used to concentrate the laser beam to a pinpoint accuracy, whereas ZnSe laser lens acts as protection. FAQs of ZnSe Selenide Windows What is the refractive index of ZnSe? A: The refractive index of ZnSe is about 2.4. What is the thermal conductivity of ZnSe? A: The thermal conductivity of ZnSe is about 18 W/mK. What is the typical thickness of ZnSe selenide windows? A: ZnSe selenide windows are available in thicknesses ranging from a few millimeters to several centimeters. Can ZnSe windows be used in high-power laser applications? A: Yes, ZnSe selenide windows have low absorption in the visible and near-IR regions, which makes them an ideal choice for high-power laser applications. As one of znse window manufacturers,we will do our best to meet all the needs of customers. More kinds of optical components china, please visit our website.

Minimum Order: 100

Tcoptics, one of professional big size sapphire windows manufacturers, provides all types of custom sapphire windows, which have a series of excellent physical and chemical characteristics such as high strength, high hardness, high- temperature resistance, abrasion resistance, corrosion resistance, good light transmission performance and excellent electrical insulation performance. Therefore, the sapphire window can be widely used in various demanding fields such as national defense, scientific research, and civil industry. Sapphire Window Properties Material Sapphire Diameter 1 to 500 mm Diameter Tolerance +0/-0.02 mm Thickness Tolerance ±0.01 mm Surface Quality 10-5 Surface Figure λ/10 Parallelism 1 Minute Coating Uncoated, AR, HR, Beamsplitter, etc. Sapphire windows are known as being high performers in any industry for their overall versatility and ability to withstand abrasive applications that would otherwise break glass made of silica. Sapphire optical window is hard, strong, and wears resistant. Because of sapphire hard properties, so it can be used in Aerospace windows, downhole and drilling vision systems, inspection windows, watch crystals, and gun sights. Sapphire window transparency is very good also. So it is ideal for deep sea and underwater sensors. Our team of experienced engineers and technicians use advanced manufacturing techniques and equipment to ensure that our optical windows are of the highest quality, with exceptional clarity, low levels of birefringence, and minimal wavefront distortion. This makes them ideal for use in many optical applications, including imaging, spectroscopy, and laser optics. Types of sapphire glass window for your needs: Fused quartz windows BK7 optical windows ZnSe focus lens Germanium IR window Silicon window Borosilicate glass for sale Float glass optical windows Sapphire Optical Window Feature Ideal for high temperature, high pressure, or strong vacuum environments. Highly corrosion resistant. Transparent from 170 nm to 5.5 µm. Extremely hard and more durable than standard optical glass. Sapphire Window Cleaning Cleaning a sapphire custom optical window is similar to cleaning any other type of window, but you need to be careful to avoid scratching the surface. Here are some steps you can follow to clean a sapphire window: Prepare the cleaning solution: Mix warm water with a small amount of mild soap or detergent in a container. Wet a soft cloth with the cleaning solution: Make sure the cloth is clean and free of any debris that could scratch the surface. Gently wipe the sapphire window: Use the wet cloth to wipe the surface of the window, being careful not to apply too much pressure. Rinse the window: Use a separate clean cloth or sponge to rinse the window with clean water. Dry the window: Use a clean, soft cloth to dry the sapphire window. Avoid using paper towels or any other abrasive materials that could scratch the surface. If the window has stubborn stains or grime, you can use a specialized sapphire cleaning solution, which can be purchased from jewelry stores or online retailers. Be sure to follow the manufacturer's instructions carefully when using these products. Sapphire window transmission Sapphire windows have excellent optical properties, including high transmission in the visible to near-infrared (NIR) wavelength range. The exact transmission characteristics of a sapphire window depend on factors such as its thickness and surface quality, as well as the wavelength of the light passing through it. In general, sapphire windows have high transmission in the visible spectrum, with transmission rates of up to 90% or more depending on the thickness of the window. In the NIR range, sapphire windows also have high transmission rates, typically over 80% for wavelengths up to 2 microns. However, as the wavelength increases beyond 2 microns, sapphire windows become increasingly opaque due to absorption. At wavelengths around 3 microns, sapphire windows have a transmission rate of around 50%, and at 4 microns, the transmission rate drops to around 10%. Therefore, if you need to transmit light at longer wavelengths, you may need to consider other materials such as germanium or zinc selenide, which have higher transmission rates in the mid- and far-infrared regions. Sapphire Glass Window Uses Sapphire windows can be used in vision systems, inspection windows, watch crystals, and gun sights. Underwater security equipment. Sapphire windows can be widely used in gas and oil analysis, barcode readers, and IR analysis devices. Its application in industry, military, defense, space, medical and research sectors. Sapphire optical windows can be made a great deal thinner than other optical windows, which results in improved transmission. Sapphire optical windows are useful through a wide wavelength range of 0.15 to 5.5µm and are resistant to UV radiation darkening.

Minimum Order: 100

This non-crystalline, uv fused silica glass combines a very low thermal expansion coefficient with good optical qualities and excellent transmittance in the ultraviolet region. Transmission and homogeneity exceed those of crystalline quartz without the problems of orientation and temperature instability inherent in the crystalline form. It will not fluoresce under UV light and is resistant to radiation. Our fused quartz windows are made from high-purity quartz, which offers superior optical transmission properties, as well as exceptional thermal and mechanical performance. Specification of Quartz Window Material Fused Silica Diameter 1 to 500 mm Diameter Tolerance +0/-0.02 mm Thickness Tolerance ±0.01 mm Surface Quality 10-5 Surface Figure λ/10 Parallelism 1 Minute Coating Uncoated, AR, HR, Beamsplitter, etc. Our quartz glass windows are available in a variety of shapes and sizes, including standard sizes and custom designs to suit your specific needs. We also offer various coatings and treatments to enhance the performance of our quartz windows, including anti-reflection coatings, hydrophobic coatings, and more. At TC Optik, we are committed to providing exceptional customer service and support, with fast turnaround times and competitive pricing to meet your needs. Contact us today to learn more about our optical window glass and how they can help you achieve your optical and industrial needs. Types of optical window glass for your needs: BK7 optical windows Custom sapphire windows ZnSe laser lens Germanium window Silicon window Borosilicate glass windows Float glass optical windows What's the difference between quartz windows and fused silica glass Quartz windows and fused quartz glass are both materials that are commonly used for optical windows and other high-performance applications. While they may appear similar, there are some key differences between these materials. 1. Composition: Quartz windows are made from natural quartz crystals that are mined from the earth, while fused silica glass is produced by melting high-purity silica using high-temperature techniques. 2. Purity: Fused silica glass is typically purer than quartz, with a purity level of over 99.9%. 3. Transmission: Both materials have excellent optical transmission properties, but quartz typically has a lower transmission range in the ultraviolet spectral region than fused silica glass. 4. Refractive Index: Quartz has a slightly higher refractive index than fused silica glass. 5. Thermal Expansion: Quartz has a higher coefficient of thermal expansion compared to fused silica glass, making it more prone to thermal shock. 6. Cost: Quartz is typically less expensive than fused silica glass. Quartz windows are commonly used in applications that require a lower level of purity and precision, while fused silica glass is often used in applications that require higher levels of purity, precision, and performance, like in high- end optical components, cutting-edge semiconductor OEM applications, and high- intensity discharge lamps. Ultimately, the choice of material depends on the specific application and the performance requirements of the project. Fused silica glass properties Fused silica glass is a high-purity form of silica that is produced by melting high-purity silica at very high temperatures and then rapidly cooling it to form a glass. Some key properties of fused silica glass include: 1. High purity: Fused silica glass is one of the purest forms of silica, with a purity level of over 99.9%. 2. High temperature resistance: Fused silica glass can withstand temperatures up to 1200°C without softening or undergoing deformation. 3. Low coefficient of thermal expansion: Fused silica glass has a very low coefficient of thermal expansion, making it highly resistant to thermal stress. 4. High transmission: Fused silica glass has a very high transmission range, allowing for excellent optical performance across a broad range of wavelengths. 5. Hardness: Fused silica glass is very hard and resistant to scratching, making it ideal for use in harsh environments. 6. Low thermal conductivity: Fused silica glass has a low thermal conductivity, which makes it an excellent insulator. 7. Chemical inertness: Fused silica glass is highly inert and resistant to chemical attack, making it ideal for use in chemical and high-ph applications. These properties make fused silica glass an excellent material for use in optical applications, such as lenses, prisms, mirrors, and windows, as well as in high-temperature applications, semiconductor-quality quartzware and other high-performance applications. Fused silica glass uses Fused silica glass has a wide range of uses in various industries and applications, including: 1. Optical components: Fused silica glass is used to make high-end optical components such as lenses, prisms, mirrors, and windows. It has excellent transmission properties in the ultraviolet, visible, and infrared regions of the spectrum, which makes it ideal for use in a broad range of optical applications. 2. Semiconductor processing: Fused silica glass is commonly used in the semiconductor industry to manufacture wafer carriers, supply tubes, and other components that require high-purity and resistance to high temperatures and chemicals. 3. Aerospace: Fused silica glass is used to make windows and lenses for aerospace applications, as it can withstand high temperatures, high radiation levels, and environmental stresses. 4. High-temperature applications: Fused silica glass is used in high- temperature applications like furnace observation windows, reflectors, and insulators due to its high thermal stability and resistance to thermal shock. 5. Metrology: Fused silica glass is used in precision metrology and measurement systems, such as interferometers and optical profilometers. 6. Military: Fused silica glass is used as a structural material in military applications due to its high mechanical strength and durability. 7. Medical: Fused silica glass is used in medical applications, such as microfluidic devices and lab-on-a-chip systems, for its chemical inertness and biocompatibility with biological fluids. The unique properties of fused silica glass make it an ideal material for a broad range of high-performance applications across many industries. IR vs. UV Grade Fused Silica UV and IR grade fused silica are two different types of fused silica glass that are optimized for use in different wavelength ranges of light. UV grade fused silica has high transmission properties in the ultraviolet range of the spectrum, typically between 180 to 400 nanometers (nm). UV grade fused silica has a low level of impurities, which makes it ideal for use in applications such as UV spectroscopy, imaging, and laser optics. IR grade fused silica, on the other hand, has high transmission properties in the infrared range of the spectrum, typically between 1.5 to 6 microns. IR grade fused silica is optimized to have low absorption in the infrared region, which makes it ideal for use in applications like Fourier transform infrared (FTIR) spectroscopy, IR imaging, and high-temperature IR optics. While both UV and IR grade fused silica have excellent thermal properties, high mechanical strength, and low thermal expansion coefficients, their optical properties are optimized for different ranges of the spectrum. Therefore, it is important to choose the appropriate grade of fused silica based on the specific application and wavelength range requirements. If you want to buy fused silica lens, please leave us a message.

Minimum Order: 100