Screw compressor

What is claimed is: 1. A screw compressor, comprising: a casing including a cylindrically-shaped cylinder, a main body surrounding a vicinity of the cylinder, and a high-pressure fluid passage provided between the main body and the cylinder; and a screw rotor including a plurality of helical grooves, the screw rotor being inserted into the cylinder to define fluid chambers, and a fluid being sucked into the fluid chambers to compress the fluid in the screw compressor; a discharge passage disposed in the casing, the discharge passage guiding the fluid that has been discharged from the fluid chambers to the high-pressure fluid passage; and at least one muffler space disposed in the casing, the at least one muffler space communicating with the discharge passage so as to reduce a pressure fluctuation of the fluid flowing from the discharge passage to the high-pressure fluid passage, the casing including a cylindrically-shaped bearing holder holding a bearing, the bearing supporting a drive shaft of the screw rotor, the bearing holder being fitted into an end of the cylinder, and the bearing holder having an outer peripheral surface facing an inner peripheral surface of the cylinder, and the at least one muffler space being configured as a recessed groove extending circumferentially along the bearing holder and being formed in at least one of the outer peripheral surface of the bearing holder, a portion of the inner peripheral surface of the cylinder, the portion facing the bearing holder, and the recessed groove constituting the at least one muffler space being formed over an entire periphery of the bearing holder. 2. The screw compressor of claim 1 , further comprising a plurality of gate rotors meshing with the respective plurality of helical grooves of the screw rotor, the discharge passage including a plurality of discharge passages, the discharge passages being disposed in the casing, and the discharge passages being formed so as to be respectively associated with the gate rotors, and all of the discharge passages communicating with a single one the same muffler space of the at least one muffler space. 3. The screw compressor of claim 2 , wherein the plurality of gate rotors include two gate rotors, and the plurality of helical grooves include an odd number of helical grooves, and the odd number of helical grooves are formed in the screw rotor. 4. A screw compressor, comprising: a casing including a cylindrically-shaped cylinder, a main body surrounding a vicinity of the cylinder, and a high-pressure fluid passage provided between the main body and the cylinder; and a screw rotor including a plurality of helical grooves, the screw rotor being inserted into the cylinder to define fluid chambers, and a fluid being sucked into the fluid chambers to compress the fluid in the screw compressor; a plurality of gate rotors meshing with the respective plurality of helical grooves of the screw rotor, a plurality of discharge passages disposed in the casing, the plurality of discharge passages guiding the fluid that has been discharged from the fluid chambers to the high-pressure fluid passage, and being equal in number to the gate rotors; a single muffler space disposed in the casing, the single muffler space communicating with the plurality of discharge passages so as to reduce a pressure fluctuation of the fluid flowing from the plurality of discharge passages to the high-pressure fluid passage; and the single muffler space being fluidly connected to all of the plurality of discharge passages. 5. The screw compressor of claim 4 , wherein the plurality of gate rotors include two gate rotors, and the plurality of helical grooves include an odd number of helical grooves, and the odd number of helical grooves are formed in the screw rotor.