Radio controlled toys such as cars, airplanes and boats are well known.

However these toys are all controlled so as to be driven in the same manner as the real car, airplane or boat, by applying power to the wheels, or propellers, and to provide steering by turning the wheels of the toy car or the tail rudder or ailerons of the plane or the rudder of the boat. Hence it is a relatively easy matter to scale done the size of the components from the "real" vehicle to operate the toy vehicle.

However in the case of surfboard riding, a board is first propelled by the surfer laying or kneeling on the board and paddling with his arms to obtain sufficient speed to catch the wave. The surfer then stands and uses the position of his weight and body movement along the board to turn the board and maintain position on the wave or to leave the wave. It is therefor not a simple procedure to produce a toy surfboard which will operate in the same manner as a "real' surfboard.

The present invention has ameliorated this problem by providing a radio controlled toy surfboard which perform manoeuvres on a wave similar to those performed by a "real" surfboard.

In one broad form the invention comprises a radio controlled toy surfboard or body board comprising: a board having a top surface, a bottom surface, a front end, and a tail end; a figure of a surfer located on the top surface and being so positioned and constructed as to provide a balance to maintain and to bias the board into a flat running position; a compartment within the surfboard to hold the radio receiver and the controls and the motor; a drive propeller located near the tail of the board; and a rudder located between the propeller and the tail of the board.

the bottom of the board being so shaped as to hold the waves in the same manner as a full size surfboard.

In another form the invention comprises a radio controlled toy surfboard or body board comprising:

a board having a top surface, a bottom surface, a front end, and a tail end; a figure of a surfer located on the top surface and being so positioned and constructed as to provide a balance to maintain and to bias the board into a flat running position; a compartment within the surfboard to hold the radio receiver and the controls and the motor; a drive propeller located near the tail of the board; and a rudder located between the propeller and the tail of the board.

the bottom of the board being shaped with a upswept nose portion, being rolled in cross section, with a central section having two concave channels and a stepped runner at each edge, and a relative flat section adjacent the tail, so as to hold the waves in the same manner as a full size surfboard.

In a further form the invention comprises a radio controlled toy surfboard or body board comprising: a board having a top surface, a bottom surface, a front end, and a tail end;

a figure of a surfer located on the top surface and being so positioned and constructed as to provide a balance to maintain and to bias the board into a flat running position; a compartment within the surfboard to hold the radio receiver and the controls and the motor; a drive propeller located near the tail of the board; and a rudder located between the propeller and the tail of the board.

the bottom of the board being shaped with a upswept nose portion, being rolled in cross section, with a central section having an oval shaped lifting surface extending along the board and out of the board with two concave channels extending there along, and a stepped runner at each edge of the board, a small fin located adjacent the rear of the oval shaped lifting surface and a relative flat section adjacent the tail, so as to hold the waves in the same manner as a full size surfboard.

Preferably the rudder comprises an outer ring with a three bladed elongated spoke extending within the ring and beyond said ring, towards and aligned with the propeller.

The present invention will now be described with reference to the accompanying drawings in which: Figure 1 shows a perspective view of a radio controlled toy surfboard according to one embodiment of the present invention; Figure 2 shows a view of the cavity for the guidance and power system of the radio controlled toy surfboard as shown in figure 1; Figure 3 shows a bottom view of the toy surfboard shown in figure 1; Figure 4 shows a side view of the toy surfboard shown in figure 1; Figure 5 is a cross sectional view taken through the toy surfboard as illustrated in figure 3 in the direction of the arrows V-V; Figure 6 is a cross sectional view taken through the toy surfboard as illustrated in figure 3 in the direction of the arrows VI-VI; Figure 7 is a cross sectional view taken through the toy surfboard as illustrated in figure 3 in the direction of the arrows VII-VII;

Figure 8 is a cross sectional view taken through the toy surfboard as illustrated in figure 3 in the direction of the arrows VIII-VIII; Figure 9 is a close up view of the underside of the tail of the toy surfboard as shown in figure 1; Figure 10 is a partial cut away view of the surfer figure and cavity cover of the toy surfboard as illustrated in figure 1; Figure 11 is a bottom plan view of a toy surfboard according to another embodiment of the present invention with the top cover and surfer figure removed; Figure 12 is a side view of the toy surfboard shown in figure 11; Figure 13 is a cross sectional view taken through the toy surfboard as illustrated in figure 11 in the direction of the arrows XIII - XIII; Figure 14 is a cross sectional view taken through the toy surfboard as illustrated in figure 11 in the direction of the arrows XIV - XIV; Figure 15 is a cross sectional view taken through the toy surfboard as illustrated in figure 11 in the direction of the arrows XV - XV;

Figure 16 is a cross sectional view taken through the toy surfboard as illustrated in figure 11 in the direction of the arrows XVI - XVI; Figure 17 illustrates a perspective view of a radio controlled toy body board according to another embodiment of the present invention; Figure 18 illustrates a plan view of the radio controlled toy body board illustrated in figure 17; and Figure 19 illustrates a side view of the radio controlled toy body board illustrated in figure 17.

As is shown in figure 1, the radio controlled toy surfboard (1), comprises an elongated surfboard body (2) with a surfer figure (3) mounted on a cover (4) which is located above and seals the cavity (5). The surfer figure (3) is preferably positioned in a crouched position as shown. Apart from the aesthetics, the surfer figure (3) provides an essential feature to provide for the flat running of the surfboard body (2), in that it provides a balance for the surfboard body. Further the surfer figure (3) is also either hollow or made from a material less dense than water, so that if the board (2) should tip, the floatation of the surfer figure (3) rights the board (2).

To assist in the performance, the surfer figure (3), as shown in figure 10, is hingedly attached to the cover (4), to absorb shocks and to provide a more realistic appearance. As shown, the figure (3) is attached by a rubber band (6) on a pin (7) to a stud (8) on the cover (4), allowing for the surfer figure (3) to pivot during movement of the board body (2) and to spring back into position to assist in effective turns and to right the board in the case of the board body (2) flipping over. This could be replaced by any suitable hinge system such as stainless steel spring.

A preferred shape of the board body (2) is shown in figures 3 to 8. As shown in figure 4, the front (8) of the board body (2) is upturned, and is curved in profile, as shown in figure 5. Further down the board body (2), a small blunt keel (9) extends along the centre of the board body (2) to form the housing (11) for the propeller (10). The keel (9) is preferably gently curved to assist in smooth turning of the board body (2) through the water.

A concave channel extend along the middle section (12) of the board body (2) on both sides of the blunt keel (9) as shown in figures 6 & 7. Also a stepped runner (13) extends along the edges (14) adjacent the middle section, (12) as shown in figures 3, 4 & 7. Each change in slope is preferably smooth to assist the smooth travel of the bodyboard body (2) across the wave.

To assist in ease of turning, the tail section (14) has a relatively flat bottom, as shown in figure 8. The steering and propulsion system is also located at the tail (14) of the board body (2). As shown in figures 3, 4 & 9, a propeller (10) extends from the housing (11) which is an extension of the blunt keel (9). Located adjacent the end of the tail section (14) is a specially shaped rudder (15). The rudder (15) comprises an annular member (16) with a trifurcated directional blade (17), which comprises a vertical orientated elongated blade (17) extending towards the propeller(10), with two blades (18 & 19) orientated at approximately 1200 from each other, and extending along the bottom of the vertical blade (17). Preferably the two blades (18 & 19 ) are triangular in shape, with the vertically orientated blade (17) being some what parallelogram in shape. The rudder (15) pivots on the shaft (20). A propeller guard (21) extends from the annular member (16) to the housing (11). It has been found that a rudder of this configuration provides an effective directional control of the toy surfboard.

As shown in figure 2, the control and propulsion system is mounted in the cavity (5). To assist in the flat running and in effective turning, it is preferable to have the batteries (22) located at the rear of the cavity. The toy surfboard (1) is powered by a suitable electric motor (23), which is water cooled by means of the coil (24), which has its inlet (25) and outlet (26), positioned as shown in figure 9, such that as the toy surfboard (1) travels through the water,

water flows through the coil (24). In the embodiment shown the motor (23) is directly connected to the propeller shaft (31).

The radio control receiver (30) and operating mechanisms (28 & 29) are located in the front of the cavity (5). A push rod (27) is connected from the operating mechanism (28) to a lever (not shown) rigidly connected to the rudder (15). Another operating mechanism (29) controls the speed of the motor (23). The antennae can be connected to the surfer figure (3) or formed integrally therewith or even be free standing.

As in surfing, it is important that the weight distribution of the components be correct for the shape of the bottom of the board to ensure that the board runs flat and that the turns are effective.

A further embodiment of a toy surfboard is shown in figures 11 to 16, in which the front (8) of the board body (2) is also upturned and is curved in profile with a small keel (32) as shown in figure 13. Further along the board body (2) an oval shaped lifting surface (33) projects from the middle section (12) of the underneath of the board body (2). Two concave channels (34) run on either side of the keel (9) along the oval shaped lifting surface (33) as shown in figures 14 &15 the keel (9) continuing along the board to form the housing (11) for the propeller (10). A small fin (35) projects from the housing

(11) . Adjacent the rear of the oval lifting surface (33), are stepped runners (13) located on the underneath of the edges (14) as shown in figures 11 and 15.

In this embodiment a bifurcated rudder (36) is used, having the arms (38) angled away from each other and the free ends (37) of the arms (38) projecting outwardly at an angle to the plane of the arms (38). A propeller guard similar to that of the previous embodiment can be used. Apart from the shape of the hull and propeller this embodiment is constructed in a similar manner as the previous embodiment.

A further embodiment is shown in figures 17 to 19, in which the invention is applied to a radio controlled body board toy. The underneath of the board can be similar to the previously described embodiments. However in this embodiment the keel (39) is a tear drop shaped lifting surface (40) projecting out of the plane of the underneath of the board body (2) and similarly constructed as the oval shaped lifting surface (33) of the previous embodiment.

Stepped runners (13) extend, adjacent the edges, from approximately the middle of the board to the rear of the board.

The lay out of the components in the cavity of the board are similar to the previous embodiments,. The figure (3) rather than standing on the cover (4) is located on the cover (4) in a reclined position, with the legs (41) pivotally connected to the cover (4), such that the legs (41) move from side to side as the board turns through the water It should be obvious to people skilled in the art that variations and modifications, such as using a water jet propulsion system, or cable operated controls, can be made to the embodiments described without departing from the spirit and the scope of the present invention.