Suspension support cable and its tension is done in two steps. First, the cable is pulled along the length of the wiring and one end is secured to the end anchor structure, the tension bolt of which is previously loosened. The second free end of the cable is measured according to the actual length of the line, taking into account the length of the cable required for sealing loops, installing tension devices and compensating the sag, and connects it to a pre-weakened special tension device, if necessary. Then they create a preparatory tension of the supporting cable together with a tensioning device, which is put on the 2nd end anchor hook. The tension of the supporting cable, depending on its length, is carried out manually at small gaps, and with the use of blocks, pulleys or winches at large gaps.
As already indicated, the cable tension should be created until the calculated sag is obtained, but with a force not exceeding the tension force permissible for a given load-bearing cable. Monitoring the correct tension of the supporting cable is carried out by a dynamometer, connected alternately with the cable of the pulley block or block, with the help of which the tension of the cable is created, or by measuring the sag. The final tension and adjustment of the supporting cable is created by tightening previously loosened tension devices. It is recommended to carry out work on hanging and tensioning load-bearing cables at an ambient temperature of at least -20 degrees Celsius.
To unload the supporting cable and its end fastenings and reduce the sag in the cable runs, various unloading devices are used in the form of additional vertical, longitudinal and transverse auxiliary wire hangers and guy wires.
To make the cable wiring more immobile and to prevent lateral swings, side braces are installed.
Vertical wire hangers are installed approximately every 3 -12 m, placing them in the locations of branches from wires and cables, installation and suspension of branch boxes, branches and lighting fixtures.
Vertical wire hangers are made from metal wire with a diameter of 2-6 mm for power lines that are heavier in weight and with a diameter of 2-3 mm for lighter-weight lighting lines.
Longitudinal lateral and transverse guys are made of metal wire with a diameter of 2 - 6 mm.
For string electrical wiring, unlike cable wiring, the supporting string in a tense state is attached tightly to floors, trusses, supports, walls and protruding parts of walls, columns and others construction grounds using different methods.

Figure 12.7 – End fastening structures of cable wiring and methods of their installation:
c - tension bolt with hook, b - cable tension anchor, "- anchors for end fastening wire strings secured with studs, pins, dowels, and electric welding, d - cable anchors for end fastening of factory-made steel cables, e - structures for fastening cables and wires to metal trusses made of profile steel and T-beams, f - structure for fastening parallel load-bearing structures cables

As load-bearing elements, hangers of guy wires are used: steel rope (cable with a diameter of 1.95 - 6.5 mm, galvanized steel wire with a diameter of 2.5 - 6 mm, round hot-rolled wire (rod) with a diameter of 5 - 8 mm, bare galvanized steel wire with a diameter of 6, 8 and 7.5 mm, twisted from ordinary steel or copper-plated steel wires, a rope that serves simultaneously as a support cable and a neutral wire.
During the process of procurement work, hangers and branch clamps for aluminum and copper wires and boxes for wires of the ANRG brand, make the necessary connections and descents to connect the wiring to the supply line.

Figure 12.8 – Products and parts for installation of cable wiring:
a - box for branching from main lines, 6 - cross-shaped and tee compression, c - ram compression, d - suspension with plastic clips, e - steel suspensions, e - strip with a buckle and a strip-buckle for banding wires and cables; 1 - strip for fastening the branch box, 2 - box body, 3 - clamp, 4 - dies, 5 - suspension brackets, 6 - eyelet for fixing the lamp

For branches from main lines made with three- and four-core wires of the APT brand, a branch box is used (Figure 12.8, a), which can be of three types: 0.2 - for lighting networks with a core cross-section of main wires of 4-10 mm2 and branch wires of 1-2.5 mm2; C2 - for lighting and power networks with a cross-section of main and branch wires of 4-10 mm2; SZ - for power networks with a cross-section of main wires of 16-35 mm2 and branch wires of 4-10 mm2.

Branches from main aluminum and copper wires are made using cross-shaped and tee clamps (Figure 12.8, b). For branches of wires with a cross-section of 6, 10 and 16 mm2 from the wires of main lines with a cross-section of 35 and 50 mm2, die clamps are used (Figure 12.8, c).

To hang four insulated wires with a cross-section of up to 6 mm2 and lamps from a cable with a diameter of 4-7 mm, a plastic hanger U930-U934 is used (Figure 12.8, d), and for a cable on a cable with a diameter of up to 10 mm, a steel hanger U954-U956 is used (Figure 12.8, d). d).

Banding of wires and cables is performed with a steel strip with a buckle or a buckle strip (Figure 12.8, e).

3 Methods of fastening cables

At the second stage of installation, the prepared sections and assemblies of cable wiring are assembled into a common strand and suspended on tension devices and supporting structures installed at the first stage of installation.
The prepared cable wiring delivered to the installation site is unwound and straightened, while simultaneously checking its condition and completeness. If the wiring is added in the form of separate sections and nodes, they are assembled into cable strands, and then the finished wiring is suspended in place. The assembly and suspension of cable wiring is shown schematically in Figure 3.
To assemble and suspend electrical cable wiring, one end of the supporting cable (right in Figure 3) is terminated with loop 1 and thrown onto a temporary right anchor hook 2, installed at a height of 1.5 m. The second temporary anchor hook 2, located on the opposite wall of the room, is thrown a loop of one end of the pulley 8, and a wedge clamp 5 is attached to the free end of the pulley, which grips the cable at some distance from the end loop of the supporting cable. In this case, the free (in Figure 3 left) end of the cable and the tension coupling 9 mounted on it will be in a suspended position. The supporting cable suspended between temporary anchors, together with the electrical wiring elements attached to it, is pulled with a pulley until the required sag is formed. The tension value of the supporting cable is controlled by a dynamometer located between the pulley and the wedge clamp.

Figure 3 – Scheme of assembly and suspension of cable wiring at the installation site: 1 and 1" - end loops on the supporting cable, 2 and 2" - temporary and permanent anchors, 3 - inventory stands, 4 - string of cable wiring, 5 - wedge clamp, 6 - auxiliary section of cable, 7 - free end of the supporting cable, 8 - pulley block, 9 - tension coupling, 10 - dynamometer, 11 - vertical wire hangers

The forces when tensioning the cable of ATRG wires should not exceed: 100 kgf for cable wires with a core cross-section of 4-10 mm2; 500 kgf - for wires with a core cross-section of 16-35 mm2.

After tensioning the electrical cable wiring is completed, the free end of the supporting cable with the tensioning device is put on the left anchor hook 2, the pulley 8 is loosened and removed from the hook. Next, inventory stands 3 are installed under the cable, supporting the electrical wiring at a height convenient for work.

At the final stage of installation, the lamp housings are suspended and secured on a cable, but without glass parts (reflectors, glass caps, etc.), and the height of the wiring suspension is adjusted (by changing the length of the pendants 11). anchor fastenings, and also perform a number of other installation operations.

The assembled string of electrical wiring is lifted, connected to anchor fasteners and a tensioning device, tensioned using tensioning devices, the vertical wire hangers are finally adjusted and secured, lamps are installed in the lamps and reflectors and caps are secured in the lamp bodies, the correctness is checked relative position all electrical wiring parts.

In accordance with the requirements of the PUE, elements of cable wiring (supporting cable, lamp housings, cable sheaths, etc.) must be grounded. To ground the cable wiring, its fastening structures and the supporting cable are connected to the grounding busbars using flexible jumpers made of steel cable with a diameter of at least 5 mm or stranded copper wire with a cross section of at least 2.5 mm2.

If a support cable is used as a neutral or grounding wire, the cross-section of the jumper must correspond to the calculated cross-section of the neutral or grounding wire.

Grounding is done like this. Cut a piece of cable or flexible copper wire of the required length and required cross-section for use as a grounding jumper. A steel sleeve or flag is welded to one end of the jumper, which, in turn, is welded to the grounding bus. The opposite free end of the jumper is connected to the supporting cable using a bolt clamp.

Metal support and cable structures grounded by securely connecting them to the supporting cable.

Cable electrical wiring made with ATRG wires is grounded, connecting the section of the carrier millet freed from insulation with the body of the branch box, inside of which there is special device.
In lighting installations with a solidly grounded neutral, the neutral wire and lamp housings are also connected to the anchor device of Special boxes or to the neutral wire in ordinary boxes. In this case, the electrical wiring together with the supporting cable is grounded through the neutral wire of the lighting network.

Metal housings of lamps in cable wiring with open gasket wires are grounded using separate grounding insulated copper conductors with a cross-section of at least 1.5 mm2. The ends of the grounding conductors are connected to the lamp housings under the grounding screws, and to the neutral wire or to the supporting cable (if one is used as a neutral wire) - by soldering or mechanical compression.

In cable wiring with open laying of protected wires and cables, grounding of lamps is performed using an additional core included in the design of the cable and wire. In these cases, the grounding conductor is connected not to the neutral wire in the branch box, but to the luminaire body - inside or outside it, depending on the design of the luminaires.

Upon completion of installation of cable wiring:
- measure the insulation resistance of the wires and cables of the cable wiring with a 1000 V megger with the fuse links removed and the lamps in the lighting circuits unscrewed, but with the switches connected, plug sockets and group shields; insulation resistance must be at least 0.5 MOhm;
- determine the correct phasing of cable wiring and branches from it; the phases must match;
- check the condition of the insulation of the current-carrying conductors of wires and cables in relation to the supporting cable, as well as the continuity of the grounding circuit: cable - branch box - grounding conductor.
If the results of the checks are satisfactory, the cable wiring is transferred for operation.

To connect the ends of a cable or rope, as well as to form loops at the ends, they are used different varieties steel, copper or aluminum clamps. Relating to rigging fasteners, cable clamps are used in elevator facilities, when carrying out various installation work, as well as in everyday life.

Types of clamps

To ensure durability and reliability, everything structural elements Clamps are made of stainless steel, and for light operating loads - also of copper, brass or aluminum.

The most popular are:

Horseshoe type cable clamp, manufactured according to DIN 741 standard. Made only from galvanized or of stainless steel, include a U-shaped threaded stepladder, a washer-plate for the cable loop, a block with a cable socket and two nuts. Such clamps are used for relatively small loads, mainly when transporting or towing cargo or equipment.

Simplex single clamps, which consist of a steel plate with flanges at the edges, and a steel clamping plate located between the plate and the cable. To fasten the elements together, Simplex type clamps have a bolt and a nut. This design is more intended for connecting the ends of the cable to each other when splicing it.

Double type or Duplex cable clamp. The principle of operation remains the same as in the previous type of clamp, but the pad and plate are twice as long, which allows you to place a second bolt-nut fastening pair. Accordingly, the reliability of the double grip increases, as does its size.

A “barrel” type clamp, which consists of two somewhat flattened hollow half-cylinders, which are connected to each other using a screw (one half-cylinder has a threaded boss, and the second has a hole for the screw). In the end parts of each half-cylinder there are two semicircular grooves for passing the cable and forming a loop.

Wedge clamp. It is a specialized type and is suitable for connecting rigging cables or ropes large diameter(up to 100 mm). Wedge clamps are different increased wear resistance, since bushings made of antifriction bronze are used for connection, and washers made of soft aluminum are used to securely grip the cable or rope.

Features of using different types of cable clamps

Main technical parameters of the products under consideration are the maximum cable diameter and the guaranteed clamping force. The dimensions of the clamp are also important, since it is recommended, regardless of the type, to use several clamps in series (at least three), especially if the weight of the load does not guarantee its safe movement or lifting.

Clamps according to DIN 741 are used for ropes with a diameter of 5...62 mm, in the presence of a spring washer in accordance with GOST 6402-70 and a nut in accordance with GOST 5915-70. The design of this clamp allows for the installation of a locking bar, which provides more reliable clamping of the cable to the bracket. The clamping block must be made by stamping from steel grade no lower than St.3kp in accordance with GOST 380-94 (only for small clamping forces cast blocks made of steel 25L in accordance with GOST 977-75 are allowed). It is not allowed to use cable clamps whose parts do not have a protective anti-corrosion zinc coating.

IN fasteners flat clamps thread according to GOST 24705-81 must be used. The material of the linings is steel St. 3, the plates should be used for fastening cables with a diameter of 4.6...30 mm.

If several clamps are used in series, the distance between them should not be less than six cable diameters.

In Duplex type double clamps, the shear force is absorbed solely by the bolted connection, so the choice of fastener diameter is determined by the diameter of the cable. The following ratios are recommended:

• For cables with a diameter of 2 mm and 3 mm - M4 fasteners;
• For cables with a diameter of 4 mm and 5 mm - M5 fasteners;
• For a cable with a diameter of 6 mm - M6 fasteners;
• For a cable with a diameter of 8 mm - M8 fasteners;
• For a cable with a diameter of 10...12 mm - M10 fasteners.

Wedge clamps are not recommended for lifting loads. Because the operational loads on the fastener are reduced, since the axes of force during operation of such a clamp coincide, and, therefore, shear stresses do not arise. The operational parameters of wedge-type clamps are regulated by DIN 15315. For screw clamping of a cable or rope to the supporting surface of the wedge, high-strength fasteners are used (strength class not lower than 5.6), with a protective anti-friction coating. The connection needs to be tightened periodically.

The barrel clamp is often made of aluminum, and is not designed for large cable diameters: the rational range of diameters is 2... 8 mm. The absence of protruding elements and the compactness of this clamp allows it to be used in cramped spaces.

Is it possible to make a cable clamp with your own hands?

The price of clamps, depending on their size and permissible load capacity, is, rub/piece:

• For Simplex type clamps - 4…14;
• For Duplex type clamps – 7…24;
• For clamps according to DIN 741 - 4…160;
• For wedge clamps – 200…250;
• For barrel type clamps - 3...40 (made of aluminum), and 60...160 (made of stainless steel).

In everyday life (for example, for car enthusiasts), there is often a need to make a cable clamp with your own hands. To form a reliable loop, it is advisable to use a regular aluminum (not duralumin!) tube, into which the cable should fit freely required diameter. The tube is bent in an arc, after which a cable is inserted there at a distance of 120...150 mm, its ends are covered with staples, and connected with a bolt.

When building up parts of the cable, the diameter of the pipe is chosen so that both cables can fit in freely, and from different ends. All other actions are performed in the same way. It should be noted that load bearing capacity such a cable clamp will be determined by the bending strength of the pipe material, so the permissible force homemade device the clamp will be noticeably lower than that manufactured by a specialized enterprise.

Installation of cable wiring

Installation of electrical wiring is carried out in two stages.

At the first stage in the workshop they prepare electrical wiring elements, complete anchors, tensile structures and supporting devices.

Measuring the cable required length and “charge” one end of it into the lanyard ring, at the other end they make a loop under the hook or close it on the lanyard if tension couplings are used on both sides. The cables are connected to the end fasteners by installing a loop at the end of the cable. different ways, for example, using the so-called thimble and bolt clamps.

Drawing. Making the end loop of the cable: a – cable termination diagram; b – thimble; c – bolt clamp-clip.

The sequence of operations to complete the loop is as follows.

The cable is looped around the thimble and a clip-clip is attached to the end of the cable (stage 1). The second clamp is attached as close to the thimble as possible (step 2). Install the remaining clamps between the first two (step 3), while tightening the clamp nuts with force, but not tightening them completely. [ Total clamps in the loop is determined by the calculated pulling force of the cable, which in turn depends on the length of the cable wiring span, the mass and number of electrical products attached to the supporting cable.] If a “slack” of the cable has formed between the clips, then it is eliminated by tensioning the end of the cable that goes around the thimble , and then finally tighten the clamp nuts.

Drawing. Bolt clamp K676 for making the end loop of the support cable

Below are several videos that show the principle of making an end loop on a support cable using various clamps.

Drawing. Making a loop on a support cable using a pressed sleeve

The sequence of operations is as follows. The cable is threaded into the sleeve with a loop so that its end protrudes from the sleeve by 1-2 cm. Next, the sleeve will be crimped using a special tool - a press (manual, electric, hydraulic), having previously selected a matrix for it (the size of the matrix depends on the type of sleeve, used for crimping). Crimping begins from the middle of the sleeve, then crimping is performed from the edges of the sleeve. After crimping is completed, its quality is checked using special templates.

You can make the end loop of the support cable without using special devices(clamps, sleeves, etc.) and tools. In this case, the end of the cable is woven in a special way into the main part of the supporting cable. It should be noted that making a loop using this method requires much more time.

If steel wire or rod rod is used as a cable, loops at the ends are made without the use of clamps, by simply twisting the wire into a spiral at a length of 60-80 mm.

In addition, execute end seal the support cable can also be installed without organizing a loop, using special tips mounted on the cable by crimping. An overview of these mounting products, as well as an example of how to terminate a support cable, is shown in the video below.

After completing the end seal of the supporting cable, branch, connection and input boxes are installed on the cable wiring and secured. Pre-measured wires and cables are attached to the supporting cable; the distance between the points of attachment of the cable to the supporting cable should not exceed 50-60 cm.

At the second stage carry out installation of cable wiring to building structures at the installation site. Lamps are attached to the wiring, as a rule, at the second stage of installation, when the cable wiring is unwound on the floor, temporarily suspended at a height of 1.2-1.6 m for straightening the wires, hanging and connecting the lamps (if they were not mounted on the cable line in workshops). Then the electrical wiring is raised to the designed height.

Install the end fastening structures to building elements buildings and structures.

The most reliable fastenings of anchor structures to building surfaces are fastenings in brick and concrete walls and floors using through bolts and through anchors or fastening anchors using through studs with installation with reverse side fastening of enlarged square washers. In anchors with such fastenings, the pulling forces correspond to the actual strength of the material from which the anchor is made, depending on the grade of steel and the cross-section of the threaded part of the fastening rods.

Drawing. Diagram of end fastening using a through anchor bolt

Fastening of anchor structures to walls and ceilings is also carried out using grease-in pins or expansion dowels. Such fastenings are less reliable, since they largely depend on the quality of workmanship and the accuracy of the prepared holes in size and the reliability of embedding anchors in them. Therefore, these methods of fastening anchors are used for less responsible intermediate fastenings load-bearing cables and guy wires.

Drawing. Scheme for performing end fastening using: a – grease-in pins; b – spacer dowels.

Fastening of anchor structures to metal trusses and building structures is carried out using crimped steel fasteners or similar parts, as well as using bolted connections or by welding the anchor along its perimeter using electric welding.

Drawing. Diagram of end fastening to metal elements building structures using: a – crimping steel fasteners; b – welding.

TO wooden bases The tension cable is secured with metal screws and a hook.

In each individual case, the choice of anchor design and method of fastening is made depending on specific local conditions, the material from which the parts of the anchor structures are made, and the compliance of the design with the calculated pull-out force created by the cable wiring.

Drawing. Installation of cable wiring

The suspension of the supporting cable and its tension is carried out as follows. First, the cable is pulled along the length of the wiring and one end is secured to the end anchor structure. Tensioners(turnbuckle, anchor bolts) must first be loosened (so that there would be movement afterward to adjust the degree of tension of the cable). Then the support cable is pre-tensioned. Depending on the length of the span, pre-tensioning is carried out: for small spans - manually, and for large spans - using blocks, pulleys or winches. The cable is tensioned until the calculated sag is obtained, but with a force not exceeding that permissible for a given load-bearing cable. The tension force of the supporting cable is monitored by a dynamometer connected in series with the cable of the pulley or pulley. The final tension and adjustment of the supporting cable is carried out by tightening the previously loosened tensioning devices: turnbuckle (tension coupling), anchor bolts.

The cable sag in spans should be within 1/40-1/60 of the span length. Splicing of cables in the span between the end fastenings is not allowed. To prevent lighting wiring from swinging on steel rope guy wires must be installed.

After tensioning the supporting cable, it is grounded.

When using metal ropes, it may be necessary to fasten them together or form loops at their ends. A steel cable clamp will help you cope with this task effectively. We will describe below what modifications exist and how to use them.

Purpose and design specifics

These devices are made of durable materials - it is thanks to metal that reliable fastening, withstanding increased loads. Structurally, the clamp consists of an arc and nuts.

It is advisable to use several clamps - professionals advise using at least three. However, if the load is excessively high, then it is better to choose other fixation methods and refuse installation large quantity clamps.

High-strength steel is additionally treated with galvanization. Such protective layer protects elements from corrosion and also minimizes the impact of other external factors.

To prevent disengagement and breakage, you should learn how to use the cable clamp correctly. There is nothing complicated about this - just put the ends under the arc and tighten it with nuts. They twist in different directions, and the rope remains in the spaces between them.

The nuts must be tightened until the cable is completely tightened. If a loop is being created, the cut end should be on top, above the whole piece, but directly below the arc. Clamping element– nuts – will be at the bottom.

Classification of devices

You need to select clamps taking into account the specific conditions of their use, the characteristics of the cable used and the planned load. In terms of size, you can choose a wide variety of modifications - they can be small 3-5 mm in diameter, but there are also larger ones up to 40 mm.

Most often used in everyday life conventional designs, which are made from second class steel after galvanization. They have a loop at the base that is clamped with bolts. However, professionals demand reinforced modifications with a more durable shutter. Therefore, they are oriented towards increased load levels.

Steel or copper is used for manufacturing, although in some cases it is permissible to use only an aluminum cable clamp. But galvanized steel will be a more expensive option, but will allow fasteners to be used in harsh climatic zones.

The design also varies - they can be single or double, have a flat or arched design. Flat models have two galvanized steel plates with a diameter of 2-40 mm.

Fastening is done using bolts and nuts. Their use is effective when splicing cables and carrying out other similar manipulations. To connect, you need to install more than two devices.

Double cable clamps are distinguished by the presence of two fixing bolts, while single clamps have only one bolt-nut pair. Their operating principle is almost identical.

The arcuate structure has a cylindrical shape with an arched convexity. There are bolts at the ends that provide fixation. Most often they are used in connecting operations, but fastening a loop is also acceptable. This is an industrial version of fasteners that can withstand a load of at least 97 kg.

The crimp clamp is made from aluminum alloy. It looks like an oval piece of pipe with a slight flatness on both sides. The cable is inserted into this section, and the structure is flattened in two ways:

• impact with a hammer;
• manually by pressing.

Specific types of clamps

Since fastening units in construction experience dynamic loads, and loads often rise to a height, spring mechanisms are used here.

Thanks to them, not only the usual fastening of cables is carried out, but also the fixation of objects. Structurally, they have levers with moving brackets. As a result, the object can be fixed on the cable, regardless of its thickness.

Wedge connections are indispensable for working with copper and aluminum wires with a cross-section of 35-100 sq. mm. They are a body made of cast iron steel with a wear-resistant wedge made of bronze or aluminum alloys.

For greater clamping reliability aluminum wires For large sections, special gaskets made of the same material are used. The fastening will be strong, but the bolts should be tightened every 7-10 days.

Selection and use

The photo of cable clamps shows various modifications that can be used for a specific installation purpose. It is important to check:

• presence of markings;
• absence of defects and defects;
• compliance of the clamp with the parameters of the rope.

When fixing the rope, the jumper should be on the side of the rope where the main load is present. Before use, check the tightness of the fastening. It is not allowed to influence the mechanism by welding.

The use of clamps allows for reliable and durable fastening when connecting cables or forming a loop. You can make them yourself, but purchasing factory-made products will ensure the durability of the fasteners.

Photo of cable clamps

Rope lanyard is a device that is widely used for installation, construction and rigging work. Thanks to this intermediate link, the tension of cables, ropes and cables can be easily adjusted. You are probably familiar with it, but you didn’t know its wonderful name!

What is this intricate tool used for?

Since the cargo lanyard has a special design, this allows it to withstand high stress and force, even when working with fairly heavy loads. Initially, this device was used to connect wooden and metal structures of the most various types. It is often used during rigging work, when it is necessary to secure transported or mounted equipment, or any other heavy load. If you need to install a metal mast or antenna, then this tool will help you cope with it.

Metal appliances tend to rust if they are exposed to moisture for some time. But a stainless lanyard is protected from this disease, since it is made of special steel or treated with a zinc coating. This measure was developed for the reason that this element is very often located outside the fixed structure, and therefore is always exposed to the influence of the atmosphere.

It is necessary to choose this device based on the length and thickness of the ropes or antennas, and, despite the impressive tasks, they are solved by such little ones as lanyards, their sizes vary from 5 to 20 mm. The overall success of any construction process depends on the choice of installation device. First of all, you need to decide why it is needed. Most often, such an element is used precisely to connect and tension cables or ropes on which a heavy load will be attached.

How does this mechanism work and why?

In order to understand the structure of this device, you need to pay attention to the drawing, The lanyard from the outside looks like an ordinary coupling, which consists of two screws. Moreover, the screws used are those on which the opposite thread is applied. They are then screwed into a metal structure, often cylindrical. If of this device no, you can use a special ring. Thanks to metal structure or ring, the screws are “pulled” closer to the center, as a result of which it is tightened.

Also, in addition to rigging work, this device is widely used at home, mainly when it is necessary to tighten curtain fasteners, tune a piano (achieve a better sound, tighten the strings).

Often such a tool is made open, that is, the adjusting screws are visible. Its body is made by forging, welding or casting. After this, two holes are milled, which allow you to change the length and force using screws. They are made by turning. In cases where work is carried out in difficult weather conditions, a closed lanyard is used. Most often, this tool consists of three parts: a body, two screws (with right-hand and left-hand threads) and a screw head (fork, hook or ring).

Types of devices for tensioning cables

Before purchasing a tensioning device, you need to understand its markings., namely: C+C – hook and hook, C+O – hook and ring, O+O – ring and ring. These are the most commonly used, but there are others. In order to tighten or loosen the tension, it is necessary to rotate the “ring”, after which the screws will move either towards the center or away from it. The type of tool depends on what kind of work you are going to do. Galvanized tools are used when you need high tension force. The cargo type is used when it is necessary to either tighten the cables or attach a heavy load. Such devices can reach a weight of up to 25 kg, and this tool can withstand up to 90 tons.

The “hook-hook” type of device is used when it is necessary to change the length of a cable, mainly when installing masts or antennas. The “ring hook” is also used in such cases. The moving parts of this version of the device have threaded threads, thanks to which the length can be adjusted. There are also now options using modern technologies, using which you can adjust the smoothness of the tension. Such tools are used when working with fiber optic cables. In order to tension wires and cables under light loads, you can use closed tools.

In such cases there is no clear meaning permissible load, so you need to be guided by the facts. It should also be remembered that such devices are not used for load-bearing structures. The fork-fork option is very popular and is used quite often. It allows you to quickly change or adjust tension and length. However, this tool is not used for lifting loads. It was created in order to adjust suspensions, braces and belays. But the chain lanyard is longer than its counterparts; it is able to grab two objects that are relatively far from each other, and then pull it together, giving the required tension.

Successful work and proper operation of the lanyard

Forces that act on the mechanism of this instrument, should not cause deformation during loading. If this happens, then the tension must be reduced, and the parts that have undergone deformation must be replaced. If there is a chance of shock loading or critical mode, then before starting work, you must clearly select the product to be used. The permissible load is only permissible along the axis line. There should be no overload.

The products are also not designed to withstand lateral loads. The tensioner used must always be checked before and after work for compliance with safety standards, otherwise unacceptable critical deformations may occur. If you calculate the measurements correctly and follow everything the smallest details, and also carry out preventative work and inspection of the condition of the tool, it will last as long as possible long term, and the likelihood of its breakage or deformation will be minimized.

Before starting work, it is recommended to wash the tool with gasoline, if possible polish it on a felt wheel, apply lubricant and run it dry. The best lubricants in this case are those with the addition of graphite or molybdenum bisulfate. It is recommended to turn them during work (two or three times will be enough). If the work is carried out in difficult climatic conditions, where humidity is high, then spilling will not be superfluous. fresh water on the mechanisms, which will allow you to wash off salt water. Exactly these simple rules will deprive the user of many problems, in particular, the painful unwinding of a “stuck” lanyard.

Thus, thanks to universal tool, you can do both simple work (tensioning strings, curtains) and complex work (tensioning ropes or carrying heavy loads without using additional accessories). Also, using this mechanism, you can achieve best indicator vertically when installing the antenna or mast.