Cable Blowing Machine comprising of an Air Container

The Cable Blowing Machine comprising of an Air Container, Cable pusher and Hydraulic Power Pack, has been designed to offer an powerful and secure method of Fiber Optic Cable Installation.  The Machine installs fiber optic cable of 8 – 32 mm overall diameter at up to 90m/min into pre-installed ducts, employing the viscous drag compressed air principle.

The compressed air is fed into the duct through a venturi principle, and the hydraulically powered cable feed system controls the fiber optic cable.

The machine comes mounted on a light weight frame for ease of site maneuverability and is powered by a hydraulic supply system.  The unit is supplied with a 1-1/2”BSP for connecting air supply hose (not supplied).  The air supply hose should be 25mm (min) bore or more.

The unit is supplied with 2 x hydraulic hoses x 3 meters for connecting between the Fiber Cable Blowing Equipments and hydraulic power pack (or hydraulic power source).

Fiber Optic splicing machine is used for joining two optical fibers end-to-end using heat, to fuse the two fibers together in such a way that light passing through the fibers is not scattered or reflected back by the splice.  Fusion Splicers are used to connect optical fibers with high precision to ensure data is transmitted reliably anywhere.

Fusion Splicing Machine is a tough fiber optic cable joint machine with an auto heater and integrated cooling tray.

Perfect for use in Industrial plants, Campus networks, Telecom and Railway network project and maintenance.

The Prayaag Technologies fiber optic joint machine are the most rugged equipment’s in the industry - splice time of 8 seconds and tube heating time of 24 seconds -designed to be use by any level of operator in any site conditions.

With the rapid improvement in Fiber Optic Technology, OTDR testing methods have become essential to building, certifying, maintaining and troubleshooting fiber optic systems.

An OTDR (Optical Time Domain Reflectometer) is an Optoelectronic device used to create a virtual “picture” of a fiber optic cable route. The analyzed data can provide insight into the integrity of the fibers, as well as any passive optical component such as the connectors, splices, splitters and multiplexers along the cable path.

Once this information has been captured, analyzed and stored, it can be recalled as needed to evaluate the degradation of the same cable over time.

The OTDR is also the only tool capable of troubleshooting any fiber optic cable failures by locating the distance to the fault and identifying the type of fault-like breaks, bends, bad connectors and any excessive loss.  An OTDR device can be a portable tool or it can be rack-mounted and placed for permanent monitoring in the network such that an alarm can be triggered if the fiber is compromised.