Step system for elevating platform

The invention claimed is: 1. A step for a vertical surface of a utility bucket, the step comprising: a step body comprising a top, a bottom, a first side, and a second side, wherein the step is provided on the vertical surface of the utility bucket; at least two flanges, including a lower flange and an upper flange; a first notch and a second notch, wherein the first notch separates the upper flange from the lower flange on the first side and the second notch separates the upper flange from the lower flange on the second side, wherein the lower flange and the upper flange provide contact surfaces and are operable to bear compression loads, wherein the lower flange is integrally formed to the bottom, the first side, and the second side, of the step body, wherein the upper flange is integrally formed to the top, the first side, and the second side of the step body with an offset from the lower flange, the offset being approximately a thickness of the vertical surface and spanning a width of the step body from the first side to the second side, wherein the step is configured to be inserted into an opening of the vertical surface, wherein the lower flange is configured to contact an outer surface of the vertical surface when the upper flange contacts an inner surface of the vertical surface, and wherein the step is constructed to support a vertical load of an operator. 2. The step of claim 1 , wherein the step is operable to lock into the vertical surface by positioning the step in the opening of the vertical surface such that the upper flange contacts the inner surface of the vertical surface, and the lower flange contacts the outer surface of the vertical surface. 3. The step of claim 2 , wherein the step is configured such that when the step is locked into the vertical surface and the vertical load is applied to the step body, the at least two flanges are substantially in compression with the vertical surface. 4. The step of claim 2 , wherein the step further locks into the vertical surface by engaging a vertical surface cross-section via the opening of the vertical surface. 5. The step of claim 2 , wherein the at least two flanges close the opening of the vertical surface when the step is locked into the vertical surface. 6. The step of claim 1 , wherein the step is operable to be pivoted via the first notch or the second notch such that the first notch or the second notch is operable to be passed through the opening of the vertical surface. 7. The step of claim 1 , wherein the upper flange extends beyond the step body. 8. A step for a vertical surface of a utility bucket, the step comprising: a step body comprising a top, a bottom, a first side, and a second side, wherein the step is provided on the vertical surface of the utility bucket; at least two flanges, including a lower flange and an upper flange; a first notch and a second notch, wherein the first notch separates the upper flange from the lower flange on the first side and the second notch separates the upper flange from the lower flange on the second side, wherein the lower flange and the upper flange provide contact surfaces, wherein the lower flange and the upper flange are operable to bear compression loads, wherein the lower flange is integrally formed to the bottom, the first side, and the second side of the step, wherein the upper flange is integrally formed to the top, the first side, and the second side of the step with an offset from the lower flange, the offset being approximately a thickness of the vertical surface and spanning a width of the step body from the first side to the second side, wherein the step is configured to be inserted into an opening of the vertical surface, wherein the lower flange is configured to contact an outer surface of the vertical surface when the upper flange contacts an inner surface of the vertical surface, and wherein the step is constructed to support a vertical load of an operator. 9. The step of claim 8 , wherein the step is operable to lock into the vertical surface by positioning the step in the opening of the vertical surface such that the upper flange contacts the inner surface of the vertical surface, and the lower flange contacts the outer surface of the vertical surface. 10. The step of claim 9 , wherein the step is configured such that when the step is locked into the vertical surface and the vertical load is applied to the step body, the at least two flanges are substantially in compression with the vertical surface. 11. The step of claim 9 , wherein the step further locks into the vertical surface by engaging a vertical surface cross-section via the opening of the vertical surface. 12. The step of claim 9 , wherein the at least two flanges close the opening of the vertical surface when the step is locked into the vertical surface. 13. The step of claim 8 , wherein the step is operable to be pivoted via the first notch or the second notch such that the first notch or the second notch is operable to be passed through the opening of the vertical surface. 14. The step of claim 8 , wherein the upper flange extends beyond the step body. 15. The step of claim 8 , wherein the upper flange is approximately parallel to the lower flange before being inserted into the opening of the vertical surface and after being inserted into the opening of the vertical surface. 16. A step for a vertical surface of a utility bucket, the step comprising: a step body comprising a top, a bottom, a first side, and a second side, wherein the step is provided on the vertical surface of the utility bucket; at least two flanges, including a first flange and a second flange; a first notch and a second notch, wherein the first notch separates the first flange from the second flange on the first side and the second notch separates the first flange from the second flange on the second side, wherein the first flange and the second flange provide contact surfaces, wherein the first flange and the second flange are operable to bear compression loads; wherein the first flange is integrally formed to the bottom, the first side, and the second side of the step, wherein the second flange is integrally formed to the top, the first side, and the second side of the step with an offset from the first flange, the offset being approximately a thickness of the vertical surface and spanning a width of the step body from the first side to the second side, wherein the step is configured to be inserted into the vertical surface, wherein the first flange is configured to contact an outer surface of the vertical surface when the second flange contacts an inner surface of the vertical surface, wherein the second flange extends beyond the step body, and wherein the step is constructed to support a vertical load of an operator. 17. The step of claim 16 , wherein the step is operable to lock into the vertical surface by positioning the step in an opening of the vertical surface such that the second flange contacts the inner surface of the vertical surface, and the first flange contacts the outer surface of the vertical surface. 18. The step of claim 17 , wherein the step is configured such that when the step is locked into the vertical surface and the vertical load is applied to the step body, the at least two flanges are substantially in compression with the vertical surface. 19. The step of claim 17 , wherein the step further locks into the vertical surface by engaging a vertical surface cross-section via the opening of the vertical surface.