Ingot cutting apparatus and ingot cutting method

The invention claimed is: 1. An ingot cutting apparatus including a cutting table on which an ingot is horizontally placed, and an endless-belt blade provided in a tensioned state between pulleys, the blade having a blade-abrasive-grain portion and a blade base, the ingot cutting apparatus cutting the ingot by relatively feeding the blade from above to below against the ingot while driving to rotate the blade by rotating the pulleys and supplying a coolant to the blade, the ingot cutting apparatus comprising at least two coolant pockets storing the coolant to be supplied to the blade and a pair of static pressure pads having coolant-spraying outlets through which coolant is sprayed toward the blade, the static pressure pads being arranged opposite one another at a predetermined interval so as to allow the blade to pass through, wherein the blade-abrasive-grain portion is brought into contact with the coolant stored in the at least two coolant pockets by causing the blade-abrasive-grain portion of the blade to travel through a groove portion provided at an upper portion of the at least two coolant pockets while driving to rotate the blade so that the coolant is supplied to the blade-abrasive-grain portion of the blade, the at least two coolant pockets are arranged below the static pressure pads, and the coolant sprayed through the coolant-spraying outlets of the static pressure pads is stored in the at least two coolant pockets, wherein at least one of the at least two coolant pockets is arranged at respective positions of a front and a rear of the ingot with respect to a direction of driving to rotate the blade, and wherein a number of the coolant pockets is the same as a number of the arranged static pressure pads. 2. The ingot cutting apparatus according to claim 1 , wherein the pulleys are configured to be rotatable about an axis thereof in both directions, and the direction of driving to rotate the blade can be changed to cut the ingot. 3. The ingot cutting apparatus according to claim 1 , wherein the coolant is pure water having a specific resistance of 17 MΩ·cm or more. 4. The ingot cutting apparatus according to claim 1 , further comprising an ultrasonic wave propagation means for applying an ultrasonic wave to the coolant stored in the at least two coolant pockets. 5. The ingot cutting apparatus according to claim 1 , wherein the ingot is a silicon ingot having a diameter of 300 mm or more. 6. The ingot cutting apparatus according to claim 1 , wherein the coolant-spraying outlets are configured to spray coolant toward the blade in a direction substantially perpendicular to the direction of driving to rotate the blade when the blade-abrasive-grain portion of the blade travels through the groove portion of the at least two coolant pockets. 7. An ingot cutting method including: horizontally placing an ingot on a cutting table; providing an endless-belt blade in a tensioned state between pulleys, the blade having a blade-abrasive-grain portion and a blade base; driving to rotate the blade by rotating the pulleys; and cutting the ingot by relatively feeding the blade from above to below against the ingot while supplying a coolant to the blade, wherein a pair of static pressure pads having coolant-spraying outlets through which coolant is sprayed toward the blade are arranged opposite one another at a predetermined interval so as to allow the blade to pass through, at least two coolant pockets for supplying the coolant to the blade are arranged below the static pressure pads, the coolant sprayed through the coolant-spraying outlets of the static pressure pads is stored in the at least two coolant pockets, and the coolant is supplied to the blade-abrasive-grain portion of the blade in such a manner that the blade-abrasive-grain portion is brought into contact with the coolant stored in the at least two coolant pockets by causing the blade-abrasive-grain portion of the blade to travel through a groove portion provided at an upper portion of the at least two coolant pockets while driving to rotate the blade, wherein at least one of the at least two coolant pockets is arranged at respective positions of a front and a rear of the ingot with respect to a direction of driving to rotate the blade, and the coolant is supplied through the at least two coolant pockets, and wherein a number of the coolant pockets is the same as a number of the arranged static pressure pads. 8. The ingot cutting method according to claim 7 , wherein after the ingot is cut with the blade driven to rotate in one direction, the direction of driving to rotate the blade is changed into a direction opposite to the one direction, and thereafter the ingot is continuously cut or a next ingot is cut. 9. The ingot cutting method according to claim 7 , wherein pure water having a specific resistance of 17 MΩ·cm or more is used as the coolant. 10. The ingot cutting method according to claim 7 , an ultrasonic wave is applied to the coolant stored in the at least two coolant pockets, and the blade-abrasive-grain portion is cleaned by the coolant to which the ultrasonic wave is applied while driving to rotate the blade. 11. The ingot cutting method according to claim 7 , wherein a silicon ingot having a diameter of 300 mm or more is used as the ingot. 12. The ingot cutting method according to claim 7 , further comprising spraying coolant from the coolant-spraying outlets toward the blade in a direction substantially perpendicular to the direction of driving to rotate the blade when the blade-abrasive-grain portion of the blade travels through the groove portion of the at least two coolant pockets.