Oil-flooded screw compressor system and method for modifying the same

The invention claimed is: 1. An oil-flooded screw compressor system for compressing a gas to be compressed which is a compatible gas with lubricating oil, comprising: a screw compressor which includes: a male screw rotor and a female screw rotor each having a screw part and shaft portions formed on both ends of the screw part; a housing having a screw chamber accommodating the screw parts inside and a bearing chamber accommodating the shaft portions inside; and a bearing disposed in the bearing chamber, for rotatably supporting the shaft portions; a first lubricating oil supply system for supplying lubricating oil to the screw parts; and a second lubricating oil supply system for supplying the lubricating oil to the bearing, wherein the first lubricating oil supply system includes: a gas-liquid separator configured to introduce discharge gas of the screw compressor therein and to separate the lubricating oil from the discharge gas; a first supply flow passage formed through a housing wall which constitutes the housing, the first supply flow passage having an opening on an outer surface of the housing wall and being in communication with the screw chamber; and a first supply path connected to a lubricating-oil storage region of the gas-liquid separator and to the opening of the first supply flow passage, and wherein the second lubricating oil supply system includes: a lubricating oil reservoir; a second supply flow passage formed through the housing wall, the second supply flow passage having an opening on the outer surface of the housing wall and being in communication with the bearing chamber; a second supply path connected to the lubricating oil reservoir and to the opening of the second supply flow passage; a first discharge flow passage formed through the housing wall, the first discharge flow passage being in communication with the bearing chamber and having an opening on the outer surface of the housing wall; and a discharge path connected to the lubricating oil reservoir and to the opening of the first discharge flow passage, wherein a first branch discharge flow passage is formed so as to communicate with the first discharge flow passage and the screw chamber, wherein the first branch discharge flow passage and a part of the first discharge flow passage having an opening on the outer surface of the housing wall together constitute a linear through hole, and wherein the first branch discharge flow passage of the linear through hole is closed by a first closure member. 2. The oil-flooded screw compressor system according to claim 1 , wherein a tapered female threaded hole is formed on a side of the opening of the first branch discharge flow passage which faces the first discharge flow passage, and wherein the first closure member has a tapered male thread formed thereon, the tapered male thread being engageable with the tapered female threaded hole. 3. The oil-flooded screw compressor system according to claim 1 , wherein the lubricating oil reservoir is a sealed tank, and wherein the oil-flooded screw compressor system further comprises: a suction path connected to an inlet port of the screw compressor; a suction branch path branched from the suction path and connected to the lubricating oil reservoir; a return pipe connected to the lubricating oil reservoir and to a lubricating oil storage region of the gas-liquid separator; an open-close valve disposed in the return pipe; an oil-surface level sensor provided for the lubricating oil reservoir; and a controller which is configured to receive a detection value from the oil-surface level sensor and to open the open-close valve when the detection value is at most a threshold. 4. The oil-flooded screw compressor system according to claim 3 , further comprising: a discharge gas path disposed in the housing; a temperature sensor for detecting a temperature of the discharge gas flowing through the discharge gas path; and a flow-rate adjustment valve disposed in the first supply path, wherein the controller is configured to receive a detection value of the temperature sensor and to adjust an opening degree of the flow-rate adjustment valve to adjust the temperature of the discharge gas. 5. The oil-flooded screw compressor system according to claim 1 , wherein the gas to be compressed is a hydrocarbon gas. 6. The oil-flooded screw compressor system according to claim 5 , wherein the gas to be compressed is a hydrocarbon gas having a molar mass of at least 44. 7. An oil-flooded screw compressor, comprising: a male screw rotor and a female screw rotor each having a screw part and shaft portions formed on both ends of the screw part; a housing having a screw chamber accommodating the screw parts inside and a bearing chamber accommodating the shaft portions inside; a first supply flow passage formed through a housing wall which constitutes the housing so as to be in communication with the screw chamber and configured to supply a first oil to the screw chamber; a second supply flow passage formed through the housing wall so as to be in communication with the bearing chamber and configured to supply a second oil to the bearing chamber; a discharge flow passage formed through the housing wall so as to be in communication with the bearing chamber and configured to discharge the second oil from the bearing chamber; and a closure member disposed in a through hole penetrating the housing wall to radially extend to the screw chamber, wherein the discharge flow passage includes: a radial passage formed by a portion of the through hole positioned opposite to the screw chamber across the closure member; and an axial passage axially extending in the housing wall to intersect with the radial passage so as to be communicated with the bearing chamber and the radial passage. 8. A method of modifying an oil-flooded screw compressor which comprises: a male screw rotor and a female screw rotor each having a screw part and shaft portions formed on both ends of the screw part; a housing having a housing wall to form a screw chamber accommodating the screw parts inside and a bearing chamber accommodating the shaft portions inside; and an axial passage axially extending in the housing wall to be communicated with the bearing chamber, the method comprising: forming a through hole which penetrates the housing wall to radially extend to the screw chamber such that the through hole intersects with the axial passage at an intersection; and disposing a closure member in the through hole at a position between the screw chamber and the intersection such that a radial passage formed by a portion of the through hole positioned opposite to the screw chamber across the closure member constitutes a discharge flow passage for discharging oil from the bearing chamber together with the axial passage. 9. The method of modifying an oil-flooded screw compressor system according to claim 8 , connecting the discharge flow passage to a lubricating oil reservoir for storing the oil to be supplied to the bearing chamber via a flow path. 10. The method of modifying an oil-flooded screw compressor system according to claim 9 , wherein the lubricating oil reservoir is a tank inside of which is sealable, wherein the method further comprises: providing a suction branch path which branches from a suction path connected to an inlet port of the screw compressor and connects to the lubricating oil reservoir; providing a return pipe to be connected to the lubricating oil reservoir and to a lubricating-oil storage region of a gas-liquid separator configured to introduce discharge gas of the screw compressor therein and to separate the lubricating oil f