Abstract:
A high voltage electrical transmission line tower is constructed virtually completely from insulated pultruded composites, enabling the closer spacing of conductors and the creation of a smaller tower structure and weighing half or less the weight of a steel tower with the same power transmitting capabilities.

Description:
This invention is a continuation in part of U.S. Pat. No. 5,024,036 to issue Jun. 18, 1991 on an INTERLOCKING SUPPORT STRUCTURES, filed Jun. 21, 1990 having Ser. No. 541,547. 
    
    
     BACKGROUND OF THE INVENTION 
     The inventions combines the fields of high voltage transmission towers and pultruded composite construction. The inventor has several patents and several pending applications that relate in one way or another to interlocking joints formed of pultruded composites. A pultruded composite is a mass of fibers, generally fiberglass, that are pulled through the die rather than being pushed (extruded). Currently, virtually all such towers are made of steel. However, there are inherent limitations of steel towers primarily because of the conductive nature of steel. This requires that enormous towers must be used both to separate the individual conductors from the steel structure and to accommodate inter-tower sag. 
     There are few large structures made of pultruded composites. This is partly due to the fact that when composite members are fastened with conventional fasteners such as bolts and screws, the joint strength suffers unacceptably. 
     However, nuts and bolts are not the only ways to hold composite members together. The inventor has developed a number of interlocking joint structures that do not require passing a hole through the members. 
     SUMMARY OF THE INVENTION 
     The invention is a high voltage transmission tower made almost completely from composites. By using composite construction, the weight of the tower is reduced by more than half, and there are other advantages including reduced inductive reactance due to the absence of a large steel structure in the vicinity of the wire, and closer phase-to-phase spacing. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a diagrammatic view of a tower made according to the invention; 
     FIG. 2 represents diagrammatically a prior art tower; 
     FIG. 3 is a prior art tower with a composite tower superimposed on for size comparison purposes; and, 
     FIG. 4 illustrates the relationship between wet insulator flashover and the size of the gap between the conductor and ground, that is the distance between the conductor and the grounded steel structure. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     A typical prior art tower is indicated at 10. It consists of a lattice structure 12, sometimes called a &#34;cage&#34; with extended support arms 14, leg members 15, horizontal bracing members 19, and diagonal bracing members 21. Strings of insulators indicated at 16 support the power lines 18. A &#34;goat peak&#34; 20 supports a lightning shield wire, not shown. The structure in FIG. 2 is all L-angled steel, and is bolted together with as many as 1500 bolts. 
     The invention is shown in FIG. 1. Although similar in appearance to the prior art, it is vastly different, being made of pultruded composites, and having no bolts. The predetermined distance between the respective high voltage wire conductors 18 is identified by the letter A and the predetermined distance between the high voltage wire conductors 18 and the legs 15 of the tower is identified by the letter B. 
     The spacing of the &#34;phases&#34;, or individual cables, is fairly narrowly defined by the amount of voltage the lines carry. The wet-insulation flashover should be four times the line-to-ground voltage. For example a three-conductor tower carrying 345 kilovolts is first divided by the square root of 3, which equals approximately 200 kilovolts. Since four times two hundred equals 800 kilovolts, an insulator string is selected to space the conductor from the metal tower sufficiently to have a minimum of 800 kilovolt flashover with wet insulation. The chart in FIG. 4 illustrates how to convert from a flashover voltage to air gap spacing. Therefore, at 345 kv, the conductors must be approximately 110 inches from ground potential, which basically includes all of the tower. Referring to the drawing of FIG. 3, a modified form 24 of the new tower can be seen superimposed on the equivalent metal tower 10. By eliminating the conductive material in the tower, it can be seen that the wires can be brought in to approximately half of their former spacing in the new composite tower. 
     This same efficiency in spacing is apparent in FIG. 1 as the tower 22 is approximately 80% as high as the tower of FIG. 2. The closest conductor to ground level, 18, remains at the same height in both configurations, to ensure with conductor sag, the minimum safe height above ground level is achieved. However, in FIG. 1, a compaction of conductors, or phases, is possible because the tower is a fully insulative composite and the design criteria of FIG. 4 is no longer a limiting criteria. Thus the insulator lengths, 17 in FIG. 1 are shown one half the length of the insulators 16 in FIG. 2. 
     The insulator length of FIG. 1 was illustrated as one half the typical length required of a steel tower. However, the insulation could be eliminated as a separate unit 17 in FIG. 1. This could be achieved by adding the silicone rubber sheds, a common &#34;tracking&#34; resistant skirt material used in high voltage polymer insulators, to extended rods which are an integral structure of the tower as shown at 26 in FIG. 1. In lieu of separate insulators, the sheds that are generally installed on insulator rods will be installed directly on a portion of the tower adjacent to the attachment point of the conductor. This is shown on just one arm of the tower in FIG. 1 at 26 but would of course replace all of the hanging insulators. 
     By compacting the conductors, the tower height is reduced, the right-of-way owned by the entity transmitting electricity is more compact, energy is transmitted more efficiently due to lower inductive reactance, the electric magnetic field at ground level (EMF) is reduced, and further reduction in weight is achieved.