Industrial optical communication solutions from TOMOR
Custom networking and fiber solutions for industry

Understanding Concrete Cold Joints Causes,

Browse technical resources about industrial optical communication, fiber switches, Ethernet over fiber, and networking solutions.

  • New Smart Cold Aisle Model

    New Smart Cold Aisle Model

    SmartAisle™ provides always uniform and predictable temperature to all IT equipment controlling directly cold aisle temperature and humidity. The SmartAisle offering optimizes infrastructure deployment and management with an intelligent row-based system that integrates data center racks, power, row cooling, aisle containment, monitoring and control technologies for spaces with up to 40 racks. In recent years, there has been no greater. Freestanding, Rack-independent system with the flexibility to maximize efficiency and capacity from the core to the edge for raised floor and slab data centers. Adaptable to hot and cold aisle containment, the Vertiv Aisle Containment system allows you to deploy containment before or after racks. Eaton's SmartRack Aisle Containment System is an easy-to-assemble structure designed to keep hot and cool air separated for better temperature control and equipment performance in hot aisle/cold aisle configurations.

    [PDF Version]
  • Advantages of cold aisle in computer room

    Advantages of cold aisle in computer room

    Advantages: Maintains a more comfortable overall room temperature and uses the room as a cold air buffer, providing more response time in case of air conditioning failure. In hot aisle containment, the hot aisle is enclosed instead. Advantages Disadvantages The main distinction comes down to where airflow is controlled. In modern data centers—especially those with high-density loads— hot aisle. Cold aisle containment is typically going to be easier to retrofit in an existing data center, particularly when there are overhead obstructions to circumnavigate, such as power and network distribution, ducts, lighting. LED solutions like the Budget High Bay Light from CAE. Advantages: Generally lower implementation cost; suitable for retrofitting older data centers. This method channels hot exhaust directly. An inefficient cooling strategy can lead to hotspots, equipment failures, increased operating costs, and a higher carbon footprint.

    [PDF Version]
  • Causes of damage to network cables and fiber optic cables

    Causes of damage to network cables and fiber optic cables

    Despite their robustness, fiber networks can fail due to: Physical Damage : Cuts, bends, or contamination in fiber cables or connectors. Fiber-optic cables are the backbone of modern connectivity—powering 5G networks, global internet backbones, and data center interconnections with near-light-speed data transmission. While these cables are engineered for durability (with some rated to last 25+ years), they are not invulnerable. However, in real-world installations, whether underground, aerial, or in harsh industrial environments, fiber cables can and do fail. Hardware Failures : Faulty transceivers, switches, or routers. Physical damage, signal loss, and contamination are common issues requiring professional repair. Every fiber optic cable installer or a company that deals in optical installation needs to know the reasons behind reasons which can damage fiber cable. This blog will cover the most common reasons of damage and suggest how to prevent them.

    [PDF Version]
  • Causes of Dispersion in Optical Cable Polarizing Film

    Causes of Dispersion in Optical Cable Polarizing Film

    In an ideal optical fiber, the core has a perfectly circular cross-section. In this case, the fundamental mode has two orthogonal polarizations (orientations of the ) that travel at the same. The signal that is transmitted over the fiber is randomly polarized, i.e. a random superposition of these two polarizations, but that would not matter in an ideal fiber because the two polarizations would propagate identically (are ).


  • Analysis of the causes of heat generation in fiber optic panels

    Analysis of the causes of heat generation in fiber optic panels

    In this work, we analyze the thermal effects occurring in optical fibres, such as the coating heating due to high power propagation in bent fibres and the fibre fuse effect. Thus, the conjugation of high power propagation and tight bending, resulting from the actual FTTH infrastructures, is responsible for fibre lifetime reduction, mainly caused by the local increase of the coating temperature. It discusses the historical context and recent advancements in understanding these thermal phenomena, alongside. This paper investigates the thermal effects in fused-tapered passive optical fibers under near-infrared absorption. Using the finite element method, the volume changes during fiber.


  • Tin plating technology for air-type busbar joints

    Tin plating technology for air-type busbar joints

    The Tin-Plated Copper Busbar uses T2/TU1 electrolytic copper as the base material, with a 5-15 µm pure tin layer deposited through fully automated continuous electroplating. The tin layer isolates air and sulfurous gases, enhancing oxidation resistance and extending service life. Tin plating is a common coating applied to a large variety of copper products including busbars, electrical terminals, battery connectors or any other copper component used in the passing of current.


  • Loss of fiber optic cable fixing joints

    Loss of fiber optic cable fixing joints

    Fiber splice loss measures how much signal drops when you join two fiber ends. Many factors, like core mismatch and contamination, can increase splice loss. Optical fibers can be joined together, such that light is efficiently transferred from one fiber to another. This method is typically used for permanent connections. To be able to judge whether a fiber optic cable plant is good, one does a insertion loss test with a light source and power meter and compares that to an estimate of what is a reasonable loss for that cable plant. Modern fiber optic networks usually keep splice loss. Employing these fibers in lightwave systems requires precise jointing devices such as con­ nectors and splices. Considering the small size of the fiber cores, less than 10 11m in diameter for single-mode fibers and less than 100 11m for multimode fibers, it is not surprising that these components.

    [PDF Version]

More industry information

Contact Us

We Look Forward to Working with You

Contact Information

Phone +49 69 2381 5497
Address Am Hauptbahnhof 10, 60329 Frankfurt am Main, Germany

Send an Inquiry