Belt splicing apparatus and method

What is claimed is: 1. A portable conveyor belt splicing apparatus comprising: upper and lower platens for clamping belt ends therebetween; upper and lower heaters operable to heat the upper and lower platens; a power supply circuit operably coupled to the upper and lower heaters for energizing the upper and lower heaters to splice the belt ends, the power supply circuit adapted to be electrically connected to either one of a high power standard power supply and a low power standard power supply; and the power supply circuit being configured such that predetermined dwell characteristics for a belt splicing operation generated by the energized upper and lower heaters are the same regardless of whether the power supply circuit is connected to the high power standard power supply or the low power standard power supply, wherein the power supply circuit is configured to alternate between providing more power to the upper heater than the lower heater and providing more power to the lower heater than the upper heater during a warm-up stage of the belt splicing operation in response to the power supply circuit being connected to the low power standard power supply. 2. The conveyor belt splicing apparatus of claim 1 wherein the power supply circuit is configured to operate the upper and lower heaters according to a first warm-up mode in response to the power supply being connected to the high power standard power supply and the power supply circuit is configured to operate the upper and lower heaters according to a different, second warm-up mode in response to the power supply being connected to the low power standard power supply. 3. The conveyor belt splicing apparatus of claim 2 wherein the first warm-up mode lasts for a first time period and the second warm-up mode lasts for a second time period that is longer than the first time period. 4. The conveyor belt splicing apparatus of claim 1 wherein the power supply circuit is further configured to energize the upper heater and the lower heater together during a warm-up stage of the belt splicing operation in response to the power supply circuit being connected to the high power standard power supply. 5. The conveyor belt splicing apparatus of claim 1 wherein the power supply circuit is configured to provide more power to the upper heater than the lower heater by providing power to the upper heater and not providing power to the lower heater, the power supply circuit being further configured to provide more power to the lower heater than the upper heater by providing power to the lower heater and not providing power to the upper heater. 6. The conveyor belt splicing apparatus of claim 1 further comprising at least one cord for connecting the power supply circuit to the high power standard power supply and the low power standard power supply, the power supply circuit being configured to determine whether the power supply circuit is connected to the high power standard power supply or the low power standard power supply based at least in part on the at least one cord. 7. The conveyor belt splicing apparatus of claim 1 wherein the power supply circuit is adapted to be connected to a high power standard power supply providing one of the following power supplies: single phase, 230 volt, 16 amp; single phase, 230 volt, 30 amp; three phase, 230 volt, 16 amp; and three-phase, 400volt, 16 amp; and the power supply circuit is adapted to be connected to a low power standard power supply providing one of the following power supplies: single phase, 110 volt, 15 amp; single phase, 110 volt, 20 amp; and single phase, 230 volt, 10 amp. 8. The conveyor belt splicing apparatus of claim 1 wherein the power supply circuit is adapted to be connected to a high power standard power supply providing one of the following power supplies: single phase, 230 volt, 30 amp; three phase, 400 volt, 16 amp; three phase, 400 volt; three phase, 460 volt; and the power supply circuit is adapted to be connected to a low power standard power supply providing one of the following power supplies: single phase, 230 volt, 16 amp; and three phase, 230 volt, 16 amp. 9. The conveyor belt splicing apparatus of claim 1 wherein the power supply circuit is configured to operate the upper and lower heaters according to a first warm-up mode in response to the power supply being connected to the high power standard power supply and the power supply circuit is configured to operate the upper and lower heaters according to a different, second warm-up mode in response to the power supply being connected to the low power standard power supply, wherein the first warm-up mode lasts for a first time period and the second warm-up mode lasts for a second time period that is longer than the first time period. 10. A portable conveyor belt splicing apparatus comprising: upper and lower platens for clamping belt ends therebetween; upper and lower heaters operable to heat the upper and lower platens; a power supply circuit operably coupled to the upper and lower heaters for energizing the upper and lower heaters to splice the belt ends, the power supply circuit adapted to be electrically connected to either one of a high power standard power supply and a low power standard power supply; and the power supply circuit being configured such that predetermined dwell characteristics for a belt splicing operation generated by the energized upper and lower heaters are the same regardless of whether the power supply circuit is connected to the high power standard power supply or the low power standard power supply, wherein the power supply circuit is configured to alternate between providing more power to the upper heater than the lower heater and providing more power to the lower heater than the upper heater during a dwell stage of the belt splicing operation regardless of whether the power supply circuit is connected to the high power standard power supply or the low power standard power supply. 11. The conveyor belt splicing apparatus of claim 10 wherein the dwell characteristics include a dwell time such that the upper and lower platens are heated for a dwell time that is the same regardless of whether the power supply circuit is connected to the high power standard power supply or the low power standard power supply. 12. The conveyor belt splicing apparatus of claim 10 wherein the dwell characteristics include dwell temperatures for the upper and lower platens such that the upper and lower platens each have a dwell temperature that is the same regardless of whether the power supply circuit is connected to the high power standard power supply or the low power standard power supply. 13. The conveyor belt splicing apparatus of claim 10 further comprising an air pump and at least one inflatable bladder connected to the air pump; and the dwell characteristics include a dwell pressure and the power supply circuit is configured to control operation of the air pump to inflate the at least one bladder and apply the dwell pressure to the belt ends that is the same whether the power supply circuit is connected to the high power standard power supply or the low power standard power supply. 14. The conveyor belt splicing apparatus of claim 10 wherein the power supply circuit is configured to provide a predetermined power to one of the upper and lower heaters during a high-power portion of the dwell stage of the belt splicing operation, the power supply circuit configured to provide a power less than the predetermined power to the one of the upper and lower heaters during a low-power portion of the dwell stage of the belt splicing operation, wherein the power su