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Breakthrough in optical component technology with broad market prospects In the era of rapid technological development, optical components, as key components, are experiencing unprecedented technological breakthroughs. These breakthroughs not only demonstrate the enormous potential of optical components, but also bring new possibilities for applications in multiple industry fields. 1. Breakthrough in optical component technology Recently, significant technological progress has been made in the field of optical components. Researchers have successfully developed optical components with higher performance and stability through in-depth research on new materials and advanced manufacturing technologies. These new components have made breakthroughs in transparency, resolution, durability, and other aspects, laying a solid foundation for improving the performance of optical instruments and equipment. 2. Performance analysis of new components The performance of new optical components is remarkable. They have higher transparency and can effectively reduce the loss of light during transmission; At the same time, the resolution of these components has also been significantly improved, allowing optical instruments to capture more details and improve imaging quality. In addition, the new components have excellent stability, heat resistance, and corrosion resistance, and can adapt to more harsh working environments. 3. Outlook on application fields With the breakthrough of optical component technology, its application prospects in multiple fields have become more extensive. In the medical field, new optical components are expected to improve the imaging quality of equipment such as endoscopes and microscopes, providing more accurate basis for disease diagnosis and treatment. In the field of aerospace, high-performance optical components can be used in satellite remote sensing, astronomical observation and other fields, promoting the in-depth development of space science. In addition, new optical components have broad application prospects in fields such as communication, security, and consumer electronics. 4. Market Outlook Forecast With the continuous breakthroughs in technology and the expansion of application fields, the market prospects of optical components are very broad. It is predicted that the size of the optical component market will continue to grow in the coming years and is expected to drive the development of related industrial chains. Especially in emerging markets such as Asia, the demand for optical components has enormous growth potential. 5. Industry Impact Assessment The breakthrough in optical component technology will have a profound impact on the entire industry. Firstly, it will promote the performance improvement of optical instruments and equipment, and drive the development of related industries. Secondly, the application of new optical components will expand to more fields, providing more possibilities for the development of various industries. Finally, breakthroughs in optical component technology will drive the development of related industrial chains, promote employment and economic growth.

200W LED Profile Spot Light, High-Quality Optical Lens Model NO.: UM-200P Origin: Guangdong, China HS Code: 9405409000 Model NO.: UM-200P Origin: Guangdong, China HS Code: 9405409000 Model No: UM-200P Voltage:AC100-240V,50/60HZ Comsumption:250W Light source:200W led warm white/cold white lifetime:<50000hours CRI:Ra>90 Lens angel:19/26/36/50degree Color temperature:3200K/5700K(optional) Zoom function:Manual zoom Control mode:DMX512,master-slave,auto Channel:1/3CHs Dimmer:0-100% linear dimmer Optic system:High quality optic system,reflective glass IP rating:IP20 Net weight:7.2kg Packing size:720*320*330mm(1pcs/CTN) 1.Introduction: We are a professional big manufacturer which have 18 years experience and can produce many different kinds of stage lighting and stage effect machine in high quality with low price . OEM order is also welcome and small order is also accepted Welcome you visit our factory for more business negotiation anytime 2.shipping: For small order, We will delivery by DHL , UPS, Fedex, EMS or TNT , also ,we can help to find best forwarder if the big order and need ship by sea .so Please send the available phone number and right address for fast and safe delivery 3.Guarantee and responsibilty: We guarantee that all our products will be tested before shipment., if there any damage caused in transit , we can not control the entire process , if so , we are happy to communicate with the buyer friendly solution. Our products have 1year warrantly time. Import duties, taxes and charges are not included in the product price or shipping charges. These charges are the buyer's responsibility. So Please check with your country custom office to determine what these additional costs will be prior to bidding/buying. however, we will try our best to minimize the extra charge for our customers. In order to avoid any unhappiness, you are suggest to know your local customs and government regulation before purchase

A germanium-antimony compound has characteristics similar to graphene The single-layered structure of graphene with only one carbon atom thickness has spawned a large number of studies on its unique electronic, optical, and mechanical properties. According to a report from the Physicist Organization Network on April 24th, researchers at the Massachusetts Institute of Technology (MIT) discovered that a gallium-tellurium compound has many unusual characteristics similar to graphene, and in some cases can be replaced with graphene as a replacement. material. The researchers found that the helium-neodymium film material has a variety of different controllable properties, depending on the temperature and pressure of the environment, the material will be thickened and oriented growth. The results of the study were published in the latest issue of Nano Express. The new material has a unique two-dimensional planar structure and a Dirac cone-shaped electron energy band structure termed the Dirac cone two-dimensional. This unusual electronic properties like graphene can cause electrons to move in different ways, exceeding the possibilities in most materials, and this will be used to make next-generation electronic chips or thermoelectric generators and coolers. Very desirable property. Researchers say that in these materials, electrons "become comparable to light beams", enabling new chips to have faster computing power. In some cases, electrons flow faster than traditional silicon chips and may reach hundreds of times. Similarly, in a thermoelectric application, the temperature difference between the two sides of the device creates a faster electron motion current, coupled with stronger thermal insulation performance, which promotes more efficient power generation, such as the use of the temperature difference between the two sides of the satellite, yin and yang. It is possible to show the use of power for satellites. Researchers say that no equipment has been manufactured using this new material, and some details have yet to be resolved, but the principles are clear and will be verified within a year. Until the creation of a real device, many mysteries will be revealed. (Hua Ling)

Significant Innovation Achievements in Optical Components, Promoting Sustainable Development of the Industry In today's society, the innovative achievements of optical components not only promote technological progress, but also make important contributions to achieving sustainable development goals. Recently, innovative achievements in the field of optical components have attracted much attention, injecting new vitality into the industry's development. 1. Innovative achievements in optical components The innovation achievements in the field of optical components are fruitful. Researchers have successfully developed multiple high-performance and low-energy optical components by continuously exploring new materials, processes, and technologies. These innovative achievements not only improve the performance of optical components, but also reduce production costs, laying a solid foundation for the sustainable development of the industry. 2. Overview of Manufacturing Process Progress With the continuous progress of manufacturing technology, the manufacturing accuracy and efficiency of optical components have been significantly improved. The application of modern manufacturing technologies such as nanoimprinting and laser processing has made the manufacturing process of optical components more refined and efficient. This not only improves product quality, but also reduces energy consumption and waste generation, helping to achieve green production. 3. Environmental Impact and Sustainable Development The innovative achievements of optical components and the progress of manufacturing processes have had a positive impact on environmental protection and sustainable development. The development and application of new optical components have reduced reliance on traditional materials and reduced resource consumption. At the same time, advanced manufacturing processes reduce waste and pollutant emissions during the production process, effectively reducing the impact on the environment. These measures are in line with the global trend of sustainable development and provide strong support for the green development of the industry. 4. International cooperation and exchange In the field of optical components, international cooperation and exchanges are becoming increasingly frequent. Through cooperation with international advanced enterprises and research institutions, advanced technology and management experience can be introduced to jointly promote innovation and development of optical components. Meanwhile, international cooperation and exchanges also contribute to expanding the international market and enhancing the international competitiveness of China's optical component industry. 5. Outlook on Future Development Trends Looking ahead, the optical component industry will continue to usher in a wave of innovative development. With the continuous emergence of new materials, processes, and technologies, the performance and functionality of optical components will be further improved. Meanwhile, with the recovery of the global economy and the rise of emerging markets, the competitive landscape of the optical component market will also undergo profound changes. In this new era full of opportunities and challenges, optical component enterprises need to strengthen innovation cooperation and communication, continuously improve product performance and application areas, and make greater contributions to the sustainable development of the industry. In short, the innovative achievements of optical components and the progress of manufacturing processes have injected new impetus into the sustainable development of the industry. In the future development, the optical component industry needs to continue to pay attention to environmental protection, strengthen international cooperation and exchange, promote technological innovation and application expansion, and make greater contributions to global scientific and technological progress and social development.

Tin-Silicon Replaces Germanium: Solid Electrolytes Reduce Lithium Battery Costs According to foreign media reports, Tokyo Institute of Technology researchers have developed a new technology program - germanium-free solid electrolyte can reduce the cost of solid-state lithium batteries, and is committed to the technology applied to the electric car , Communications and other industries. Germanium-free solid electrolyte The team published a paper in the Journal of the American Chemical Society (ACS), "Chemistry of Materials," a technology that uses tin and silicon to replace the germanium element in solid electrolytes because Two materials are more chemically stable. The new material increases the lithium ion conductivity compared to the liquid electrolyte. Commenting on his research, Ryoji Kanno and his colleagues said: "This solid electrolyte is germanium-free and may be used in all solid-state batteries in the future." All-solid-state battery systems with solid-state electrolytes (SEs) are expected to compete for a new generation of batteries. It is estimated that such batteries can provide large power, high energy density, stable performance, safety performance also increased. Sulfide-based lithium-ion conductors have high conductivity and electrochemical windows (also known as "electrochemical windows") and good mechanical properties. To this end, many agencies are now vigorously developing solid electrolyte. Li10GeP2S12 (LGPS) is a new member of the crystalline sulfur electrolyte product family with an electrical conductivity of 1.2 × 10 -2 S cm -1, comparable to organic liquid electrolytes. All-solid battery LiCoO2 / LGPS / In? Li using LGPS electrolyte, its charge and discharge performance is quite good. However, germanium is relatively expensive or will limit the widespread use of LGPS materials. The type of crystal structure is also an important factor in designing a lithium ion conductor. If the structure of different types of materials are similar, and the conductivity of solid high, then the new material will be better conductive properties. The lithium ion diffusion rate of the LGPS type structure is high. In the future, both germanium-based and germanium-free germanium-based materials may be used as solid electrolytes and are in practical use. The new material's atomic arrangement is named LSSPS. The new germanium-free material uses the result Li10.35 [Sn0.27Si1.08] P1.65S12 (Li3.45 [Sn0.09Si0.36] P0.55S4.

University of Arkansas develops silicon-germanium-tin solar cells The research team at the University of Arkansas received a $750,000 grant from NASA for the development of silicon germanium-tin (SiGeSn) solar cells for space missions. University of Arkansas associate professor of electronic engineering Yu Shuiqing will be the main scientific research personnel for multi-agency projects. The research team will develop silicon-germanium-tin photovoltaic devices that have been shown to improve the efficiency of capturing, detecting, and controlling light. To complete the project, the United States NASA/EPSCoR allocated $750,000 to the Space Support Alliance Office at the University of Arkansas. The Incentive Competition Research Pilot Program (EPSCoR) is a funding program to increase the participation of state governments in competitive aerospace research activities. Professor Yu said, [Now we have the opportunity to develop a space application of high-performance solar cells." Prof. Yu will work with Hameed Naseem, professor of electrical engineering at the University of Arkansas, and professor of physics, Mansour Mortazavi, and Allan Thoma to complete the project. Prior to this, Professor Yu, Naseem and Mortazavi received US$725,000 funding from the US Air Force Scientific Research Office for similar solar cell technology development. Researchers used ultra-high vacuum chemical vapor deposition to grow silicon-germanium tin on silicon substrates. For NASA's projects in the United States, researchers will use silicon-germanium-tin to develop photovoltaic devices that can be integrated into existing solar cells to achieve a more efficient electric energy source. Existing 3-junction solar cells used by NASA in the United States are estimated to have reached their efficiency limit. The new material is expected to help NASA in the United States achieve its goal of 15 years of working life and 45% conversion efficiency of solar cells. New materials should also reduce production costs and make photovoltaic devices more resistant to radiation. The research plan includes device design and simulation, material growth and characterization, optical properties of silicon germanium and tin materials, and the development of silicon germanium tin photoconductors. In connection with this study, Prof. Yu also obtained a grant of US$ 96,455 from the U.S. Army Research Office to update the characteristic measuring instruments for silicon germanium-tin-based devices.

Innovative materials and technological progress drive the flourishing development of the optical component market In today's rapidly changing technology, optical components, as core components in many fields, are increasingly showing their importance. The continuous emergence of innovative materials and technological progress is driving the optical component market into a new era of vigorous development. 1. Innovative materials lead development With the deepening of research on new materials, the manufacturing materials of optical components are also constantly innovating. The emergence of new optical glass, crystals, thin films and other materials provides strong support for the performance improvement and functional innovation of optical components. These new materials not only have excellent physical and chemical properties, but also can to some extent reduce production costs and improve production efficiency. 2. Technological progress drives the market In terms of manufacturing technology, with the continuous progress of nanotechnology, laser processing, precision grinding and other technologies, the manufacturing accuracy and performance of optical components are also constantly improving. The application of these advanced technologies has made significant breakthroughs in the resolution, transparency, stability, and other aspects of optical components, further expanding their application scope in various fields. 3. International cooperation and exchange In the context of globalization, international cooperation and exchanges in the optical component industry are becoming increasingly frequent. Through cooperation with international advanced enterprises and research institutions, not only can advanced technology and management experience be introduced, but new products, technologies, and markets can also be jointly developed. This kind of cooperation and exchange is of great significance for promoting innovation and development in the optical component industry. 4. Environmental Protection and Sustainable Development While pursuing economic benefits, the optical component industry has also begun to pay attention to environmental protection and sustainable development. By adopting environmentally friendly materials, optimizing production processes, and reducing energy consumption, optical component companies are striving to achieve green production and sustainable development. This not only helps to enhance the social image and competitiveness of enterprises, but also conforms to the trend of global sustainable development. 5. Future outlook Looking ahead to the future, with the continuous emergence of new materials and technologies and the continuous growth of market demand, the optical component industry will usher in a broader development space. Meanwhile, with the recovery of the global economy and the rise of emerging markets, the competitive landscape of the optical component market will also undergo profound changes. In this new era full of opportunities and challenges, optical component enterprises need to constantly innovate and actively respond to market changes in order to stand invincible in competition. In short, innovative materials and technological progress are key factors driving the flourishing development of the optical component market. In the future development, the optical component industry needs to continue to strengthen innovation cooperation and communication, continuously improve product performance and application areas, and make greater contributions to global technological progress and social development.

New Breakthroughs in Optical Components Leading Industry Transformation In today's rapidly developing technology, optical components, as one of the core components, have a profound impact on the entire industry due to their technological progress and application innovation. Recently, a series of new breakthroughs have been made in the field of optical components, bringing revolutionary changes to the entire industry. 1. New breakthroughs in optical components With the continuous emergence of new materials and technologies, the performance and function of optical components are also constantly improving. For example, the recently developed high-performance optical thin films have excellent transparency, anti reflection, and high temperature resistance, greatly improving the stability and reliability of optical components. 2. Expansion of application fields The application of optical components in medical, communication, aerospace and other fields is constantly expanding. Especially in the medical field, the application of high-precision optical components, such as endoscopes, microscopes, etc., makes medical diagnosis and treatment more accurate and efficient. 3. Market demand analysis With the development of the global economy and changes in population structure, the market demand for optical components is showing a continuous growth trend. Especially in emerging markets such as China and India, the demand for optical components has grown significantly. 4. Industry chain integration Faced with intensified market competition, upstream and downstream enterprises in the optical component industry chain have begun to strengthen cooperation, integrate resources, and improve the overall competitiveness of the industry. Through the integration of the industrial chain, not only can production costs be reduced, but product quality and production efficiency can also be improved. 5. Challenges and Opportunities Although the optical components industry is facing fierce market competition and technological challenges, it also nurtures huge development opportunities. With the continuous emergence of new materials and technologies, the performance and function of optical components will continue to improve, and the application fields will also be further expanded. In short, the optical component industry is facing new development opportunities, but also many challenges. Only by constantly innovating and actively responding to market changes can we stand invincible in fierce competition.

Packaging lens contact device Patent Name Packaging Device for Contact Lenses Patent Applicants SC Johnson & ZC Vision Protection Company Principal Applicant Address Florida Inventor L AWESS; G S Duncan; R S Sangka; G S·Hal; M·F Wiedemann; M·E Schrager (Patent) No. 03820813.X Date of Application 2003.07.01 Certification Date Approval Notice No. 1678492 Date of Publication Approval 2005.10.05 Documentation CD D0540 Main classification number B65B7/16 classification number B65B7/16; B65B41/18 division Original application number priority item 2002.7.2 US 60/393,187; 2002.7.8 US 60/394,398 Abstract The present invention relates to a package for contact lenses Device. The device includes a plurality of lens holders (14), a plurality of lifters (18), a plurality of contact lens containers (24) and either a plurality of platens (16) or a plurality of cores. One of the containers (24) is mounted on a corresponding one of the supports (14). Each platen or each core is individually supported by a lifter. The lifter applies pressure to each container within a predetermined range. The heated core (32) is disposed above the plurality of containers (24). The heated core may be moved between a retracted position above the plurality of containers and an engaged position immediately adjacent the plurality of containers. The lidstock (26) is selectively moveable between a retracted position and an inserted position. The insertion position is between the heated core (32) and the plurality of containers (24) such that in the inserted position the cover material is fixedly held in place until the cover material is engaged when the core is moved to the engaged position. The device includes a cover material having indicia printed thereon. The cover material is fed from the web under tension. The image registration inspection system checks the printing quality on the cover material and at the same time checks whether the cover material is aligned within the device. Slaves 1. A device for packaging a contact lens in a plurality of contact lens containers, each container having a recess, a sealing flange surrounding said recess and a contact lens within said recess, a plurality of said containers Sealed onto the continuous lidstock in the device to form a set of packages, the device comprising: a plurality of lifters; a plurality of platens located in the lower portion of the device, each of the platens included in A compliant, compliant head in one direction, each said platen adjacent to each other, each said platen being individually supported by one of said lifters; a plurality of discrete bearings, said branches The seat may be moved within said device to said plurality of said platens such that each said seat is mounted on a respective one of said platens, a single said container being mounted on a single said support In order to provide a plurality of containers adjacent to each other; a cover material handling system for placing successive cover materials on the plurality of containers adjacent to each other; and disposed on the plurality of platens On the core; characterized by passing the core and the plurality of platens Pressure is applied to the continuous lidstock and the flange of the container to adhere the continuous lidstock to the plurality of containers to form a set of packages. International Application PCT/US2003/020724 2003.7.1 International Publication WO2004/026691 English 2004.4.1 Date of Entry into the Country Patent Agency China Patent Agency (Hong Kong) Co., Ltd. Agency Address Agent Liao Lingling

Camera lens selection method If the camera is compared to the human eye, the lens is like an eyeball, which is directly related to the distance, range and effect of the monitoring object. The selection of lens should consider the following points: 1) The lens size should be equal to or larger than the camera imaging surface size. For example: 1/3 "camera can choose 1/3" ~ 1 "lens in the whole range, but the size of horizontal angle of view is the same. Only using lens larger than 1/3" can make more use of shaping and more accurate The center optical path of the lens is improved, so the image quality and resolution can be improved. 2) Select the appropriate lens focal length. The larger the focal length, the farther the monitoring distance, the smaller the horizontal viewing angle, and the narrower the monitoring range; the smaller the focal length, the closer the monitoring distance, the larger the horizontal viewing angle, the wider the monitoring range. The focal length of the lens can be estimated according to the following formula. f = A × L / H (f--lens focal length; A--camera CCD vertical size; L--distance from subject to lens; H--height of subject) Format 1 inch 2/3 inch 1/2 inch 1/3 inch 1/4 inch CCD vertical size 9.6? 6.6? 4.8? 3.6? 2.7? 3) Considering the changes of ambient light, light plays a very important role in the image collection effect. Generally speaking, for the environment where the light change is not obvious, we often choose a manual iris lens. After adjusting the iris hand to a more ideal value, it will not move. Automatic iris, can automatically adjust the size of the aperture value according to the change of light and dark to ensure the image quality. However, it should be noted that if the light illumination is not uniform, especially when the contrast between the monitoring target and the background light is large, the effect of using the automatic iris lens is not ideal. 4) Consider the best monitoring scope. Because the focal length of the lens is inversely proportional to the horizontal angle of view, it is impossible to achieve both wide and clear vision at the same time. Each focal length lens can only achieve the best monitoring effect within a certain range, so if the monitoring distance is far and the range is large, it is best to increase the number of cameras, or use an electric zoom lens with the gimbal installation . 5) The lens interface should be consistent with the camera interface. Current cameras and lenses are usually CS-type interfaces. CS-type cameras can be mated with CS-type and C-type lenses. However, when mating with C-type lenses, a matching ring must be added between the lens and the camera. The protective glass of the CCD imaging surface is damaged, causing damage to the CCD camera. C-type cameras cannot be matched with CS-type lenses.

Filters contribute to environmental pollution control It is understood that the drum vacuum filter invented at the beginning of the 20th century has achieved continuous filtration operations. Since then, various types of continuous filters have emerged one after another. Intermittently operating filters have been developed because of their ability to be automated, and filter areas have become larger. In order to obtain a filter cake with a low moisture content, a mechanical press filter was developed. In recent years, with the serious environmental and water pollution, the filter has become the best choice for each industry and can change the health of the general public drinking water. In order to better cater to the current consumer trends in the market, many companies have joined forces to jointly develop different types of filter products. According to statistics, several companies have already applied this filtration technology to agricultural irrigation and quickly expanded into the industrial sector. These filters are competing for the market share of disposable filter cartridges. According to experts, the success or failure of the filtration operation is related to the filter and the media, but sometimes it also depends on the pretreatment process of filtration, such as coagulation, flocculation, temperature increase, and concentration. Therefore, consider the choice of filter, media, and process conditions.

New germanium transistor is four times faster than current transistor According to foreign media reports, scientists at MIT have developed a new type of transistor. The new transistor passes current through holes in the material's atomic structure, which is about four times faster than current transistors. In order to increase speed, scientists placed germanium on different silicon layers and silicon composite products. Later, germanium atoms were combined with silicon layers. Tensioning materials forced the uppermost material structure to be more compact than their original structures. It sounds a bit like we used rattan to change the shape of plants. The compact structure results in a tighter hole between the germanium materials, and the transistor speed is twice that of most current experimental designs, and the transistor speed on the market is 4 times.

The Most Hard Material Windows Sapphire Windows Single crystal sapphire possesses a unique combination of excellent optical, physical and chemical properties. The hardest of the oxide crystals, sapphire retains its high strength at high temperatures, has good thermal properties and excellent transparency. It is chemically resistant to common acids and alkali at temperatures up to 1000 °C as well as to HF below 300 °C . These properties encourage its wide use in hostile environments where optical transmission in the range from the vacuum ultraviolet to the near infrared is required. Sapphire is anisotropic hexagonal crystal. Its properties depend on crystallographic direction (relative to the optical C-axis). Sapphire Material Advantage: Transmission in 0.3-5.0μm, no absorption in 2-3μm Extremely hard and durable High thermal conductivity High bulk damage threshold Changchun Ruiqi could make Sapphire Window,sapphire Holes, Ruby holes, sapphire tube, sapphire prism sapphire concave lens sapphire dome,Sapphire ball, square sapphire window,Sapphire cone windows,Triangular sapphire prism etc More details please visit our website:www-ruiqi-optics.com

630nm 650nm 658nm 660nm 680nm Three Layers Coated collimator lens Laser Diode Collimators--Glass M9*0.5mm threaded housing, 3glass lens or single glass lens design ARC for blue,green,red available Focal Length:4-11mm Application Industrial and automotive alignment laser for small dimension Laser collimated for hand-held positioning and sensing Small dimension/short focal length requirement for optical design Application in high temperature or adverse circumstance

Meniscus Germanium infrared lens ,Germanium(Ge) windows for Thermal Imaging Germanium is a versatile infrared material commonly used in imaging systems and instruments in the 2 to 12 microns spectral region. It is used as a substrate for lenses, windows, and output couplers for low-power CW as well as pulsed TEA, CO2 lasers. The lowest absorbing Ge optics are limited to a throughput power range of 50 to 100 watts before thermal lensing or thermal runaway. These problems are minimized by properly heatsinking the optic and carefully cleaning contaminated optical surfaces. Ge is non-hygroscopic and non-toxic, has good thermal conductivity, excellent surface hardness, and good strength. II-VI carefully monitors the 10.6µm Ge absorptivity for use in laser applications to assure that thermal runaway and fracture do not occur. One ideal laser application for Ge is a > 99% reflecting back mirror for a CO2 laser with built-in power meters. A high-reflecting, low-absorption dielectric coating is on one side and an AR coating on the other. The laser operates on the feedback from the high-reflecting side, but enough power leaks through for monitoring by a power meter. II-VI supplies these optics for a number of commercial laser applications. Protective Germanium Lens Windows , Ge Laser Lens Window for Camera 0.5mm - 1.5mm ,3-5mm Thickness: Delivery Time:15 working days after received your payment Certification:ROHS / SGS Optical Germanium Lenses Ge Windows 20.0mm,25.4mm , 8μm - 12μm Wavelength Rang, More details please visit our website:www.ruiqi-optics.com

Changchun Ruiqi owns a strong production capability in our modern workshops. We are mainly specialized in the production of lens, prisms, mirrors, cylindrical lens, beam splitters, filters and windows and blanks and infrared Material included Znse, Germanium, ZnS, BaF2 and CaF2 etc More details please visit our website:www-ruiqi-optics.com Recently one of our customers customized one type reflective mirros, diamter 114mm concave mirror with aluminium coating and passed their testing, this year they will order more. For shape we could accept customized, round, square,Plano Convex, Aspheric, Meniscus, special-shaped etc, AR coating could be including 3-12um, 6-8um, 7-12um, 8-14um Commonly coating is AR/AR at 7-12um or AR/DLC at 7-12um

Spherical Ball Lenses are commonly used for laser collimating and focusing, laser-to-fiber coupling, fiber-to-fiber coupling, and fiber-to-detector coupling. Larger spheres are easier to handle and ease the sensitivity of translational alignment. However, smaller spheres has the benefit of fitting into smaller packages. Ball lenses are highly polished spheres made of optically transparent homogeneous materials. Carefully controlled manufacturing process produces spheres with precise diameters and unsurpassed surface quality. We supply optical spherical ball lens with K9, Sapphire, JGS1, Znse and Silicon ball lens and half ball lens More details please visit our website:www.ruiqi-optics.com

Innovative materials and technological progress drive the flourishing development of the optical component market In today's rapidly changing technology, optical components, as core components in many fields, are increasingly showing their importance. The continuous emergence of innovative materials and technological progress is driving the optical component market into a new era of vigorous development. 1. Innovative materials lead development With the deepening of research on new materials, the manufacturing materials of optical components are also constantly innovating. The emergence of new optical glass, crystals, thin films and other materials provides strong support for the performance improvement and functional innovation of optical components. These new materials not only have excellent physical and chemical properties, but also can to some extent reduce production costs and improve production efficiency. 2. Technological progress drives the market In terms of manufacturing technology, with the continuous progress of nanotechnology, laser processing, precision grinding and other technologies, the manufacturing accuracy and performance of optical components are also constantly improving. The application of these advanced technologies has made significant breakthroughs in the resolution, transparency, stability, and other aspects of optical components, further expanding their application scope in various fields. 3. International cooperation and exchange In the context of globalization, international cooperation and exchanges in the optical component industry are becoming increasingly frequent. Through cooperation with international advanced enterprises and research institutions, not only can advanced technology and management experience be introduced, but new products, technologies, and markets can also be jointly developed. This kind of cooperation and exchange is of great significance for promoting innovation and development in the optical component industry. 4. Environmental Protection and Sustainable Development While pursuing economic benefits, the optical component industry has also begun to pay attention to environmental protection and sustainable development. By adopting environmentally friendly materials, optimizing production processes, and reducing energy consumption, optical component companies are striving to achieve green production and sustainable development. This not only helps to enhance the social image and competitiveness of enterprises, but also conforms to the trend of global sustainable development. 5. Future outlook Looking ahead to the future, with the continuous emergence of new materials and technologies and the continuous growth of market demand, the optical component industry will usher in a broader development space. Meanwhile, with the recovery of the global economy and the rise of emerging markets, the competitive landscape of the optical component market will also undergo profound changes. In this new era full of opportunities and challenges, optical component enterprises need to constantly innovate and actively respond to market changes in order to stand invincible in competition. In short, innovative materials and technological progress are key factors driving the flourishing development of the optical component market. In the future development, the optical component industry needs to continue to strengthen innovation cooperation and communication, continuously improve product performance and application areas, and make greater contributions to global technological progress and social development.

Changchun Ruiqi owns a strong production capability in our modern workshops. We are mainly specialized in the production of lens, prisms, mirrors, cylindrical lens, beam splitters, filters and windows and blanks and infrared Material included Znse, Germanium, ZnS, BaF2 and CaF2 etc More details please visit our website:www-ruiqi-optics.com Recently one of our customers customized one type reflective mirros, diamter 114mm concave mirror with aluminium coating and passed their testing, this year they will order more. For shape we could accept customized, round, square, special-shaped etc, coating could be made silver, aluminium, gold or dielectric etc

Changchun Ruiqi owns a strong production capability in our modern workshops. We are mainly specialized in the production of lens, prisms, mirrors, cylindrical lens, beam splitters, filters and windows and blanks and infrared Material included Znse, Germanium, ZnS, BaF2 and CaF2 etc More details please visit our website:www-ruiqi-optics.com