A span clamp is also known as a suspension clamp or mid-span clamp. It works on power lines to support and stabilize conductors between two suspension poles. It installs at intermediate points along the power line span. This helps to maintain proper tension and prevent excessive sagging of the conductor. It holds the conductor in place while allowing some degree of movement to accommodate thermal expansion and contraction. The span clamp distributes the weight of the conductor evenly on the power lines. They have a vital role of maintaining the structural integrity, tension and alignment of power line conductors.
Components of span clamp used on power lines
The design and configuration of the components vary among different span clamp models and manufacturers. It is also recommended to consult the specific product documentation or manufacturer’s guidelines for detailed information on the components. Discussed below are the major components of the span clamp.
- Clamp body – the body or frame of the span clamp provides the structural support and housing for the other components. It is from durable materials to withstand environmental conditions.
- Gripping elements – span clamps have gripping elements that securely holds the conductor in place. The elements include grooves, serrations or specially designed surfaces. They provide grip without damaging the conductor.
- Fasteners – span clamps utilize bolts and secure the conductor and maintain the grip. The fasteners include bolts, nuts and washers made from corrosion resistance materials.
- Insulators – insulators provide electrical insulation between the conductor and the clamp. They help prevent any electrical contact or arcing between the conductor and the clamp.
- Tensioning devices – some span clamps incorporate the tensioning devices or mechanisms to adjust the tension in the conductor.
- Attachment points – the devices have attachment points that allow for connection to the support structure like suspension points or holes. They enable the secure installation of the span clamp along the power line span.
- Accessories – span clamps may include additional accessories like vibration dampers or protective covers. This depends on the specific design and requirements. They help mitigate vibrations, reduce wear and tear and protect the clamp and conductor from environmental factors.
Types of span clamp used on the power lines
The types of span clamps depend on the on the regional standards, voltage levels and conductor types. Different power companies may choose their preferred types of clamps based on their specific requirements and regulations. The following are the main types of span clamps used on the power lines.
- Parallel groove clamps – these help to connect two types of conductors in parallel. This helps to maintain proper spacing and electrical continuity between them.
- Suspension clamps – suspension clamps suspend conductors between support structures like poles or towers. They also provide vertical support and allow for some movement. This also helps to accommodate thermal expansion and contraction.
- Guy wire clamps – these help to secure guy wires which provide extra support and stability to power structures. They work with guy wires to anchor and brace the structures.
- Strain clamps – strain clamps provide tension and strain relief for conductors at the termination points. They work at the ends of a span where the conductor changes direction.
- Armor rods – armor rods are not technically a clamp but they work with suspension clamps and strain clamps. They wrap around the conductor to prevent abrasion and damage from the clamp’s gripping action.
- Dead end clamps – these clamps terminate the conductor at the ends of a power line. They securely hold the conductor in place to provide mechanical and electrical continuity.
Application of span clamps
Span clamps have a crucial role in maintaining the structural integrity, tension, and alignment of power line conductors. This is through distributing the weight of the conductor and preventing excessive sagging. The clamps also contribute to the overall reliability and performance of the power transmission and distribution system. The following are the common applications of the span clamps.
- Overhead transmission lines – span clamps support the conductors between suspension point or towers. This helps maintain the proper tension and prevent excessive sagging. It also ensures reliable power transmission over long distances.
- Distribution lines – distribution lines support and stabilize the conductors between poles. They also maintain proper clearance and prevent unnecessary strain on the conductors.
- Fiber optic cables and communication lines – span clamps work in communication lines installations like fiber optic cables and telephone lines. They also provide support and stability for communication cables ensuring uninterrupted transmission of signals.
- Railway electrification – span clamps work in railway electrification projects to support and stabilize overhead contact wires. They help maintain the desired tension and alignment of the wires which ensures reliable power supply to electric trains.
Installation of the span clamps
Many of the manufacturers in the market provide detailed guidelines on how to use the devices. You may also consult with professional electricians on how to go about the installations process and what devices to use. Below are the steps followed when installing a span clamp on power lines.
- Evaluate the power line span and identify the appropriate locations for installing the span clamp. You should also consider the length of the span, conductor type and size and the desired tension and sag parameters.
- Make sure the conductor is clean and free from contaminants that may affect the grip of the span.
- Install the span clamps at the desired location along the power lines where the spacing depends on the conductor type, size and sag requirements.
- This is positioning the conductor within the gripping elements of the span clamp. Ensure that the conductor centers properly and aligns for optimal grip and performance.
- Secure the span clamp by tightening the bolts or fasteners provided to ensure a secure and reliable connection.
- Visually inspect the clamps to ensure they are securely fastened, aligned correctly and free from defects. Conduct performance tests to ensure the clamps are functioning as intended.
Choosing the best span clamp for power lines
There are various types of clamps and different manufacturers in the market which can make it hard to know the best clamp to use. The selection of the best span clamps involves a series of factors to consider before purchase. Below are he factors to consider when selecting a spa clamp for power line projects.
- Assess the specific needs of a power line project like voltage level, conductor types and the function of the clamp.
- Ensure that the span clamp is compatible with the conductor size and shape. It helps to securely hold and support the conductor without causing damage.
- Assess the load capacity of the span clamp to ensure it can handle the expected mechanical loads.
- Consider the electrical conductivity requirements to provide good continuity and minimize resistance.
- Evaluate the environmental conditions like humidity, salt spray or chemical exposure and select a clamp with resistance.
- Check the local regulations and industry standards for power line construction and maintenance.
- Consider the reputation and record of the manufacturer for high quality and reliable span clamps.
- Consult with power line engineers if you are unsure about the best clamp for your installation.
Frequently asked questions
Span clamps are devices used on the power lines to support and stabilize conductors between two suspension poles.
There are several types of span clamps used in the overhead transmission systems. They include strain clamps, dead end clamps, guy wire clamps, suspension clamps, armor rods and parallel groove clamps.
Span clamps offer several benefits that make them popular in the transmission industry. These benefits include secure conductor support, flexibility and movement, ease of installation, good electrical continuity, corrosion resistance and safety of power lines.
They also have various limitations to consider when planning to purchase for your application. They include complexity in construction and maintenance, increased costs, potential corrosion, frequent inspection, compatibility and interoperability, limited adjustment range and environmental implications.