Solar disk light with swivel mount

What is claimed is: 1. A tiltable solar disk light comprising: a disk light body comprising a disk-shaped housing, the housing containing lighting components comprising solar cells for harvesting solar energy and detecting ambient light; a rechargeable battery for storing the harvested solar energy; LEDs for emitting light; a latching pushbutton switch having an ON position and an OFF position for enabling and disabling electrical power delivery to the LEDs from the battery; and wiring and driver electronics for operably connecting the solar cells, battery, switch, and LEDs and configured to deliver electrical power to the LEDs from the battery when the switch is in the ON position and the solar cells are not detecting ambient light and to cut off power to the LEDs when the switch is in the OFF position or the solar cells are detecting ambient light; the disk light body further comprising a pair of pegs extending from the housing, the pegs in a co-axial arrangement to form an axis of rotation for the disk light body; a frame defining a circular an opening for receiving the disk light body, the frame having an inner circumference around the circular opening, and two holes in the inner circumference on opposite sides of the circular opening for receiving the pair of pegs and tiltably supporting the disk light body, the circular opening being sized and shaped to define a first clearance gap around the disk light body to permit the disk light body to tilt within the frame about the axis of rotation formed by the pegs; a landscape spike removably attached to the frame, the landscape spike configured for insertion into the ground, thereby affixing the tiltable solar light to the ground; wherein the landscape spike is connected to the frame by curved arms configured to define a second clearance gap between the spike and the frame to permit the light body to tilt within the frame about the axis of rotation formed by the pegs. 2. The tiltable solar disk light of claim 1 further comprising a landscape spike removably attached to the frame, the landscape spike configured for insertion into the ground, thereby affixing the tiltable solar disk light to the ground. 3. The tiltable solar disk light of claim 2 wherein the landscape spike is connected to the frame by curved arms configured to define a second clearance gap between the spike and the frame to permit the disk body to tilt within the frame about the axis of rotation formed by the pegs. 4. The tiltable solar disk light of claim 3 1wherein the disk light body may be tilted up to 35 degrees from horizontal relative to the frame until it contacts an arm. 5. The tiltable solar disk light of claim 3 1wherein the disk light body may be tilted up to 40 degrees from horizontal relative to the frame until it contacts an arm. 6. The tiltable solar disk light of claim 3 1wherein the disk light body may be tilted up to 45 degrees from horizontal relative to the frame until it contacts an arm. 7. The tiltable solar disk light of claim 3 1wherein the disk light body may be tilted up to 50 degrees from horizontal relative to the frame until it contacts an arm. 8. A kit for making a tiltable solar disk light assembly, the kit consisting of a tiltable solar disk light according to claim 1 , and comprising: (a) a tiltable solar light comprising: a light body comprising a housing, the housing containing lighting components comprising solar cells for harvesting solar energy; a rechargeable battery for storing the harvested solar energy; LEDs for emitting light; a switch having an ON position and an OFF position for enabling and disabling electrical power delivery to the LEDs from the battery; and wiring and driver electronics for operably connecting the solar cells, battery, switch, and LEDs and configured to deliver electrical power to the LEDs from the battery when the switch is in the ON position and to cut off power to the LEDs when the switch is in the OFF position; the light body further comprising a pair of pegs extending from the housing, the pegs in a co-axial arrangement to form an axis of rotation for the light body; a frame defining an opening for receiving the light body, the frame having an inner circumference around the opening, and two holes in the inner circumference on opposite sides of the opening for receiving the pair of pegs and tiltably supporting the light body, the opening being sized and shaped to define a first clearance gap around the light body to permit the light body to tilt within the frame about the axis of rotation formed by the pegs; and (b) a pair of blades configured to be interlocked together to form a landscape spike which is configured to be removably attached to the frame and also configured for insertion into the ground, thereby affixing the tiltable solar disk light to the ground. 9. The kit for making a tiltable solar disk light assembly of claim 8 wherein the blades comprise curved arms for connecting the spike to the frame, the curved arms configured to define a second clearance gap between the spike and the frame to permit the disk light body to tilt within the frame about the axis of rotation formed by the pegs. 10. The kit for making a tiltable solar disk light assembly of claim 9 wherein the disk light body may be tilted up to 35 degrees from horizontal relative to the frame until it contacts an arm. 11. The kit for making a tiltable solar disk light assembly of claim 9 wherein the disk light body may be tilted up to 40 degrees from horizontal relative to the frame until it contacts an arm. 12. The kit for making a tiltable solar disk light assembly of claim 9 wherein the disk light body may be tilted up to 45 degrees from horizontal relative to the frame until it contacts an arm. 13. The kit for making a tiltable solar disk light assembly of claim 9 wherein the disk light body may be tilted up to 50 degrees from horizontal relative to the frame until it contacts an arm. 14. A tiltable solar disk light kit, the kit comprising: a disk light body comprising a disk-shaped housing, the housing containing lighting components comprising solar cells for harvesting solar energy and detecting ambient light; a rechargeable battery for storing the harvested solar energy; LEDs for emitting light; a latching pushbutton switch having an ON position and an OFF position for enabling and disabling electrical power delivery to the LEDs from the battery; and wiring and driver electronics for operably connecting the solar cells, battery, switch, and LEDs and configured to deliver electrical power to the LEDs from the battery when the switch is in the ON position and the solar cells are not detecting ambient light and to cut off power to the LEDs when the switch is in the OFF position or the solar cells are detecting ambient light; the disk light body further comprising a pair of pegs extending from the housing, the pegs in a co-axial arrangement to form an axis of rotation for the disk light body; a frame defining a circular an opening for receiving the disk light body, two holes being formed in relation to the circular opening for receiving the pair of pegs and tiltably supporting the disk light body, the circular opening being sized and shaped to define a first clearance gap around the disk light body to permit the disk light body to tilt within the frame about the axis of rotation formed by the pegs; a pair of tapering blades having slots formed therein such that they can be interlocked together to form a landscape spike insertable into the ground, the blades also having integrally-formed arms, the landscape spike removably connectable to the frame by the arms; the ar