This document provides information about Moskabel-Fujikura, a Russian manufacturer of fiber optic cables. It discusses the company's history, production capabilities, quality standards, product portfolio, customer base, and integrated supply services. Moskabel-Fujikura produces over 35,000 km of fiber optic cable annually in various types for indoor and outdoor use. It aims to contribute to Russia's telecommunications infrastructure through high quality cable products.
Shenzhen KINGTON Optic Co.Ltd is a high-tech enterprise founded in 2005 that engages in R&D, production, and exporting of fiber optic equipment. The company attracts many optical technology experts and has over 10 years of experience contributing to optical telecommunications worldwide. KINGTON's main products include optical splitters, fiber arrays, patch cords, connectors, attenuators, and more that conform to international standards and certifications. The company aims to be a leading global manufacturer through continuous innovation and improvement.
Shenzhen KINGTON Optic Co.Ltd is a fiber optic equipment company founded in 2005 that focuses on research and development, production, and exporting of fiber optic products. The company has attracted many optical technology experts and has been contributing to the optical telecommunications field for over 10 years. KINGTON's main products include optical splitters, fiber arrays, patch cords, connectors, attenuators, splice closures, and cabinets. In particular, their planar waveguide optical splitters perform well and meet telecommunications standards and regulations. KINGTON aims to be a leading manufacturer and continues to invest in technology research and development.
Tongding Group is one of the top 3 fiber optic cable manufacturers in China. Founded in 1999, it employs around 6,000 people and has manufacturing facilities in China and sales offices around the world. Tongding produces optical fiber, fiber optic cables, copper cables, and FTTx solutions. It serves major telecom operators globally and has the capacity to produce 30 million km of optical fiber per year, making it the largest fiber optic cable producer in China.
The document is a project report on Silicon on Insulator (SOI) devices submitted by two students, Kashish Grover and Sanket Gawade, to their professor. The report provides an overview of SOI technology, including the different manufacturing methods like SIMOX, Smart Cut, and ELTRAN processes. It describes the two main types of SOI devices - partially depleted SOI and fully depleted SOI. The students conducted simulations of SOI MOSFETs in SENTAURUS software and obtained the ID-VG characteristics. The report summarizes the key advantages of SOI devices like lower parasitic capacitance and better performance compared to conventional silicon substrates.
Loose tube vs. tight-buffered fiber optic cableTeresa Huang
Selecting the right type of fiber optic cable boils down to the applications and the installation. This post will introduce and compare two fiber optic cable types based on different cable constructions—loose-tube and tight-buffered fiber optic cable.
The Filoform Quicki range of Gel Joints are designed for use in outdoor, direct buried, and some submersible applications where moisture protection is critical. They are mainly used for unarmoured cables but can be used on some armoured cables with an armour continuity kit. The gel joints require no specialist tooling, have double seals for moisture protection, and have a high temperature resistant gel that works from -40°C to +140°C. They are suitable for jointing most cable types like XLPE, PVC, and EPR and include a gel filled shell, connector block, cable ties, and instructions.
Connector Inspection & Cleaning Best PracticesLizGoldsmith
Connector contamination and damage is the leading root cause of fiber optic network failures. Learn how proper cleaning techniques can help insure proper network performance
Shenzhen KINGTON Optic Co.Ltd is a high-tech enterprise founded in 2005 that engages in R&D, production, and exporting of fiber optic equipment. The company attracts many optical technology experts and has over 10 years of experience contributing to optical telecommunications worldwide. KINGTON's main products include optical splitters, fiber arrays, patch cords, connectors, attenuators, and more that conform to international standards and certifications. The company aims to be a leading global manufacturer through continuous innovation and improvement.
Shenzhen KINGTON Optic Co.Ltd is a fiber optic equipment company founded in 2005 that focuses on research and development, production, and exporting of fiber optic products. The company has attracted many optical technology experts and has been contributing to the optical telecommunications field for over 10 years. KINGTON's main products include optical splitters, fiber arrays, patch cords, connectors, attenuators, splice closures, and cabinets. In particular, their planar waveguide optical splitters perform well and meet telecommunications standards and regulations. KINGTON aims to be a leading manufacturer and continues to invest in technology research and development.
Tongding Group is one of the top 3 fiber optic cable manufacturers in China. Founded in 1999, it employs around 6,000 people and has manufacturing facilities in China and sales offices around the world. Tongding produces optical fiber, fiber optic cables, copper cables, and FTTx solutions. It serves major telecom operators globally and has the capacity to produce 30 million km of optical fiber per year, making it the largest fiber optic cable producer in China.
The document is a project report on Silicon on Insulator (SOI) devices submitted by two students, Kashish Grover and Sanket Gawade, to their professor. The report provides an overview of SOI technology, including the different manufacturing methods like SIMOX, Smart Cut, and ELTRAN processes. It describes the two main types of SOI devices - partially depleted SOI and fully depleted SOI. The students conducted simulations of SOI MOSFETs in SENTAURUS software and obtained the ID-VG characteristics. The report summarizes the key advantages of SOI devices like lower parasitic capacitance and better performance compared to conventional silicon substrates.
Loose tube vs. tight-buffered fiber optic cableTeresa Huang
Selecting the right type of fiber optic cable boils down to the applications and the installation. This post will introduce and compare two fiber optic cable types based on different cable constructions—loose-tube and tight-buffered fiber optic cable.
The Filoform Quicki range of Gel Joints are designed for use in outdoor, direct buried, and some submersible applications where moisture protection is critical. They are mainly used for unarmoured cables but can be used on some armoured cables with an armour continuity kit. The gel joints require no specialist tooling, have double seals for moisture protection, and have a high temperature resistant gel that works from -40°C to +140°C. They are suitable for jointing most cable types like XLPE, PVC, and EPR and include a gel filled shell, connector block, cable ties, and instructions.
Connector Inspection & Cleaning Best PracticesLizGoldsmith
Connector contamination and damage is the leading root cause of fiber optic network failures. Learn how proper cleaning techniques can help insure proper network performance
Optical fiber is a flexible transparent fiber made of high quality glass or plastic that transmits light between two ends. It functions as a waveguide or light pipe. Optical fibers are widely used for fiber optic communications due to their ability to transmit signals over longer distances and higher bandwidths compared to other forms of communication. Fibers are used instead of metal wires because signals travel along them with less loss and are safe from electromagnetic interference. Optical fibers have been used for communication since the 1840s and are now used for transmitting data at rates as high as 400 gigabits per second. Optical fiber provides benefits such as greater bandwidth, immunity to electrical interference, and lower signal attenuation over long distances compared to conventional copper cables.
A guide for fiber optic terminations, beyondtechBEYONDTECH
Beyondtech e-books and publications are created in order to help fiber optic apprentices eager to improve their techniques and learn everything they can about this amazing topic.
Optical fiber terminations need to be done carefully in order to have low loss and minimal reflectance. But for these procedures to be done perfectly, constant practice is mandatory.
Part I details the steps that have to be followed to do a permanent joint using a mechanical splice, Part II explains how to do a connectorization and Part III describes the way polishing needs to be done. This processes might be used with both multimode and single-mode fiber and with other connectors besides ST.
This document provides a catalogue of test tools from Fluke Corporation, including clamp meters, earth ground testers, infrared cameras, and more. It summarizes the key features and specifications of various product lines. New products are highlighted such as the Fluke 381 clamp meter with a remote display and iFlex flexible current probe. Accessories and replacement models are also listed.
The document provides details about an engineering team consisting of 4 members and their roles. It then outlines the steps required to prepare, connect, insert fibers, crimp connectors, cure epoxy, clean, polish and inspect fiber optic connections.
The document describes Light Runner, a benchtop fiber optic communication laboratory developed by Fiber Optika Technologies Pvt Ltd. Light Runner bridges the gap between academia and industry by providing hands-on experience with modern fiber optic technologies like WDM, EDFA, OTDR and OADM. It contains components and experiments to teach key concepts in a compact and portable device. Light Runner is aimed to help students and technicians learn the cutting-edge fiber optic communication technology.
Fiber optic communication uses lightwave technology to transmit data over long distances and local networks. It has three main elements: a compact light source like an LED or laser, low loss optical fiber made of glass or plastic, and a photo detector to convert light signals back to electrical signals. Fiber optic communication works by converting electrical signals to light signals using a light source in the transmitter, carrying the light beam through the fiber optic cable, and converting it back to an electrical signal using a receiver circuit with a photo detector. This allows for gigabit transmission of data, voice, video, and telemetry over longer distances than traditional copper wire networks.
Fiber optic communication has several military applications due to its advantages over traditional copper wire. It allows for repeaters every 16km compared to 500m for coax, is lighter weight, and has higher bandwidth for transmitting multiple signals. Fiber optic cables are also more secure as they are not affected by electromagnetic or radio frequency interference and are very difficult to tap. One weapon application is the FOG-M missile, which uses a fiber optic cable to transmit video feedback to the gunner for guidance. Fiber optics are also used for optical computing, military surveillance and sensors due to their ruggedness, and aboard vehicles since they are lighter and immune to electromagnetic interference.
Fiber optic and its recent trends
The document discusses the history and evolution of fiber optic technology from 1880 to present day. It covers the basic components and types of optical fibers including single mode fiber, multi-mode fiber, step index fiber and graded index fiber. Recent trends in the fiber optic industry include the move to higher bandwidth through advances like dense wavelength division multiplexing and smaller component miniaturization. Fiber optic networks continue to evolve to support faster data rates and more intelligent network architectures.
Optical fiber uses pulses of light to transmit information over long distances and has largely replaced copper wire for telecommunications. It works by total internal reflection of light through fiber optic cables containing glass or plastic fibers. Optical fiber transmits digital signals for telephone calls, internet, and cable TV using semiconductor devices like lasers and photodetectors. Fiber optic communication has revolutionized telecommunications by enabling much higher bandwidth transmission over greater distances than electrical wires.
Fiber optic systems are important telecommunication
infrastructure for world-wide broadband networks. Wide
bandwidth signal transmission with low delay is a key
requirement in present day applications. Optical fibers provide
enormous and unsurpassed transmission bandwidth with
negligible latency, and are now the transmission medium of
choice for long distance and high data rate transmission in
telecommunication networks.
Optical fiber communication uses glass or plastic fibers to transmit light signals for telecommunication. Light from a laser or LED is transmitted through the fiber's core using total internal reflection. Optical fibers have advantages over copper cables including higher bandwidth, less signal degradation, lighter weight, and immunity to electromagnetic interference. Fiber systems use single-mode or multi-mode fibers depending on the transmission distance and bandwidth needs.
Optical fibers are thin glass rods wrapped in plastic that are used to transmit light signals for applications such as high-speed internet, telecommunications, endoscopy, and microscopy. They allow transmission of data over longer distances and in places where copper wires cannot reach. Optical fibers work via the phenomenon of total internal reflection, where light bouncing around the higher refractive index glass core is reflected back in rather than escaping at the lower refractive index cladding.
Fiber optic sensors have four potential functions in structural health monitoring: monitoring external manufacturing process parameters, serving as embedded sensors for non-destructive evaluation, functioning as a data-link network to support other SHM systems, and complementing performance monitoring and control systems. Fiber optic sensors have advantages over conventional electronic sensors in that they are made of silica-based materials, enable multiplexing, and have a lower cost. They can provide distributed sensing along structures like buildings to monitor temperature. Fiber Bragg grating sensors embedded in concrete have been used to measure strain on the Confederation Bridge in Canada.
This document is the September 2007 issue of a magazine about communications systems. The cover story discusses how a rural school district in Georgia used federal funding to implement a high-speed 10-Gigabit Ethernet network across the entire district to support advanced teaching technologies. An article on page 11 discusses the growing acceptance and market share of blown fiber optic cable systems in certain regions as vendors enhance their product lines. Another article on page 19 details how the rural Georgia school district acquired funds from the E-Rate program to build out their new 10-Gigabit Ethernet network.
application of fibre optics in communicationRimmi07
Fibre optic communication has revolutionised telecommunications by enabling much longer distance links with lower loss and higher data rates. Fibre optic systems use total internal reflection to transmit light through the fibre and are used widely in telecom backbones, broadband networks, and data transmission. Single mode fibre has a small core and transmits single signals for long distances, while multi-mode fibre has a larger core and transmits multiple signals for shorter links like local networks. Fibre optics enable high-speed internet, cable TV, and reliable data transmission.
Lights Fantastic: The Current State of Fiber Opticsexperior
These slides cover fiber fundamentals but mostly focused on the current state and trend of fiber optics.
These slides were used in a speech by the President of Experior Laboratories, Lorenz Cartellieri
CHAPTERS
1. Fiber Basics
2. Telecommunication Trends
3. Military and Aerospace Trends
4. Industrial and Automotive Trends
5. Medial Trends
6. Summary
www.experiorlabs.com
Headquartered in Oxnard, Southern California, Experior Laboratories, Inc. is a third party, independent testing, design verification and qualification test laboratory. Specializing in fiber optics, electrical connectors and general environmental testing, Experior provides services to component manufacturers, military contractors, integrators and system providers within the telecom, datacom, military, aerospace and industrial markets. The company also provides ISO accredited calibration services for fiber optic / lightwave test instruments. Provided testing services are in accordance with Bellcore/Telcordia requirements and the company is MIL-STD-790 approved by DLA/DSCC for QPL testing of electrical and fiber optic components. Experior Labs is also a member of the prestigious Verizon FOC (Fiber Optic Component) Program as a certified ITL (Independent Test Lab).
This document provides an overview of optical fiber communication. It begins with introducing optical fibers and how they guide light through total internal reflection. It then describes the different types of optical fibers, including step index and graded index fibers. The key elements of an optical fiber communication system are presented, along with the benefits such as high bandwidth, low loss, and electrical isolation. Applications include telecommunications networks, computing, and military systems. In conclusion, while optical fibers have some disadvantages, they have revolutionized communications due to their wide bandwidth and low transmission losses.
This document provides an overview of optical fibers, including their evolution, structure, working principles, classification, communication systems, advantages and applications. It discusses how optical fibers guide light using total internal reflection. Fibers are classified based on mode (single or multi-mode) and refractive index profile (step or graded). Key advantages are high bandwidth, low attenuation, immunity to EMI, and security. Applications include telecommunications, broadband, medicine, military and more. Optical fibers have become the backbone of long-distance networks since the 1980s due to refinements in manufacturing.
Ideal for cable pulling & installation of signaling & communication cables, optical fiber cables, datacom cables in street lighting, campus installations, airports & industrial conduits up to 120 meters.
4SProducts is an international cable manufacturer with 35 years of experience. It produces various types of cables including power cables, telecom cables, optical cables, and aluminum conductors. 4SProducts has full production facilities across 392,086 square meters and aims to deliver high-quality, competitively priced cables while meeting various industry standards and customer requirements. It offers financing options and focuses on on-time deliveries to customers around the world.
Optical fiber is a flexible transparent fiber made of high quality glass or plastic that transmits light between two ends. It functions as a waveguide or light pipe. Optical fibers are widely used for fiber optic communications due to their ability to transmit signals over longer distances and higher bandwidths compared to other forms of communication. Fibers are used instead of metal wires because signals travel along them with less loss and are safe from electromagnetic interference. Optical fibers have been used for communication since the 1840s and are now used for transmitting data at rates as high as 400 gigabits per second. Optical fiber provides benefits such as greater bandwidth, immunity to electrical interference, and lower signal attenuation over long distances compared to conventional copper cables.
A guide for fiber optic terminations, beyondtechBEYONDTECH
Beyondtech e-books and publications are created in order to help fiber optic apprentices eager to improve their techniques and learn everything they can about this amazing topic.
Optical fiber terminations need to be done carefully in order to have low loss and minimal reflectance. But for these procedures to be done perfectly, constant practice is mandatory.
Part I details the steps that have to be followed to do a permanent joint using a mechanical splice, Part II explains how to do a connectorization and Part III describes the way polishing needs to be done. This processes might be used with both multimode and single-mode fiber and with other connectors besides ST.
This document provides a catalogue of test tools from Fluke Corporation, including clamp meters, earth ground testers, infrared cameras, and more. It summarizes the key features and specifications of various product lines. New products are highlighted such as the Fluke 381 clamp meter with a remote display and iFlex flexible current probe. Accessories and replacement models are also listed.
The document provides details about an engineering team consisting of 4 members and their roles. It then outlines the steps required to prepare, connect, insert fibers, crimp connectors, cure epoxy, clean, polish and inspect fiber optic connections.
The document describes Light Runner, a benchtop fiber optic communication laboratory developed by Fiber Optika Technologies Pvt Ltd. Light Runner bridges the gap between academia and industry by providing hands-on experience with modern fiber optic technologies like WDM, EDFA, OTDR and OADM. It contains components and experiments to teach key concepts in a compact and portable device. Light Runner is aimed to help students and technicians learn the cutting-edge fiber optic communication technology.
Fiber optic communication uses lightwave technology to transmit data over long distances and local networks. It has three main elements: a compact light source like an LED or laser, low loss optical fiber made of glass or plastic, and a photo detector to convert light signals back to electrical signals. Fiber optic communication works by converting electrical signals to light signals using a light source in the transmitter, carrying the light beam through the fiber optic cable, and converting it back to an electrical signal using a receiver circuit with a photo detector. This allows for gigabit transmission of data, voice, video, and telemetry over longer distances than traditional copper wire networks.
Fiber optic communication has several military applications due to its advantages over traditional copper wire. It allows for repeaters every 16km compared to 500m for coax, is lighter weight, and has higher bandwidth for transmitting multiple signals. Fiber optic cables are also more secure as they are not affected by electromagnetic or radio frequency interference and are very difficult to tap. One weapon application is the FOG-M missile, which uses a fiber optic cable to transmit video feedback to the gunner for guidance. Fiber optics are also used for optical computing, military surveillance and sensors due to their ruggedness, and aboard vehicles since they are lighter and immune to electromagnetic interference.
Fiber optic and its recent trends
The document discusses the history and evolution of fiber optic technology from 1880 to present day. It covers the basic components and types of optical fibers including single mode fiber, multi-mode fiber, step index fiber and graded index fiber. Recent trends in the fiber optic industry include the move to higher bandwidth through advances like dense wavelength division multiplexing and smaller component miniaturization. Fiber optic networks continue to evolve to support faster data rates and more intelligent network architectures.
Optical fiber uses pulses of light to transmit information over long distances and has largely replaced copper wire for telecommunications. It works by total internal reflection of light through fiber optic cables containing glass or plastic fibers. Optical fiber transmits digital signals for telephone calls, internet, and cable TV using semiconductor devices like lasers and photodetectors. Fiber optic communication has revolutionized telecommunications by enabling much higher bandwidth transmission over greater distances than electrical wires.
Fiber optic systems are important telecommunication
infrastructure for world-wide broadband networks. Wide
bandwidth signal transmission with low delay is a key
requirement in present day applications. Optical fibers provide
enormous and unsurpassed transmission bandwidth with
negligible latency, and are now the transmission medium of
choice for long distance and high data rate transmission in
telecommunication networks.
Optical fiber communication uses glass or plastic fibers to transmit light signals for telecommunication. Light from a laser or LED is transmitted through the fiber's core using total internal reflection. Optical fibers have advantages over copper cables including higher bandwidth, less signal degradation, lighter weight, and immunity to electromagnetic interference. Fiber systems use single-mode or multi-mode fibers depending on the transmission distance and bandwidth needs.
Optical fibers are thin glass rods wrapped in plastic that are used to transmit light signals for applications such as high-speed internet, telecommunications, endoscopy, and microscopy. They allow transmission of data over longer distances and in places where copper wires cannot reach. Optical fibers work via the phenomenon of total internal reflection, where light bouncing around the higher refractive index glass core is reflected back in rather than escaping at the lower refractive index cladding.
Fiber optic sensors have four potential functions in structural health monitoring: monitoring external manufacturing process parameters, serving as embedded sensors for non-destructive evaluation, functioning as a data-link network to support other SHM systems, and complementing performance monitoring and control systems. Fiber optic sensors have advantages over conventional electronic sensors in that they are made of silica-based materials, enable multiplexing, and have a lower cost. They can provide distributed sensing along structures like buildings to monitor temperature. Fiber Bragg grating sensors embedded in concrete have been used to measure strain on the Confederation Bridge in Canada.
This document is the September 2007 issue of a magazine about communications systems. The cover story discusses how a rural school district in Georgia used federal funding to implement a high-speed 10-Gigabit Ethernet network across the entire district to support advanced teaching technologies. An article on page 11 discusses the growing acceptance and market share of blown fiber optic cable systems in certain regions as vendors enhance their product lines. Another article on page 19 details how the rural Georgia school district acquired funds from the E-Rate program to build out their new 10-Gigabit Ethernet network.
application of fibre optics in communicationRimmi07
Fibre optic communication has revolutionised telecommunications by enabling much longer distance links with lower loss and higher data rates. Fibre optic systems use total internal reflection to transmit light through the fibre and are used widely in telecom backbones, broadband networks, and data transmission. Single mode fibre has a small core and transmits single signals for long distances, while multi-mode fibre has a larger core and transmits multiple signals for shorter links like local networks. Fibre optics enable high-speed internet, cable TV, and reliable data transmission.
Lights Fantastic: The Current State of Fiber Opticsexperior
These slides cover fiber fundamentals but mostly focused on the current state and trend of fiber optics.
These slides were used in a speech by the President of Experior Laboratories, Lorenz Cartellieri
CHAPTERS
1. Fiber Basics
2. Telecommunication Trends
3. Military and Aerospace Trends
4. Industrial and Automotive Trends
5. Medial Trends
6. Summary
www.experiorlabs.com
Headquartered in Oxnard, Southern California, Experior Laboratories, Inc. is a third party, independent testing, design verification and qualification test laboratory. Specializing in fiber optics, electrical connectors and general environmental testing, Experior provides services to component manufacturers, military contractors, integrators and system providers within the telecom, datacom, military, aerospace and industrial markets. The company also provides ISO accredited calibration services for fiber optic / lightwave test instruments. Provided testing services are in accordance with Bellcore/Telcordia requirements and the company is MIL-STD-790 approved by DLA/DSCC for QPL testing of electrical and fiber optic components. Experior Labs is also a member of the prestigious Verizon FOC (Fiber Optic Component) Program as a certified ITL (Independent Test Lab).
This document provides an overview of optical fiber communication. It begins with introducing optical fibers and how they guide light through total internal reflection. It then describes the different types of optical fibers, including step index and graded index fibers. The key elements of an optical fiber communication system are presented, along with the benefits such as high bandwidth, low loss, and electrical isolation. Applications include telecommunications networks, computing, and military systems. In conclusion, while optical fibers have some disadvantages, they have revolutionized communications due to their wide bandwidth and low transmission losses.
This document provides an overview of optical fibers, including their evolution, structure, working principles, classification, communication systems, advantages and applications. It discusses how optical fibers guide light using total internal reflection. Fibers are classified based on mode (single or multi-mode) and refractive index profile (step or graded). Key advantages are high bandwidth, low attenuation, immunity to EMI, and security. Applications include telecommunications, broadband, medicine, military and more. Optical fibers have become the backbone of long-distance networks since the 1980s due to refinements in manufacturing.
Ideal for cable pulling & installation of signaling & communication cables, optical fiber cables, datacom cables in street lighting, campus installations, airports & industrial conduits up to 120 meters.
4SProducts is an international cable manufacturer with 35 years of experience. It produces various types of cables including power cables, telecom cables, optical cables, and aluminum conductors. 4SProducts has full production facilities across 392,086 square meters and aims to deliver high-quality, competitively priced cables while meeting various industry standards and customer requirements. It offers financing options and focuses on on-time deliveries to customers around the world.
The document discusses fiber optic cable types and designs. It describes the various construction elements that make up fiber optic cables, including the fiber buffer, cable core, sheath, armor, and other protective elements. It also outlines the different cable construction types for outdoor, indoor, and special use cables. Finally, it provides details on the fiber optic cable production process and specifications.
Opportunities & Challenges for Marine Cables Jerry Brown
This document discusses opportunities and challenges in marine cables. It provides an overview of Hengtong Marine Cable Systems, including their factory capabilities and port facilities. Some key challenges discussed are storage and integration of long length submarine cables, and meeting various client requirements for telecom, oil and gas, and other specialized cables. The document also outlines Hengtong's submarine cable test center which is important for research, development, testing and certification of cables and accessories.
Loose tube cables can be either dielectric or optionally armored. The loose-tube design helps in the identification and administration of fibers in the system.
This document provides an overview of XDK's fiber optic products and manufacturing capabilities. XDK offers a wide range of pre-terminated fiber optic assemblies, cables, connectors, and passive optical components. They have 5 cable production lines with a monthly capacity of over 60 million meters. XDK prides itself on its dependable supply, customization support, certifications including UL and ISO, and facilities with clean rooms and advanced testing equipment. The company focuses on teamwork, continuous learning, respect, and community involvement.
Nestor Cables has evolved from a traditional cable manufacturer to a provider of complete connectivity solutions. The document introduces six of Nestor's solutions: Fibre to the Antenna, Fibre to the Home, Fibre Optic Cables for Windmill Farms, Mobile Optical Cable Units, the Nestor Cables Security System, and a Microduct Cabling Solution. It provides details on the Fibre to the Antenna solution and its main feeder cable and jumper cables. It also gives an overview of Nestor's product portfolio for Fibre to the Home networks including cables, installation accessories, termination products and more.
Hastel is a renowned Turkish manufacturer of high-quality cables established in 1997. It produces fire resistance cables, signal and control cables, data transmission cables, coaxial cables, communication cables, silicon cables, special cables, instrumentation cables, and bus cables for industries such as building and infrastructure, oil and gas, and data communication. Hastel prides itself on innovation, quality control processes, and certifications to standards like ISO, TSE, VDE, TSEK, CE, ROSH, and GOST. It has a wide range of cable production capabilities and a commitment to operating ethically.
Hastel is a renowned Turkish manufacturer of high-quality cables established in 1997. It produces fire resistance, signal, data transmission, coaxial, communication, silicon, and special cables. Hastel prides itself on innovative manufacturing methods, stringent quality control, and certifications to international standards. It aims to be a trusted partner through expertise, safety, innovation, and responsibility.
Gbic-shop.de is a manufacturer of active and passive network solutions such as fiber patch cords. Fiber patch cords use thin glass optical fibers to transmit light signals between network devices like switches and routers over long distances with low signal loss. Different types of fiber patch cords, such as single-mode and multi-mode, are optimized for different network needs. Mechanical transfer registered jacks (MTRJ) are also commonly used optical fiber connectors that are smaller than standard connectors to reduce costs.
This document provides information about BMET energy telecom industry and trade PLC, a cable factory in Ethiopia. It discusses the company's history, including its establishment in 2010 and the start of production in 2013. It also describes the factory's buildings, infrastructure, machinery, production processes for different cable types, and technical specifications. In general, the document outlines the operations and capabilities of BMET as one of the largest cable manufacturers in Ethiopia.
JTOPTICS introduces the Outdoor Cable Assembly-Waterproof Series, meticulously designed for challenging environments. Our FTTA Patch Cord is constructed with a waterproof housing, ensuring compliance with IP67/IP68 environmental sealing standards. The LC UPC duplex connectors, paired with a flame-retardant LSZH jacket, provide superior crush resistance and flexibility, making it ideal for both indoor and outdoor industrial installations. The armored tube enhances durability, while UV stabilization and resistance to industrial chemicals further contribute to its robust design.
Key Features:
Enhanced optical performance to meet telecom requirements
Cable with IEC 60332-3-24 fire performance
IEC, EIA/TIA, and Telcordia compliant
RoHS, REACH, and SvHC compliant
High-quality connectors and Zirconia Ceramic Ferrule
Low insertion loss and high return loss
IP67/IP68 water and dust protection
Compliance with IEEE 802.1 CM standard
Flexibility with a small bending radius and excellent cable routing properties
As 5G integration becomes more prevalent, the demand for increased fiber bandwidth between radio units and baseband units rises. To address this, CPRI and eCPRI are anticipated to play vital roles in 5G networks, with eCPRI being particularly suitable for 5G fronthaul applications.
For more information, visit WWW.JTOPTICS.COM.
High Tension Wire & Cables at kei-ind.com/ht-cables.phpVinay Pravidhi
KEI manufactures HT XLPE cables up to 220KV conforming to National and International Standards at Bhiwadi plant. KEI has State of Art HT cable plant with German technology. The manufacturing capability is upto 220KV.
Huiyuan Optical Communications Co., Ltd. is a leading Chinese manufacturer of optical fiber cables. The document discusses several types of cables produced by the company, including:
1) Power optical fiber cables like OPGW and ADSS cables that can be installed on power lines.
2) Micro air-blown cables for FTTx applications in 1-3 fiber counts with central loose tube or layer stranding structures.
3) Common cables such as central tube armored cables, layer stranding cables with steel or aluminum tape armoring, and self-supporting figure 8 cables for long-distance trunk lines.
The company has annual production capacity of 2 million km for communication cables and 500
This document discusses various applications of fiber optic cable networks including:
1. Fiber To The Home networks which provide voice, video, and data services over a single fiber using different wavelengths of light. Popular FTTH network types include BPON, EPON, and GPON.
2. Metropolitan telecom networks which connect local area networks across a region and require high-speed connections best provided by fiber optic cables.
3. Long distance telecom networks which transmit telephone, internet, and television signals between cities using a backbone of fiber optic cables laid underground and underwater.
Cable Solutions and Hydro Solutions provide cables and cable systems for harsh and underwater environments. Some of their offerings include Amercable products, Norwegian and British specification cables, panel wiring, data and fiber optic cables, terminations and assemblies, ROV cables, umbilicals, tow cables, and custom designed composite cables built to specifications. They offer services like project management, material management, pre-terminated cables, repairs, and technical support.
Fiber optics are compact, lightweight rugged design, saving the space in patch panels. Used to terminate fiber optic cable & provide a connection to individual spliced fibers
Due to security concerns, many industrial automation companies using fiber optics instead of wired & wireless ethernet as fiber optic signals.
Fiber optics also protect against hackers & able to detect the thief
The document discusses the future of fibre optic networks and the way forward. It promotes the use of air blown fibre technology, such as the Blolite+ system, for deploying fibre infrastructure. Air blown fibre allows a deferred capital cost model where ducts are installed initially and fibre is blown in later as needed. This provides savings over traditional fibre installation and enables fibre to be deployed more flexibly. Standards organizations and new fibre types are also discussed as supporting the growth of fibre networks.
Communication networks are the vital part of today’s world and based mostly on the optical networks. Nestor Cables provides all needed passive components to the optical network and we are privileged to develop this vital sector in forefront providing our customers continuously developing product portfolio. Additionally we also provide copper telecommunication cables for all applications and industrial copper cables for automation and control purposes. Industries we serve: Energy, Oil&Gas, Utilities, Telecommunications, Security, Defence, etc.
Fiber optic cables transmit data using glass strands coated with plastic. Light signals travel through the strands due to total internal reflection off the plastic coating. Fiber optic cables have advantages over copper cables like extremely high bandwidth, security, reliability, and immunity to electromagnetic interference. However, fiber optic cables also have disadvantages such as high initial installation costs, susceptibility to physical damage, and requiring specialized testing equipment.
- The document discusses Neva Metall Posuda (NMP), the largest manufacturer of cookware in Russia. It has the most advanced die-casting and crystallization technology in Russia and owns its own foundry.
- NMP produces high quality products through strict 7-level quality control. It has ISO 9001 quality management certification.
- NMP has increased its market share from 4.9% to 10.7% over the past year through moderate price increases. It is now the largest manufacturer in the "mass premium" cookware segment.
The Nevsky konditer SPb LLC was founded in 1996 and is now one of the largest confectionery manufacturers in Russia. It produces over 300 tons of more than 420 products daily across two plants in Penza region. The company supplies customers across Russia and internationally with a wide range of high quality confectionery.
Este documento presenta la compañía PGM Urban Hardlandscapes S.L., la cual produce productos de materiales compuestos para uso en construcción. Describe los tipos de productos como vallados, canales de drenaje y escaleras, así como las ventajas de los materiales compuestos sobre los metálicos. También detalla los procesos de producción, experiencia aplicando los productos, y la capacidad actual de producción de la fábrica en Kaliningrado.
The document discusses the benefits of exercise for both physical and mental health. Regular exercise can improve cardiovascular health, reduce stress and anxiety, boost mood, and may even help prevent chronic diseases. Staying active for at least 30 minutes each day is recommended for overall health and well-being.
The document outlines plans to construct a greenhouse complex in Belgorod region of Russia. The complex will have a total area of 24 hectares and be capable of producing at least 19.3 thousand tons of vegetables annually by the end of 2019. The project aims to build modern greenhouse facilities with year-round vegetable production and maximize local food supply. It provides details on the construction process, budgets, and social and economic criteria for measuring the project's success.
The document summarizes the development of an organized timber commodity market on the Saint Petersburg International Mercantile Exchange (SPIMEX) from 2014 to 2017. It discusses the expansion of trading to new regions, increasing trading volumes and values, and plans to further develop mandatory exchange trading of timber including for export. Trading volumes on the exchange increased from 37,000 cubic meters in 2014 to over 637,000 cubic meters in 2016, with continued growth projected in 2017.
The Komi Republic is located in northeastern European Russia. It has an area of 416,800 square km and a population of around 880,000 people. The capital and largest city is Syktyvkar. The Komi Republic has a wealth of natural resources, particularly mineral resources, forests, and fossil fuels. It is one of Russia's most important fuel and energy production regions. The economy focuses on extractive industries like mining, forestry, and energy production. The Komi Republic offers various tax incentives and other forms of support to attract investors and encourage economic development.
Región de Kémerovo está situada en el suroeste de Siberia con una superficie de 95.7 mil de km². La región tiene red de transporte muy desarrolada de los Urales. Su territorio cruzan las redes importantes de ferrocarril y carreteras de Rusia - el Transiberiano.
Kémerovo es una de las regiones industriales más importantes de Rusia, con uno de los mayores depósitos de carbón del mundo. Región de Kémerovo está dominado por la industria metalúrgica y la minera, la petroquímica y la ingeniería mecánica.
“Gidrokompozit” LLC is equipped with modern injection molding machines JONWAI with clamping forces from 120 to 650 tons and shot sizes up to 3500 cm3.
High-tech equipment makes it possible to produce parts from 5 grams to 3 kilograms from various materials, such as polyamide, polyethylene, polypropylene, acrylonitrile butadiene styrene copolymer (ABS), liquid crystal polymer (LCP), and their blend compounds.
The modern laboratory of physical and mechanical and physical-chemical analysis, certified by ILAC, is developing compounds for replacement existing metal solutions and performing the quality control of raw materials and final products.
The Republic of Buryatia now is a region of dynamic development of industrial potential and favorable investment climate that makes it one of the most attractive regions of Russia.
Concurso internacional de los proyectos de innovación en química IQ-CHem.
IQ-CHem is an international contest of innovative projects in the field of chemistry and new materials
This document describes an organic fertilizer called BIOST-1. It is made from dried sludge deposits and improves soil properties and plant nutrition. When applied, it increases soil organic matter and yields for many crop types by 10-40%. It is safe for use as it does not contain toxic levels of elements and does not pollute the environment when applied as directed. BIOST-1 is an effective and environmentally friendly organic fertilizer.
The Tula Region Development Corporation document provides information from Tula Region's participation in the XV International Investment Forum "Sochi-2016" in October 2016. Some key details include:
- Tula Region signed 3 agreements of intent worth over 10 billion rubles to cooperate on projects in the Special Economic Zone of Industrial Type "Uzlovaya".
- The Sochi forum provided an opportunity for Tula Region to present investment opportunities, resulting in the first investment agreements for the Uzlovaya zone.
- Upcoming events include the Russian Regions Day in Austria on November 18th, where Tula Region will present its largest investment projects.
LLC "CARBONEX" is a Russian trading organization formed in 2015 by experienced professionals to export timber and supply raw materials. They have extensive experience in exports and offer independent quality control, optimal logistics selection, customized sourcing, and certified products. Their main product is timber from Russia, and they can be contacted via phone, Skype, email or their website.
Building a Raspberry Pi Robot with Dot NET 8, Blazor and SignalRPeter Gallagher
In this session delivered at NDC Oslo 2024, I talk about how you can control a 3D printed Robot Arm with a Raspberry Pi, .NET 8, Blazor and SignalR.
I also show how you can use a Unity app on an Meta Quest 3 to control the arm VR too.
You can find the GitHub repo and workshop instructions here;
https://bit.ly/dotnetrobotgithub
Google Calendar is a versatile tool that allows users to manage their schedules and events effectively. With Google Calendar, you can create and organize calendars, set reminders for important events, and share your calendars with others. It also provides features like creating events, inviting attendees, and accessing your calendar from mobile devices. Additionally, Google Calendar allows you to embed calendars in websites or platforms like SlideShare, making it easier for others to view and interact with your schedules.
2. 2
The purpose of "Moskabel-Fujikura" - to
provide customers with competitive products
of consistently high quality for business
success
The mission of "Moskabel-Fujikura" - make
a worthy contribution to the development of
the telecommunications infrastructure and the
construction of the information society in
Russia and around the world
“MOSKABEL– FUJIKURA”
3. 3
ABOUT US
• "Moskabel-Fujikura" founded September 9, 1999 on the basis of production
facilities of "Moskabelmet“ company with the participation of the Japanese firm
"Fujikura Ltd".
• In 2001 the company took the leading position in the production of optical cable in
Russia and keeps them up to date.
• "Moskabel-Fujikura" can produce up to 35,000 km of cable per year.
• Technological capabilities allow the company to produce all types of optical
communication cables with the additional requirements of customers.
4. 4
“MOSKABEL– FUJIKURA”
Over 160,000 km of optical cable of our production with about
4,000,000 km of fiber are in operation - indicator of demand and
reliability of our products.
Among our customers are :
• «ROSTELECOM»,
• «Mobile TeleSystem»,
• «Beeline»,
• «Megafon»,
• «Transneft»,
• «GAZPROM»,
• «Beltelecom» ,
• «Moscow metropolitan»
• Ministry of Defence of the Russian Federation an many others.
5. 5
“MOSKABEL– FUJIKURA”
We have the most modern equipment by SWISSCAB
(Switzerland), ROSENDAHL (Austria), NEXTROM (Finland),
MAILLEFER (Finland), MALI (Austria), Dunst (Austria), Sket
(Germany), Medek & Schorner (Austria) and others.
6. 6
“MOSKABEL– FUJIKURA”
for the production of fiber optic cable, we use the highest
quality materials from leading world manufacturers such as:
Fujikura, Borealis, Du Pont, TEIJIN TWARON, Herkula, BASF,
Huls GmbH and others.
7. 7
PRODUCT QUALITY
Quality of produced cable confirmed by:
Declarations of Conformity to the requirements
of “Russian Federal Communications Agency."
Certificate of compliance with the Russian
Defense Ministry
Optic cables, on request, can be manufactured with cable sheath made of
polymer material flame-retardant for single and bundle installation, HFFR, low
smoke emission or with sheath from plastic tracking resistant material.
8. 8
ACCREDITED TESTING LABORATORY
Laboratory equipment allows to control
tensile strength of:
Aramid fiber
Steel wire
Fastener threads.
Fiberglass rod
Polymeric materials.
And also to measure the geometric dimensions by a non-
contact method.
To control the quality of manufactured cables
there is a testing laboratory. All materials are
carefully monitoring the input. Parameters of the
optical fiber are controlled after each cable
manufacturing operation.
9. 9
ACCREDITED TESTING LABORATORY
Heating Cabinet
«Heraeus» allows the
testing of polymers and
semi-optic cable when
heated to +300 ° C.
Viscometer «Brookfield
DV-II» to control
parameters for the optical
fiber dyes and hydrophobic
fillers.
The AQ8603 Optical Strain
Analyzer is a dedicated
analyzer using special
brillouin backscattering
detection technology is used
for optical fiber strain
detection and strain
monitoring during cable
production, installation and
operation
11. 11
Environmental testing - checking optical cables
resistance to mechanical stress at low
temperatures.
Our “aerial” cables may be mounted at a
temperature of -30 °C.
Test of resistance to a tensile force for self-
supporting and suspended optic cables are
carried out using the accessories, ensuring a
correct estimate of the resistance of cables
during operation.
ACCREDITED TESTING LABORATORY
12. 12
“MOSKABEL– FUJIKURA” MANUFACTURES
THE FOLLOWING OPTICAL CABLES
Outdoor fiber optic cable for laying in ground
Outdoor fiber optic cable for laying in duct
Outdoor fiber optic cable hanging on a rope and
suspended flat
Outdoor fiber optic cable for overhead installation
dielectric self-supporting
Outdoor fiber optic cable for blowing in plastic tubes
Indoor fiber optic cables (distribution, subscriber)NEW
13. 13
Outdoor fiber optic cable armored with round galvanized
steel wires used for laying in the ground all categories except
subject to low temperature deformation, in cable ducts, pipes,
blocks, reservoirs, tunnels, bridges and underground mines
in the water while crossing bogs, lakes and rivers with a
maximum depth of no more than 10m.
Operating temperature of the cable: -40°C to +70°C.
FIBER OPTIC CABLE FOR LAYING
IN GROUND
14. 14
Outdoor fiber optic cable armored with corrugated
steel tape and polyethylene outer sheath. Designed
for installation in cable ducts, pipes, blocks,
reservoirs, tunnels, bridges and mines.
Operating temperature of the cable: -40°C to +70°C.
FIBER OPTIC CABLE FOR LAYING
IN CABLE DUCTS
15. 15
AERIAL FIBER OPTIC CABLE WITH
EXTERNAL STRENGTH MEMBER
Cables are designed for suspension and
operation on aerial communication lines and
street lighting poles, urban transport contact
network , supports broadcasting network,
between the buildings.
Operating temperature of the cable: -60°C to
+70°C.
Aerial optical cable with
external strength member of
the fiberglass rod, steel wire
rope or steel wire.
16. 16
AERIAL FLAT FIBER OPTIC CABLE
Cables are designed for suspension and operation on aerial
communication lines and street lighting poles, urban
transport contact network , supports broadcasting network,
between the buildings.
Operating temperature of the cable: -60°C to +70°C.
Suspended optical cable
with the central tube
containing up to 48 optical
fibers and strength member
of the two fiberglass rods.
17. 17
Suspended optical cable, self-supporting, dielectric, with a
central strength member of the fiberglass rod with
additional strength member of aramid yarns or glass yarns.
Cable is designed for suspension on the poles of
communication lines, contact network of railways, public
lighting poles and overhead power lines.
Operating temperature of the cable: -60°C to +70°C.
ALL DIELECTRIC SELF-SUPPORTING
OPTICAL CABLE
18. 18
OUTDOOR FIBER OPTIC CABLE FOR INSTALLATION IN PLASTIC
PIPES AND ALSO FOR INDOOR INSTALLATION
Optical cable is designed for installation in
cable ducts and plastic pipes by blowing
method.
Operating temperature of the cable: -40°C
to +70°C.
At the request of the customer cable can
be produced with outer sheath made of
polymer material flame-retardant for
bundle installation, HFFR, low smoke
emission (LSZH).
19. 19
FIBER OPTIC CABLE FOR LOCAL AREA NETWORKS
In 2012, "Moskabel-Fujikura" purchased new equipment
and started the production of new types of optical cables:
Simplex
Duplex
Distribution
Riser
Breakout
Drop-cable
subscriber and for
suspension
20. 20
FIBER OPTIC INDOOR CABLE
(SIMPLEX, DUPLEX)
Indoor fiber optic cable with one or two Tight
Buffered fibers, with aramid yarn strength
member, with outer sheath made of polymer
material flame-retardant, low smoke, zero halogen
(LSZH).
The cable is designed for indoor installation, for
production of optical cords and pigtails.
Operating temperature of the cable: -10°C to +50°C.
1. Undyed fiber
2. The buffer layer of polyamide, polyethylene, PVC.
3. Aramid yarn strength member.
4. FR PE LSZH sheath.
21. 21
FIBER OPTIC INDOOR CABLE
(BREAKOUT)
1. Simplex cable;
2. Fiberglass rod;
3. Outer sheath made of polymer material flame-retardant, low smoke, zero halogen (LSZH).
Indoor distribution optical cable containing
from 1 to 24 Simplex cables, stranded
around the strength member - fiberglass
rod, with outer sheath made of polymer
material flame-retardant, low smoke, zero
halogen (LSZH).
The cable is designed for horizontal and vertical
indoor installation in special boxes.
Operating temperature of the cable: -10°C to
+50°C.
22. 22
FIBER OPTIC INDOOR CABLE
(DISTRIBUTION)
1. Tight Buffered fiber;
2. Aramid yarn;
3. Outer sheath made of polymer material flame-retardant, low smoke, zero halogen
(LSZH).
Indoor distribution optical cable containing
up to 288 optical fibers in Tight Buffer
sheath or micro loose tubes with optical
fiber, with aramid yarn strength member and
outer sheath made of polymer material
flame-retardant, low smoke, zero halogen
(LSZH).
The cable is designed for horizontal and vertical
installation inside and outside of buildings in
special boxes.
Operating temperature of the cable: -40°C to +50°C.
23. 23
FIBER OPTIC INDOOR CABLE
WITH DIRECT ACCESS TO FIBER (RISER)
1. Tight Buffered fiber;
2. Fiberglass rods;
3. Outer sheath made of polymer
material flame-retardant, low
smoke, zero halogen (LSZH).
1. Optical fiber;
2. Micro loose tubes;
3. Fiberglass rods;
4. Outer sheath made of polymer material
flame-retardant, low smoke, zero halogen
(LSZH).
Indoor distribution optical cable with direct
access to fiber containing up to 24 optical
fibers in Tight Buffer sheath or up to 288 optical
fibers in micro loose tubes, with outer sheath
made of polymer material flame-retardant, low
smoke, zero halogen (LSZH).
The cable is designed for vertical installation
inside of buildings.
Operating temperature of the cable: -10°C to
+50°C.
24. 24
1. Optical fiber
2. Strength members
3. Outer sheath
4. External strength member
AERIAL DISTRIBUTION OPTICAL
FIBER CABLE
Optical cable with external strength
member made of galvanized steel wire or
fiberglass rod. Optical fibers are in the
center of the cable, the outer sheath is
made of flame retardant polyethylene with
two strength members inside (fiberglass
rods or galvanized steel wires).
Cable is designed for suspension and
operation on aerial communication lines
and street lighting poles, urban transport
contact network , supports broadcasting
network, for installation inside and outside
of buildings.
Operating temperature of the cable for
outdoor installation: -60°C to +70°C.
25. 25
1. Optical fiber
2. Strength members
3. Outer sheath
FIBER OPTIC INDOOR CABLE (DROP)
Indoor fiber optic cable. Optical fibers are
in the center of the cable, the outer sheath
is made of flame retardant polyethylene
with two strength members inside
(fiberglass rods or galvanized steel wires).
The cable is designed for suspension and
installation in special boxes outside and
inside of buildings.
Operating temperature of the cable for
outdoor installation : -60°C to +70°C.
26. 26
COMBINED OPTICAL CABLES
"Moskabel-Fujikura" produces combined optic cables:
• Suspended optical cable with external power element
with aluminum core and with copper cores
• Optical cable for pneumatic installation in tubes with
copper cores
• Optical cable for duct installation with copper cores
• Optical cable for installation in ground with copper cores
27. 27
COMBINED OPTICAL CABLE
OPTICAL CABLE COMBINED WITH THE INSULATED ALUMINUM
ALLOY CONDUCTOR
Application:
Fiber-optic cable of loose tube design combined with the conductor, for suspension
on overhead lines with a nominal voltage of 10-35 kV in different areas including sea
coasts, salt lakes, in industrial areas and areas with salinized sands.
1. Insulated aluminum alloy conductor as a external strength member.
2. Central strength member.
3. Optical fibers in loose tubes filled with hydrophobic compound.
4. Loose tubes are stranded around central strength member forming cable core.
Optical fibers are placed inside loose tubes. Interstice between loose tubes is
filled with hydrophobic compound. Insulating tapes are imposed on the cable
core.
5. Outer XLPE sheath.
28. 28
OPTICAL CABLE COMBINED WITH THE
INSULATED ALUMINUM ALLOY CONDUCTOR
Parameters of FOC Measurement
units
Value
Number of fibers Pcs. from 2 up to 432
Nominal tention kV from 10 up to v 35
Nominal frequency Hz 50
Tensile Strength N ≥13000
Permissible crushing load N/100 mm ≥ 3000
Resistance to a single impact J. ≥ 30
Operating Temperature °С -60 to +70
Installation Temperature °С ≥ -20
The bend radius at maximum load - 20 х cable diameter
TECHNICAL DATA
29. 29
1. External strength member made of the fiberglass rod or steel wire rope,
or aramid yarns or steel wire .
2. The outer sheath of high density polyethylene.
3. Hydrophobic compound.
4. Insulated copper conductors.
5. Optical fiber.
6. Hydrophobic compound.
7. Loose tube.
8. Central strength member made of the fiberglass rod.
COMBINED OPTICAL CABLE
Application:
Cables are designed for suspension and operation on aerial
communication lines and street lighting poles, urban transport contact
network , supports broadcasting network.
COMBINED OPTICAL CABLES WITH COPPER CONDUCTORS
SUSPENDED
30. 30
COMBINED OPTICAL CABLES WITH
COPPER CONDUCTORS
Parameters of FOC Measurement units Value
Number of fibers Pcs. от 2 до 384
Number of conductors Pcs. От 2 до 4
Tensile Strength N ≥ 2700
Permissible crushing load N/100 mm ≥ 3000
Resistance to a single
impact
J. ≥ 10
Operating Temperature °С -60 to +70
Installation Temperature °С -30 to +50
The bend radius at
maximum load
- 20 х cable diameter
TECHNICAL DATA
31. 31
INTEGRATED SUPPLY SERVICES
Moskabel-Fujikura provides customers with comprehensive service supply
a wide range of additional equipment for the construction of Fiber Optic
Lines (FOL):
• Passive and active equipment for commutation.
• Instruments, tools and equipment for the installation and monitoring of
FOL.
Measuring
equipment
Equipment for
FTTH
networks
Splicers and
cleavers for
optical fiber
Fastening for
areal cables
Optic splice
closures
Optical
Distribution
Frames
Optical
cords
Fiber-
optical
cable
32. 32
FIBER OPTIC SPLICE
CLOSURE
Moskabel-Fujikura supplies high
quality fiber optic splice closures
by TyCo Electronics (Belgium):
End and Straight-through
With 1 and up to 112 trays
Up to 1152 optical fibers
With possibility of splitter
modules mounting with various
splitter configurations
33. 33
ACCESSORIES FOR AERIAL FIBER
OPTICAL CABLE
Moskabel-Fujikura supplies wide range of
fittings for optical fiber aerial cables:
Anchor staining clamps
Suspension clamps
TG/LG suspension rods
Suspension pulleys with helical rods
AG helical dead ends
Thimbles
Vibration dampers
UTA protection rods
Armor grip suspension clamps
Spiral basin suspension clamps
Brackets
Tools for capturing, cable tension, to
install the steel tape, steel tape and
locks, and many others.
34. 34
OPTICAL CONNECTORS, PIGTAILS, OPTICAL
DISRTIBUTION FRAMES
Optical Distribution Frames equipped with the necessary
elements for termination, stacking and distribution of
optical cables.
Wall Mount and Rack Mount, from 4 up to 288 adaptors
Optic cords to connect the active and passive equipment,
on the basis of a single-mode and multimode fiber.
Simplex and Duplex Cable Assemblies with FC, SC, LC
single fiber connectors, cord sizes diameter 0.9mm, 2mm,
3mm.
Moskabel-Fujikura supplies:
35. 35
OPTICAL FIBER FUSION SPLICERS AND
CLEAVERS
Fusion splicers by FUJIKURA (Japan) FSM-80S
designed for splicing of all types of optical fibers – SM, MM,
DS, NZDS, CS, G.657.
Has a high level of protection against dust and moisture,
Not afraid of bumps and falls.
Operating temperature: -10°C to +50°C.
Fusion splicers by SUMITOMO TYPE-71C with a touchscreen
designed for ultra-fast optical fiber connection in the local and
trunk lines of communication.
Compact and lightweight, designed to work with different
types of optical fibers (MM, SM, DS, NRZ, G.657 (A,B)).
Durable and reliable (preserves the integrity when falling from
a height of 0.76 m).
36. 36
TEST EQUIPMENT
Moskabel-Fujikura offers measuring equipment
of the company EXFO - a leading supplier of
equipment for testing of optical and copper
networks, supporting 3G, 4G/LTE, IMS,
Ethernet, OTN, FTTx ant the other optical
technologies:
Multifunction measuring platforms for fast,
efficient testing of optical networks
Optical testers for measuring optical loss in
the fiber optic lines
The radiation sources
Power Meters
OTDR modules for measurements in both
local and in the trunk fiber optic lines
OTDRs
37. 37
The Stock Company “Moskabel-Fujikura”
Address: 2-nd Kabelnaya str., 2, bld.2, Moscow, 111024, Russia.
Tel.: +7 (495) 673-83-15; 728-72-10; 728-72-05
Fax: +7(495) 728-72-09
E-mail: mk-f@mk-f.ru
www.mk-f.ru
THANK YOU FOR
ATTENTION!