System for transferring rotational, mechanical motion into sinusoidal wave-like motion

The invention claimed is: 1. A device for transferring rotational, mechanical motion into sinusoidal wave-like motion, said device comprising: a. at least one motor, generating rotational movement around a first Cartesian axis; b. an elongated rod, curved in the form of a helix, substantially aligned along said first Cartesian axis, and rotated by the at least one motor; c. a surface comprised of discrete, connected hollow elements, wherein: i. the elongated rod is interlaced within said discrete connected hollow elements, such that the surface is undulated, and the rotation of the elongated rod dynamically changes the surface's shape, moving the discrete connected hollow elements along a second perpendicular Cartesian axis, thus creating a wave like motion; ii. the width of each said discrete connected hollow element is larger than the diameter of the helix-shaped rod, so that while rotating, the elongated rod is freely movable within the cavity of the discrete connected hollow elements, along a third perpendicular Cartesian axis; iii. said surface interacts with the surrounding medium or base-surface upon which the device is moving, wherein said interaction is generated by said wave-like motion, such that said interaction creates a propelling force that drives said device forward or backward along said first Cartesian axis; wherein said discrete connected hollow elements are implemented as a plurality of hollow links connected in series, wherein said helix-shaped rod passes through said plurality of hollow links; and wherein each link comprises a hollow rectangular shape with two side members, a top member and a bottom member, forming the rectangular shape. 2. The device of claim 1 wherein the pitch of the helix-shaped rod corresponds with the wave length of the created wave-shaped surface. 3. The device of claim 1 , wherein each link comprises two distal arms extending distally from the side members, one distal arm from each side member; and each link comprises two proximal arms extending proximally from the side members, one proximal arm from each side member. 4. The device of claim 3 , wherein the angle between each distal arm and the side member it extends from is substantially a right angle; and wherein the angle between each proximal arm and the side member it extends from is substantially a right angle. 5. The device of claim 3 , wherein each pair of distal arms of each of the links in the series, which has a distal link, connects to the proximal arms of the adjacent distal link in the series. 6. The device of claim 3 , wherein a. each proximal arm and each distal arm comprises an aperture; b. the proximal and distal arms comprise inner recessed regions; c. each pair of distal arms of each of the links in the series that has a distal link, connect to the proximal arms of the adjacent distal link in the series; d. the recessed regions of the distal arms of the link face the recessed regions of the proximal arms of the distal link such that the apertures in each distal arm of the link are aligned with the corresponding apertures on the same side in each proximal arm of the distal link forming pairs of aligned apertures; and e. connecting means are inserted into each pair of aligned apertures. 7. The device of claim 3 , wherein the at least one motor is placed within a housing, and said housing is connected by means of hinge joints to two proximal arms extending proximally therefrom; and wherein the two proximal arms are connected at their proximal ends to the most distal link in the series of connected links to the most distal link's distal arms. 8. The device of claim 7 , wherein the two proximal arms extending proximally from the motor housing each comprise an aperture near their proximal ends which are placed in a manner such that they are aligned with the corresponding apertures of the distal arms of the most distal link in the series of connected links forming pairs of aligned apertures; and wherein connecting means are inserted into each pair of aligned apertures. 9. The device of claim 1 , wherein the top member and/or the bottom member of each rectangular link includes protrusions that elongate the distance between the center of said rectangular links and their point of contact with the ground, thus increasing the device's travelled distance within each full rotation of the helix-shaped rod. 10. The device of claim 9 , wherein the protrusions of each adjacent pair of rectangular links are designed in a spatially complementary manner, so as not to interfere with one another's movement, and not collide during the wave-like motion of said surface. 11. The device of claim 9 , wherein the protrusions of each adjacent group of three or more rectangular links are designed in a spatially complementary manner, so as not to interfere with one another's movement, and not to collide during the wave-like motion of said surface. 12. The device according to claim 1 , wherein the cross-section of the helix-shaped rod is round. 13. A device for transferring rotational, mechanical motion into sinusoidal wave-like motion, said device comprising: a. at least one motor, generating rotational movement around a first Cartesian axis; b. an elongated rod, curved in the form of a helix, substantially aligned along said first Cartesian axis, and rotated by the at least one motor; c. a surface comprised of discrete, connected hollow elements, wherein: i. the elongated rod is interlaced within said discrete hollow elements, such that the surface is undulated, and the rotation of the elongated rod dynamically changes the surface's shape, moving the discrete hollow elements along a second perpendicular Cartesian axis, thus creating a wave like motion; ii. the width of each said discrete hollow element is larger than the diameter of the helix-shaped rod, so that while rotating, the elongated rod is freely movable within the cavity of the discrete hollow elements, along a third perpendicular Cartesian axis; iii. said surface interacts with the surrounding medium or base-surface upon which the device is moving, wherein said interaction is generated by said wave-like motion, such that said interaction creates a propelling force that drives said device forward or backward along said first Cartesian axis; wherein the discrete hollow elements individually rotate about said third perpendicular Cartesian axis during said wave-like motion, so as to apply a force component in the direction of the first Cartesian axis on the base-surface, at the point of contact of each discrete hollow element with the base-surface, thus propelling the device forward in the direction of the first Cartesian axis direction. 14. The device of claim 13 , wherein if the device is set to move upon a horizontal surface, said wave-like motion will include movement of the discrete hollow elements along the vertical axis, and thus will enable the device to overcome obstacles in its path by climbing over them. 15. The device of claim 13 , wherein one or more of the discrete hollow elements are at a position being lower discrete hollow elements and one or more of the discrete hollow elements are at a position being upper discrete hollow elements; and wherein if the device is set to move upon a horizontal surface, said force component in the direction of the first Cartesian axis will be applied by both the lower discrete hollow elements and upper discrete hollow elements, so as to enable the device to advance through horizontal narrow passageways defined by walls that are in contact with the device from above and below. 16. The device of