High-speed powered hand tool with improved motor cooling

What is claimed is: 1 . A surgical device comprising: a handpiece comprising a distal end and a proximal end; a chamber formed within said handpiece; a motor disposed within said chamber; an exhaust port in fluid communication with said chamber, said exhaust port being configured for attachment to a suction source so as to apply suction to said chamber; and at least one inlet port in fluid communication with said chamber, said at least one inlet port being configured to allow ambient air to be drawn into said chamber. 2 . A surgical device according to claim 1 wherein said exhaust port comprises a hollow tube mounted to and projecting out of said handpiece, wherein the lumen of said hollow tube is in fluid communication with said chamber; and wherein said hollow tube is configured to receive a suction hose connected to a suction source. 3 . A surgical device according to claim 1 wherein said inlet port comprises at least one passageway formed in said handpiece. 4 . A surgical device according to claim 1 wherein said chamber is defined by at least one longitudinally-extending wall, said motor is defined by at least one longitudinally-extending wall, and further wherein at least one longitudinally-extending gap is formed between said at least one longitudinally-extending wall of said motor and said at least one longitudinally-extending wall of said chamber; and wherein said surgical device is configured so that when suction is applied to said exhaust port, ambient air is drawn into said at least one inlet port, along said at least one longitudinally-extending gap and out said exhaust port. 5 . A surgical device according to claim 4 wherein said surgical device is configured so that said at least one longitudinally-extending gap extends along substantially the entire length of said motor. 6 . A surgical device according to claim 4 wherein one of said exhaust port and said at least one inlet port is disposed at said distal end of said handpiece, and the other of said exhaust port and said at least one inlet port is disposed at said proximal end of said handpiece. 7 . A surgical device according to claim 4 wherein said exhaust port and said at least one inlet port are both disposed at one of said distal end of said handpiece and said proximal end of said handpiece. 8 . A surgical device according to claim 7 wherein said at least one longitudinally-extending gap comprises a first longitudinally-extending gap and a second longitudinally-extending gap, and further wherein said exhaust port is in fluid communication with said first longitudinally-extending gap, said at least one inlet port is in fluid communication with said second longitudinally extending gap, and further wherein said first longitudinally-extending gap is in fluid communication with said second longitudinally-extending gap at a location which is remote from said one of said distal end of said handpiece and said proximal end of said handpiece. 9 . A surgical device according to claim 8 wherein said first longitudinally-extending gap is in fluid communication with said second longitudinally-extending gap at a manifold. 10 . A surgical device according to claim 9 wherein said manifold extends circumferentially within said handpiece. 11 . A surgical device according to claim 8 wherein said motor is defined by a plurality of longitudinally-extending flat walls, and further wherein a plurality of longitudinally-extending gaps are formed between said plurality of longitudinally-extending flat walls of said motor and said at least one longitudinally-extending wall of said chamber. 12 . A surgical device according to claim 1 wherein said motor comprises a heat-conductive jacket. 13 . A surgical device according to claim 12 wherein said chamber is defined by at least one longitudinally-extending wall, said heat-conductive jacket is defined by at least one longitudinally-extending wall, and further wherein at least one longitudinally-extending gap is formed between said at least one longitudinally-extending wall of said heat-conductive jacket and said at least one longitudinally-extending side wall of said chamber; wherein said surgical device is configured so that when suction is applied to said exhaust port, ambient air is drawn into said at least one inlet port, along said at least one longitudinally-extending gap and out said exhaust port; and wherein said surgical device is configured so that said at least one longitudinally-extending gap extends along substantially the entire length of said heat-conductive jacket. 14 . A surgical device according to claim 12 wherein said chamber is defined by at least one longitudinally-extending wall, said heat-conductive jacket is defined by at least one longitudinally-extending wall, and further wherein at least one longitudinally-extending gap is formed between said at least one longitudinally-extending wall of said heat-conductive jacket and said at least one longitudinally-extending side wall of said chamber; wherein said surgical device is configured so that when suction is applied to said exhaust port, ambient air is drawn into said at least one inlet port, along said at least one longitudinally-extending gap and out said exhaust port; wherein said exhaust port and said at least one inlet port are both disposed at one of said distal end of said handpiece and said proximal end of said handpiece; wherein said at least one longitudinally-extending gap comprises a first longitudinally-extending gap and a second longitudinally-extending gap, and further wherein said exhaust port is in fluid communication with said first longitudinally-extending gap, said at least one inlet port is in fluid communication with said second longitudinally extending gap, and further wherein said first longitudinally-extending gap is in fluid communication with said second longitudinally-extending gap at a location which is remote from said one of said distal end of said handpiece and said proximal end of said handpiece; and wherein said heat-conductive jacket is defined by a plurality of longitudinally-extending flat walls, and further wherein a plurality of longitudinally-extending gaps are formed between said plurality of longitudinally-extending flat walls of said heat-conductive jacket and said at least one longitudinally-extending wall of said chamber. 15 . A surgical device according to claim 12 wherein said heat-conductive jacket is formed integral with at least one other element of said motor. 16 . A method for performing a procedure, the method comprising: providing a surgical device comprising: a handpiece comprising a distal end and a proximal end; a chamber formed within said handpiece; a motor disposed within said chamber; an exhaust port in fluid communication with said chamber, said exhaust port being configured for attachment to a suction source so as to apply suction to said chamber; and at least one inlet port in fluid communication with said chamber, said at least one inlet port being configured to allow ambient air to be drawn into said chamber; connecting said exhaust port to a suction source; and using the suction source to draw ambient air into said at least one inlet port and out said exhaust port. 17 . A method according to claim 16 wherein said chamber is defined by at least one longitudinally-extending wall, said motor is defined by at least one longitudinally-extending wall, and further wherein at least one longitudinally-extending gap is formed between said at least one longitudinally-extending wall of said motor