Battens Battens are linear members to which live loads may be attached for flying. Battens were made of wood originally, but today they are typically steel pipe. Loads mounted to battens include lights, curtains and scenery so they may travel vertically, be raised up into the fly space (flown out) or lowered near to the stage floor (flown in) by its associated line set. Battens typically stretch the width of the stage, parallel with the proscenium wall, and are maintained level (parallel to the stage deck) regardless of elevation. When a batten is flown all the way out (close to the grid) it is at high trim. When it is flown all the way in (usually to about above the stage deck) it is at low trim. Loads are attached to the batten in various ways. Most lighting fixtures, for example, utilize a
C-clamp to rigidly secure the light onto the batten, in conjunction with a safety cable that is looped around the batten to prevent the light from falling should the C-clamp connection fail. Non-traveling curtains (e.g., borders) often employ cloth ties, similar to shoestrings, that are hand tied onto the batten. Battens are suspended by evenly spaced lift lines, with pick points generally apart. The unsupported,
cantilevered, ends of a batten, beyond the last lift line pick points, are generally no longer than unless a bridle is used to effectively limit the cantilever. ;Standard pipe batten Battens were originally made from wood, but have been replaced by steel pipe. In the United States they are typically fabricated from sections of nominal diameter, outside diameter, schedule 40 steel pipe that are spliced together (with internal pipe sleeves and bolts) to provide a continuous member that stretches the width of a stage. Schedule 80 pipe is also used. Standard pipe battens are typically designed to support of live load per foot of length. ;Truss batten Truss battens, sometimes referred to as double battens, use a pipe-over-pipe arrangement (often center-to-center), with vertical struts welded between the upper and lower pipes to provide rigidity. Truss battens generally permit greater loads than single-pipe battens and may not require as many lift lines due to improved ability to span between lift lines. Truss battens are typically designed to support of live load per foot. ;Electric batten An electric batten, a.k.a. lighting batten, may be a single-pipe or truss batten. Electric battens typically incorporate steel straps that are used as brackets for the support of electrical equipment such as connector strips (raceways). The same straps supporting electrical equipment may also connect the two-pipe arrangement of a truss batten. The center-to-center spacing of electric truss pipe, often from , is typically greater than for a standard truss batten to allow for the proper mounting and focusing of lighting instruments. It is typical for an electric batten to support thousands of pounds of live load. ;Light ladder batten Light ladder battens are a special type of electric batten oriented perpendicular to and beyond the proscenium opening, at the stage wings. They suspend light ladders (pipe frames) to which lighting fixtures may be attached. When provided, light ladder battens are usually of the truss type and may be fitted with heavy-duty track to permit repositioning of the light ladders up and down stage. ;Tab batten Tab battens are oriented perpendicular to the proscenium opening, parallel to and just off stage of light ladder battens. When provided, they are single-pipe or truss battens for the support of tab draperies, which are used to mask the stage wings.
Lines Lines are the ropes, cables (wire ropes) and proof coil chains that enable a fly system to function. Steel bands are a relatively new type of line used in steel band hoists. It is standard practice for overhead rigging lines and hardware to be rated with at least an 8-times
safety factor to help ensure the protection of cast and crew. In other words, a line intended to support 100 pounds should have a
safe working load of at least 800 pounds. Lift lines carry and transfer the loads of a fly system to the fly system infrastructure. The lift lines for manual rigging run from the batten up to loft blocks, across the stage to a head block, and down to the counterweight balancing the load of the line set. When running horizontally, between loft blocks and head block, lift lines typically follow a transverse path (from side to side) across the stage. Operating lines, also known as hand lines or purchase lines are what the crew uses to manipulate manual fly systems. Operating lines are connected to sandbags (in a hemp system) or the top and bottom of arbors (in a counterweight system). Operating lines are typically or in diameter. Lift and operating lines were commonly made of
manila hemp. The rope was often referred to simply as manila. Use of manila had a number of issues. Splinters of fiber could get into hands and eyes. Humidity and temperature changes could significantly affect the length of the rope. Over time the rope slowly rots. Synthetic rope can reduce or eliminate these issues, while providing greater strength by volume. Some riggers have complained that rope burn is more likely with synthetics, and that wear and damage on a synthetic rope is harder to detect. The two most common brands of polyester rope in the theatre world are Stage-Set X (parallel-fiber core) and Multiline II (braided strand). Over time polyester rope became more popular than manila in hemp systems and for use as the operating lines in counterweight systems. The lift lines of a counterweight rigging systems are typically a specific type of steel
wire rope known as galvanized aircraft cable (GAC). Oil-free diameter, 7 x 19 strand, GAC is the most common counterweight system lift line. It has a minimum cable breaking strength of approximately . ;Line control Load-bearing lines must be safely tied off, locked, terminated and/or connected to other rigging components to ensure line control and the safety of a fly system. Various methods are employed.
Belaying pins are used to belay, temporarily tie off, the rope lines of a hemp system. Each belaying pin serves as an anchor to which the loose end of a rope may be quickly secured. A standardized method is used to tie off the rope so that it is subjected to friction from itself as well as from the pin rail, thus ensuring a secure connection that is unlikely to fail. Belaying pins are typically made of hickory wood or steel.
Knots, such as the clove hitch and half hitch, are used for rope line terminations. For example, hitches are used to terminate hemp lift lines at battens and operating lines at counterweight arbors.
Rope locks are cam-actuated devices through which a counterweight system operating line passes. The adjustable cam, or dog, inside the rope lock constricts and releases the operating line as the flyman lowers and raises a hand lever. Rope locks are mounted in series to the locking rail. A single rope lock can typically secure a static unbalanced load to . Rope locks are not intended to slow a running line.
Swage (compression) fittings or
cable clips are used to terminate counterweight system lift lines, after the cable has been looped around a thimble. Cable clips terminations maintain less load capacity than swage fittings, typically require three clips, and are greatly reduced in load capacity if the installer happened to
"saddle a dead horse". Both swage and cable clip terminations permanently
crimp (deform) the wire rope. Trim chains and shackles, or
turnbuckles and pipe clamps, typically connect the lift lines of a line set to the batten they support. Those connections facilitate minor adjustments to, trim, the effective length of a lift line. By trimming the lift lines, loads are more evenly distributed to them. Turnbuckles are moused (secured against free rotation) to prevent the jaws from slowly unscrewing over time due to vibrations incurred during normal use. Counterweight lift lines typically connect to the tops of arbors with shackles.
Blocks A block is a
pulley used to support and direct lift and operating lines. A block consists of a grooved wheel, known as a
sheave (pronounced "shiv"), steel side plates, spacers, shaft, flange bearings, mounting angles and clips, etc. Blocks are sized based on anticipated live loads, operating speeds, line type and other factors. Sheaves were traditionally fabricated of cast iron, but steel and nylon sheaves are now common. Blocks are either upright, when mounted atop a support structure, or under-hung, when mounted to the underside of a support structure. The side plates of blocks preferably fully cover the profile of (fully enclose) the sheaves to lend the block greater stability and limit the sheave's (and crew's) potential for damage from foreign objects. Nevertheless, blocks are available with exposed sheaves. ;Loft block A Loft block is an overhead block that supports a single lift line. A loft block supports and redirects a lift line from the batten to the head block of a line set. Under-hung loft blocks typically mount to loft block beams (fly loft roof beams). Upright loft blocks typically mount to loft block wells (grid-level structural channels). A spot block is a readily movable loft block for mounting anywhere on the grid deck for spot rigging. The diameter of a loft block sheave for galvanized aircraft cable is typically at least 32 times the diameter of the cable. For example, loft blocks are typically used with GAC, but blocks may be used to facilitate flying heavier line sets (e.g., electrics). Loft blocks may be equipped with idler pulleys or sag bars to limit the sag of horizontally running lift lines on under-hung systems. In under-hung counterweight systems that use upright head blocks the series of loft blocks immediately following the head blocks are typically multi-line loft blocks instead of single-line to account for built-in vertical misalignment between head blocks and loft blocks. ;Head block Head blocks are overhead multi-line blocks used for the lift lines and operating lines. Head blocks support and redirect all the lift lines from loft blocks to sand bags (of a hemp set), counterweight arbor (of a counterweight set) or hoist (of an automated line set). Rope line (hemp) head blocks are typically upright blocks that mount to the rope line head block well channels at the grid level. In a counterweight rigging system the head block sheave is grooved for both the steel cable lift lines and an operating line, with the groove for the operating line provided at the middle of the multi-grooved sheave, between the lift lines. Counterweight head blocks mount atop or at the underside of the head block beam, depending on the beam's vertical position. The diameter of a head block sheave used for galvanized aircraft cable is typically at least 48 times the diameter of the cable. For example, head blocks are typically used with GAC, but blocks may be used to facilitate flying heavier line sets (e.g., electrics). ;Mule block Lift lines sometimes require diversion to avoid obstacles, support non-linear loads and battens, deal with excessive fleet angles, or be reoriented from the typical transverse path across the stage (e.g., for tab and light ladder line sets). Mule blocks are single or multi-line blocks able to divert the path of those lines. Mule blocks may be permanently installed as part of counterweight rigging systems, or used for spot rigging, where they are often equipped with swivel-pivots to divert lines across a large range of angles. ;Tension block Tension blocks are single-sheave blocks located at the lower end of the arbor guide track, beneath the arbor. The operating line is reeved through the tension block from the bottom of the arbor through the rope lock. Tension blocks typically ride vertically along the arbor guide system tracks, instead of being fixed, to allow for variation in the length of the operating line.
Counterweights Counterweights are heavy objects that are used to balance the lineset loads in a fly system. In hemp systems, a counterweight consists of one or more sandbags, whereas counterweight systems employ metal bricks as counterweights. The term counterweight is commonly used to refer specifically to the metal counterweight bricks. Metal counterweights are
lead,
cast iron, or
flame-cut steel. Flame cut steel bricks are most common. In any particular fly system all counterweights typically share a common, standardized footprint that matches the system's arbors, which in turn are sized to conform to line set spacing. Counterweight systems are most often designed to use either 4 or wide weights. Weights vary in thickness, typically in half-inch increments ranging from 1/2 to , with each thickness corresponding to a different mass. thick weights are most common. Counterweights are sometimes also known as bricks or simply steel. Often a rigging worker will be asked to load a number of inches of steel, which correlates to a specific mass. Weights are usually loaded from the loading bridge, but can also be loaded from the fly gallery or stage deck in some circumstances. When viewed from the top, metal counterweight is basically
rectangular, typically with 45-degree angle chamfers cut at two opposing corners. A slot is cut into each end of the weight so as to enable the weight to straddle, and be laterally secured by, the arbor rods. In order to facilitate removal of weights with angle cuts, it is customary to stack the weights in alternating orientations so that the square corners of any weight will be aligned with the angled corners of adjacent weights. This simplifies removal because the square corners of each weight protrude beyond the angled corners of the weight below, serving as handles that can be easily gripped, even with
gloved hands. It is customary to apply paint (typically yellow) or colored tape to the weights that counterbalance the batten (pipe) to indicate that they should not be removed from the arbor. As an additional precaution, they may be strapped in with steel strapping. When a dedicated line set carries a permanent load (e.g., main drape, orchestra cloud, etc.) the counterweight balancing the additional load may be treated in a similar fashion. Steel to lead density ratio is 1 : 1.448
Arbors A counterweight arbor is a sturdy mechanical assembly that serves as a carriage for counterweights. In its simplest form, an arbor consists of two horizontal steel plates, a top plate and bottom plate, tied together by two vertical steel connecting rods. Counterweights are stacked as required on the arbor's bottom plate to balance the line set load, with the weights held in place by the connecting rods. A flat tie bar at the rear of the arbor also connects the top and bottom plates. Guide shoes at the top and bottom of the tie bar guide the arbor along tracks mounted to the side stage wall.
UHMWPE pads on the guide shoes limit friction between guide shoe and track as the arbor travels. Spreader plates are thin steel plates with holes through which the arbor connecting rods pass. Spreader plates are lowered onto the counterweights in a distributed fashion as the counterweight stack is being built. Typically one spreader plate is placed on top of every two feet of counterweight in the stack. Finally, a locking plate is lowered onto the completed, interleaved stack of counterweights and spreader plates and secured in place with a thumbscrew. Spreader plates serve to maintain consistent spacing between the arbor rods to ensure reliable containment of the counterweights under normal operating conditions. Also, in the event of a "runaway" (loss of control of an unbalanced lineset), the spreader plates will prevent the arbor rods from bending outward, and thus releasing the counterweights upon arbor impact at the end of its travel. A new type of arbor was introduced by Thern Stage Equipment in 2010. It is referred to as a front loading counterweight arbor. This arbor has shelves and a gate to secure the counterweights in the arbor. Spreader plates are not required with the front loading arbor. The arbor counterweights are loaded from the front, rather than from the sides. Counterweight arbors are commonly between 8 and 12 feet in length and can often support stacks of weights between 1500 and 2400 pounds, or beyond. In order to avoid unreasonably tall counterweight stacks at high capacity line sets, arbors may employ more than one counterweight stack. Such arbors use multiple-width top and bottom plates with a tie bar and pair of connecting rods provided at each counterweight stack. Counterweight rigging systems use either tracked or wire-guided arbor guide systems. The tracks or wire guides limit lateral movement of the arbors during arbor travel. Wire-guided systems have lower capacities and are not in common use. In addition to guiding the arbors, a tracked counterweight system is provided with bump stops at arbor high and low trim that establish the limits of an arbor's travel. A tracked guide system is sometimes referred to as a T-bar wall, as the tracks are commonly made of steel T-sections. Aluminum arbor guide tracks are a relatively recent alternative, often using a J profile, instead of a T profile, to facilitate system installation.
Hoists Hoists of various types are used in manual automated rigging systems. The terms hoist and winch are often used interchangeably in theatre jargon. Hoists are generally assumed to be motorized unless "manual" is used as a descriptor. ;Manual hoist Manual hoists, or hand winches, are typically composed of a drum, gear box, and crank (operating handle). A
worm gear is commonly used to provide
mechanical advantage as the crank is turned, which coils a single line around a smooth or helically grooved drum. The drum line is connected to the lift lines with a clew, triangular plate with holes used for line terminations. From the clew, the lift lines run over a head block and loft blocks down to a batten. The clew may be wire-guided to limit lateral play. Drill-operable hand winches permit the handle to be removed so that an electric drill may operate the hoist. ;Drum hoist Drum hoists are typically composed of an electric brake motor and a multi-line helically grooved drum. Helical drums are preferable to smooth drums for cable longevity and the precise and repeatable control of travel. Drum hoists are used for motor-assist, engaging an operating line, and dead-haul, engaging the lift lines, applications. A dead-haul drum hoist uses the single drum to support all the lift lines running from the head block of a line set. The lift lines neatly wrap and unwrap in a side-by-side arrangement on the drum as it is spun by the motor. As a lift line coils and uncoils from the drum of a drum hoist, its fleet angle (angle of a line between drum and sheave) changes. Excessive fleet angles (e.g., greater than 1.5–2.0°) cause unpredictable line behavior and can damage lines, blocks, and drums. As a result, fleet angles limit how close a dead-haul drum hoist can be mounted to the head block (usually about 10 feet). A moving drum hoist, or traveling drum hoist, is a variation on the traditional drum hoist. Moving drum hoists effectively eliminate the fleet angle between drum and block by shifting the drum along its axis as it spins. The amount of shift per drum revolution is equal to the pitch of the drum's helical groove. With the fleet angle problem resolved, moving drum hoists can combine drum and head block into a single, relatively compact, unit for mounting to fly loft structure, with a corresponding reduction of installation cost. Yo-yo, pile-up, or pilewind, hoists use
yo-yo type devices instead of helically grooved drums. The yo-yos lines are coiled into overlapping layers of cable in the narrow slots. The pile-up drum hoists are usually used in low load. As the hoists are narrower than helically grooved drum hoists, these can be used in the places with limited space. Pile-up drum hoists can be mounted in many locations including ceiling, floor or wall mounting. Typical applications are to have a pile-up drum hoist with many pulleys to control a batten. Since the line is piled up on itself, this type of drum hoist provides a zero fleet angle solution. ;Line shaft hoist Line shaft hoists are typically composed of an electric brake motor, line shaft (drive shaft) and evenly spaced single-line drums aligned above the batten pick points. By placing an individual drum over each pick point, line shaft sets have the advantage, over drum sets, of eliminating the need for blocks. To avoid lateral drift of the batten as the lift lines pay out of the grooved drums, the helical groove orientation on the drums of the line shaft may be alternated between drums to balance competing fleet angles. However the elimination of drift by this method is typically compromised by limited batten travel. Line shaft hoists can also use yo-yo type devices instead of helically grooved drums. Yo-yo hoists are typically used where lighter loads are imposed (e.g., for operating an Austrian puff curtain). Because yo-yos lines are wrapped over themselves, the velocity and travel of the lines are relatively difficult to accurately control. ;Point hoist Point hoists, also known as spot line winches, control a single lift line and are commonly used for automated spot rigging or flying rigs. A point hoist may operate in solitude, or in unison with other point hoists to comprise a line set. Chain hoists, more commonly referred to as chain motors, are the most common form of point hoist, especially with touring musical shows (e.g., rock-and-roll shows), but are relatively slow. Chain motors can be mounted at the grid to hoist a load from above, or mounted at the load to "climb" towards the grid. Point hoists using wire rope (GAC) are common, and steel band point hoists are also used. While generally more expensive than chain hoists, wire rope and steel band point hoists can operate at relatively high speeds. Wire rope spot line winches may be configured to pay out to the side (horizontally), for use in conjunction with a loft block, so that the position of the relatively heavy winch can be static and only the loft block need be spotted above the pick point. ==Infrastructure==