Blender

The invention claimed is: 1. A blender comprising: a blender body including an external cylinder, a grinding blade, and a blade driving portion rotating the grinding blade; and an internal cylinder unit including an internal cylinder, disposed in the external cylinder, in which the grinding blade is disposed, and having an internal side surface, on which at least one projection is formed, and an internal cylinder driving portion rotating the internal cylinder, wherein a blade rotation shaft of the blade driving portion is axially and rotationally mounted in a hollow, formed in an internal cylinder rotation shaft of the internal cylinder driving portion, to independently rotate the blade rotation shaft and the internal cylinder rotation shaft, wherein a first intermediate rotation shaft and a second intermediate rotation shaft surrounding the first intermediate rotation shaft are installed in the external cylinder, and wherein the first intermediate rotation shaft connects the blade rotation shaft of the blade driving portion and the grinding blade, and the second intermediate rotation shaft connects the internal cylinder rotation shaft of the internal cylinder driving portion and the internal cylinder. 2. The blender of claim 1 , wherein a lower portion of the first intermediate rotation shaft is key-coupled to the blade rotation shaft of the blade driving portion, and an upper portion of the first intermediate rotation shaft is key-coupled to the grinding blade, and wherein a lower portion of the second intermediate rotation shaft is key-coupled to the internal cylinder rotation shaft of the internal cylinder unit, and an upper portion of the second intermediate rotation shaft is key-coupled to the internal cylinder. 3. The blender of claim 1 , wherein the internal cylinder driving portion rotates the internal cylinder with an internal cylinder driving motor in a direction opposing a rotational direction of the grinding blade, and includes a blocking member preventing the internal cylinder from rotating in the same direction as the rotational direction of the grinding blade, and wherein the blocking member has a ratchet structure. 4. The blender of claim 3 , wherein the blocking member is mounted on the internal cylinder rotation shaft. 5. The blender of claim 3 , wherein the blocking member is mounted on a motor shaft of the internal cylinder driving motor. 6. The blender of claim 3 , wherein the internal cylinder has a side portion in which a dehydration hole is formed, and wherein the internal cylinder driving portion includes an internal cylinder driving connection portion connecting the internal cylinder rotation shaft, the internal cylinder driving motor, and the internal cylinder rotation shaft and the internal cylinder driving motor to each other, and a gear-coupled structure of the internal cylinder driving connection portion varies such that the internal cylinder has different rotational speeds during grinding of blending objects and during dehydration of the blending objects. 7. The blender of claim 6 , wherein the internal cylinder driving connection portion has a structure in which a small driving gear and a large driving gear is mounted on an internal cylinder driving shaft connected to the internal cylinder driving motor, and a large driven gear and a small driven gear are mounted on the internal cylinder rotation shaft or an intermediate rotation shaft rotating in conjunction with the internal cylinder rotation shaft, and wherein the internal cylinder driving shaft reciprocates in an axial direction thereof, or the internal cylinder rotation shaft or the intermediate rotation shaft reciprocates in an axial direction thereof, and the large driving gear and the small driven gear are not gear-coupled to each other when the small driving gear and the large driven gear are gear-coupled to each other, and the small driving gear and the large driven gear are not gear-coupled to each other when the large driving gear and the small driven gear are gear-coupled to each other. 8. The blender of claim 7 , wherein the internal cylinder driving connection portion includes a shaft moving member configured to move the internal cylinder driving shaft in an axial direction thereof, and wherein the internal cylinder driving shaft has one end portion, key-coupled to a motor shaft of the internal cylinder driving motor to rotate in conjunction with shaft rotation of the motor shaft and slidably coupled to the motor shaft of the internal cylinder driving motor to be movable in an axial direction of the motor shaft, and the other end portion axially and rotatably connected to the shaft moving member. 9. The blender of claim 3 , wherein the internal cylinder has a side portion in which a dehydration hole is formed, and wherein the internal cylinder driving portion includes an internal cylinder driving connection portion connecting the internal cylinder rotation shaft, the internal cylinder driving motor, and the internal cylinder rotation shaft and the internal cylinder driving motor to each other, and the internal cylinder driving motor comprises a plurality of internal cylindrical driving motors such that the internal cylinder has different rotational speeds during grinding of blending objects and during dehydration of the blending objects. 10. The blender of claim 9 , wherein one of the plurality of internal cylinder driving motors is a first motor configured to supply rotation driving power to the internal cylinder during grinding of the blending objects, and another internal cylinder driving motor is a second motor configured to supply rotational driving power to the internal cylinder in a direction opposing a direction of the first motor. 11. The blender of claim 1 , wherein the blade driving portion and the internal cylinder driving portion are controlled by a controller, and wherein the controller controls the blade driving portion and the internal cylinder driving portion in a grinding mode and a dehydration mode. 12. The blender of claim 11 , wherein in the grinding mode, the blade driving portion and the internal cylinder driving portion are controlled to repeatedly perform an operating pattern, in which the internal cylinder reversely rotates in a direction opposing a rotation direction of the grinding blade and is then stopped, and an operating pattern in which the internal cylinder rotates reversely and then changes speed. 13. The blender of claim 11 , wherein in the dehydration mode, the blade driving portion and the internal cylinder driving portion are controlled to continuously rotate the internal cylinder for a certain time after rotation of the grinding blade is stopped. 14. The blender of claim 1 , further comprising: a vacuum unit mounted in the blender body and configured to establish vacuum in the internal cylinder, wherein the vacuum unit comprises: a suction pipe communicating with the internal cylinder; and a vacuum driving portion communicating with the suction pipe.