Abstract:
A modular assembly of reciprocating electric generators with respective movable floats and a common submerged damper plate and buoyancy chamber produces electricity from wave motion on a body of water.

Description:
BACKGROUND 
     The field of this invention is in the generation of electricity from ocean wave motion. Prior art is exemplified in U.S. Pat. No. 3,546,473. 
     SUMMARY 
     Several linear reciprocating electric generators are assembled as elements of a generally pyramidal or conical form, like the poles of a tepee, with their movable armature members connected to floats above the apex adapted to follow displacements of the water surface and the lower ends of their stator members connected at relatively widely separated points to a damper plate below the surface. A submerged buoyancy chamber may be provided above the damper plate to maintain the assembly in proper relationship to the mean surface. This configuration minimizes tendency of the assembly to drift off station owing to the horizontal component of wave motion. The assembly is designed as a module, adapted to be secured to other like modules to form an array. 
    
    
     DRAWING 
     FIG. 1 is an overall view of a generator module according to this invention. 
     FIG. 2 shows a portion of the structure of FIG. 1, partly broken away to display internal details. 
     FIG. 3 is a circuit diagram showing the interconnections of the generator of FIG. 2 and their associated rectifier devices. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring to FIG. 1, the converter assembly includes three tubular members 1 arranged approximately as surface elements of a cone, or more specifically, as edges of the sides of a tetrahedron. The tubes 1 are fixedly secured to each other in non-intersecting relationship near the apex by a block 2 bored to receive the tubes at the appropriate angles. 
     Each tube 5 contains a reciprocable rod, to be described, provided at its upper end, beyond the apex region, with a respective float 8. The tubes 1 terminate in brackets 5 securing them to a flat damper plate 4 which may be in the form of an equilateral triangle, as shown. The brackets 5 carry exterior lugs 16 provided with holes to accept suitable fastener means for securing the module to other similar modules to form an array of any desired size. 
     A closed buoyancy chamber 3 is secured to tubes 5 below the box 2 to assist the floats 8 in maintaining the assembly at a suitable level with respect to the mean sea surface. Removable ballast weights 6 may be provided to be placed as shown on the damper plate 4 for precise adjustment or compensation for long-term changes such as may be caused by silt depositions, for example. 
     Referring to FIG. 2, the upper end of each tube 1 is sealed by a bellows sleeve 12, reinforced by a flexible cable 14 to prevent over-extension Each reciprocable rod 7 is supported and guided by suitable slide bearings 11 spaced apart longitudinally of the respective tube 1. Each rod carries a number of longitudinally spaced permanent magnets 10, extending coaxially of the rod. A plurality of coils 15, one for each of the magnets, are secured to the inner surface of the respective tube 1. 
     The coils are so located that the associated magnet will move between a position enclosed by the coil to positions at least partially outside the coil during normal reciprocation of the rod. The coils of each elemental generator are connected in series to provide a pair of output terminals that are connected to a rectifier 17. 
     Referring to FIG. 3, each series-connected group of coils 15 is connected as shown to the input terminals of a full-wave rectifier bridge 21 of unidirectionally conductive diodes 18 and a storage capacitor 19. The outputs of the rectifiers 21 are in turn series-connected between a single pair of module output terminals 22 and 23. These terminals are connected to conductors 15A contained in tubes 17 (FIG. 1) designed to connect to external utilization means or to other modules of an array. 
     In the operation of the described apparatus, the module is flotationally suspended in a body of water as indicated in FIG. 1, with the floats 8 partially submerged at the surface, and the rest of the structure totally submerged. Water wave motion diminishes rapidly as a function of depth, and the damper plate 4 is placed where such motion is relatively slight or essentially negligible. 
     As each wave passes, the floats 8 are raised and lowered, moving the rods 7 up and down within the tubes 1. The tubes are maintained relatively stationary by the damper plate 4, which strongly resists vertical motion. The damper plate also acts as a sea anchor, counteracting the tendency of the structure to drift off station. As a result, only relatively light bottom anchorage is required to hold a module or an array of modules in a desired vicinity. 
     Motion of the rods 7 moves the magnets 10 into and out of coils 15, inducing therein pulses of electromotive force alternating in polarity at the same frequency as the motion. The pulses are cophasal in the coils of any one generator, and so may be combined additively by the described series connection of the coils 15. However, the pulses of individual generators are not necessarily cophased, owing to possible independent motion of the respective floats 8. 
     Accordingly, the output of each individual generator is rectified by its rectifier 21 (FIG. 3) and stored in its capacitor 19. The direct voltages stored in the capacitors can be directly additively combined by the illustrated series connection of the capacitors across output terminals 20 and 21. The outputs of a number of modules can be combined by similar interconnection in known manner. 
     Although the invention is generally useful for producing electricity for many purposes, the direct current output is particularly suitable for electrolytic operations, for example the production of hydrogen gas as a substitute for fossil hydro-carbon fuels.