Positive-drive spiral conveyor

What is claimed is: 1. A spiral conveyor comprising: a conveyor belt including a series of belt rows and an inner side; a plurality of drive members configured to rotate about a vertical axis, each of the plurality of drive members having a generally vertical length and a ridge extending along the length and radially outward away from the vertical axis to a ridge top; wherein the ridge top is a constant first distance from the vertical axis in a first length of the drive member and decreases to a lesser second distance in a consecutive second length of the drive member and is constant at the second distance in a consecutive third length of the drive member; wherein the inner side of the conveyor belt between adjacent belt rows enters into initial driving engagement with the ridges in the first length and is driven without slip by the ridges on a helical path about the vertical axis along the first length, then along the second length, and next along the third length. 2. The spiral conveyor of claim 1 wherein the third length is greater than the first and second lengths. 3. A spiral conveyor comprising: a conveyor belt including a series of belt rows and an inner side; a drive tower having a vertical axis of rotation and an outer periphery; a plurality of drive members disposed on the outer periphery of the drive tower in radial planes intersecting the vertical axis of rotation; wherein each of the drive members includes a ridge that extends in length from an entry end and radially outward away from the vertical axis to a ridge top; wherein the drive tower imparts rotational motion about the vertical axis of rotation to the plurality of drive members; wherein the ridge top is a constant first radial distance from the vertical axis of rotation along a first length of the ridge extending from the entry end to a second length of the ridge and wherein the radial distance of the ridge top from the vertical axis of rotation along the second length decreases from the constant first radial distance to a lesser second radial distance at a third length of the ridge and wherein the radial distance of the ridge top from the vertical axis of rotation in the third length is constant at the lesser second radial distance; wherein the ridge engages the inner side of the conveyor belt between adjacent belt rows initially at the entry end and drives the conveyor belt without slip along a helical path about the vertical axis of rotation from the entry end sequentially along the first, second, and third lengths. 4. The spiral conveyor of claim 3 wherein the third length is greater than the first and second lengths. 5. A spiral conveyor comprising: a drive tower extending from a bottom to a top and rotating about a vertical axis; a plurality of circumferentially spaced drive members extending in length from the bottom to the top of the drive tower; wherein each of the drive members includes an outwardly projecting ridge whose distance from the vertical axis varies from the bottom to the top of the drive tower; wherein each drive member includes an upper segment extending downward from the top of the drive tower and a lower segment at the bottom of the drive tower; wherein the ridge in the lower segment is tapered along a first portion of its length and the distance of the ridge from the vertical axis in a second portion of the lower segment is constant at a first distance below the first portion; wherein the distance of the ridge from the vertical axis in the upper segment is constant at a second distance less than the first distance; a conveyor belt positively driven without slip on a helical path upward around the drive tower from the lower segment at the bottom and along the upper segment by the ridges of the drive members engaging an inside edge of the conveyor belt. 6. The spiral conveyor of claim 5 wherein the third length is greater than the first and second lengths. 7. The spiral conveyor of claim 5 wherein the inside edge of the conveyor belt includes outwardly extending teeth engaged by the ridges of the drive members to drive the conveyor belt on the helical path.