Robot and arm assembly thereof

What is claimed is: 1. An arm assembly of a robot comprising a chest, the arm assembly comprising: a servo coupled to the chest, comprising an output shaft; an upper arm driven by the servo; a forearm rotatably coupled to the upper arm; a forearm transmission member comprising a first end rotatable with respect to the chest and a second end coupled to the forearm, the upper arm, the forearm and the forearm transmission member being arranged in such a way that the forearm rotates when the upper arm rotates with respect to the chest; a rotary joint fixed to the output shaft and the upper arm; and a fixed post securely connected to the chest, the first end of the forearm transmission mechanism being rotatably coupled to the fixed post; wherein the forearm defines a recess, the forearm transmission mechanism comprises a sliding post at the second end that is movably received in the recess, the sliding post and the recess are configured in such a way that the forearm transmission mechanism pulls the forearm to rotate with respect to the upper arm when the upper arm starts to rotate upward from an original position; wherein the forearm defines a sliding groove that is in communication with the recess, the sliding post, the recess and the sliding groove are configured in such way that the sliding post moves out of the recess and into the sliding groove after the forearm has rotated for a predetermined angle. 2. The arm assembly of claim 1 , further comprising a fourth elastic member configured to apply a restoring force to the forearm so as to drive the forearm to rotate such that the arm assembly returns back to a fully extended state, after the upper arm has rotated for a preset angle. 3. The arm assembly of claim 1 , further comprising a hand that is connected to an end of the forearm and rotatable about a first axis extending along a lengthwise direction of the forearm and rotatable about a second axis that is perpendicular to the first axis, and a hand transmission mechanism configured to transmit motion from the servo to the hand so as to drive the hand to rotate with respect to the forearm, and the forearm comprises a protrusion that is configured in such a way that the protrusion applies a push force to the hand when the hand rotates about the second axis and comes into contact with the protrusion such that the hand extends with respect to the forearm. 4. The arm assembly of claim 3 , wherein the hand comprises a third elastic member configured to apply a restoring force to the hand to rotate the hand about the second axis from an extension state to an original state. 5. The arm assembly of claim 3 , further comprising a hand shield rotatably connected to the forearm and a fifth elastic member that is connected to the forearm and configured to apply a restoring force to the hand shield when the hand rotates from the extension state to the original state. 6. A robot comprising a chest and an arm assembly, the arm assembly comprising: a servo coupled to the chest, comprising an output shaft; an upper arm driven by the servo; a forearm rotatably coupled to the upper arm; a forearm transmission member comprising a first end rotatable with respect to the chest and a second end coupled to the forearm, the upper arm, the forearm and the forearm transmission member being arranged in such a way that the forearm rotates when the upper arm rotates with respect to the chest; a rotary joint fixed to the output shaft and the upper arm; and a fixed post securely connected to the chest, the first end of the forearm transmission mechanism being rotatably coupled to the fixed post; wherein the forearm defines a recess, the forearm transmission mechanism comprises a sliding post at the second end that is movably received in the recess, the sliding post and the recess are configured in such a way that the forearm transmission mechanism pulls the forearm to rotate with respect to the upper arm when the upper arm starts to rotate upward from an original position; wherein the forearm defines a sliding groove that is in communication with the recess, the sliding post, the recess and the sliding groove are configured in such way that the sliding post moves out of the recess and into the sliding groove after the forearm has rotated for a predetermined angle. 7. An arm assembly of a robot comprising a chest, the arm assembly comprising: a servo coupled to the chest; an upper arm driven by the servo; a forearm rotatably coupled to the upper arm; and a forearm transmission member comprising a first end rotatable with respect to the chest and a second end coupled to the forearm, the upper arm, the forearm and the forearm transmission member being arranged in such a way that the forearm rotates when the upper arm rotates with respect to the chest; wherein the servo drives the upper arm to produce a first rotation of the upper arm with respect to the chest and a second rotation of the forearm with respect to the upper arm in a same direction as the first rotation; wherein the forearm defines a recess, the forearm transmission mechanism comprises a sliding post at the second end that is movably received in the recess, the sliding post and the recess are configured in such a way that the forearm transmission mechanism pulls the forearm to rotate with respect to the upper arm when the upper arm starts to rotate upward from an original position. 8. The arm assembly of claim 7 further comprising a rotary joint, wherein the servo comprises an output shaft, the rotary joint is fixed to the output shaft and the upper arm. 9. The arm assembly of claim 8 further comprising a fixed post securely connected to the chest, wherein the first end of the forearm transmission mechanism is rotatably coupled to the fixed post. 10. The arm assembly of claim 7 , wherein the forearm defines a sliding groove that is in communication with the recess, the sliding post, the recess and the sliding groove are configured in such way that the sliding post moves out of the recess and into the sliding groove after the forearm has rotated for a predetermined angle. 11. The arm assembly of claim 10 , further comprising a fourth elastic member configured to apply a restoring force to the forearm so as to drive the forearm to rotate such that the arm assembly returns back to a fully extended state, after the upper arm has rotated for a preset angle. 12. The arm assembly of claim 7 , further comprising a hand that is connected to an end of the forearm and rotatable about a first axis extending along a lengthwise direction of the forearm and rotatable about a second axis that is perpendicular to the first axis, and a hand transmission mechanism configured to transmit motion from the servo to the hand so as to drive the hand to rotate with respect to the forearm, and the forearm comprises a protrusion that is configured in such a way that the protrusion applies a push force to the hand when the hand rotates about the second axis and comes into contact with the protrusion such that the hand extends with respect to the forearm. 13. The arm assembly of claim 12 , wherein the hand comprises a third elastic member configured to apply a restoring force to the hand to rotate the hand about the second axis from an extension state to an original state. 14. The arm assembly of claim 12 , further comprising a hand shield rotatably connected to the forearm and a fifth elastic member that is connected to the forearm and configured to apply a restoring force to the hand shield when the hand rotates from the extension state to the original state. 15. The arm assembly of claim 7 , where