Double-headed swash type compressor and method for manufacturing cylinder block

The invention claimed is: 1. A double-headed swash compressor comprising: a cylinder block including an annular array of piston bores formed through the cylinder block, a plurality of pistons reciprocatingly received in the piston bores, a suction space formed in the cylinder block, and a shaft bore formed through the cylinder block, the shaft bore communicating with a plurality of refrigerant supply holes formed in the cylinder block, the plurality of refrigerant supply holes communicating with a plurality of compression chambers defined by the piston bores and the plurality of pistons; a first housing coupled to a first side of the cylinder block; a second housing coupled to a second side of the cylinder block; a shaft received in the shaft bore, the shaft including a passage formed in the shaft configured to receive a refrigerant, a refrigerant introduction hole in fluid communication with the suction space and configured to introduce the refrigerant into the passage, and a refrigerant discharge hole configured to discharge the refrigerant from the passage; a swash plate coupled to the shaft in an oblique position with respect to the shaft, the swash plate operatively coupled to the plurality of pistons; and a journal bearing disposed between an inner peripheral surface of the shaft bore and an outer peripheral surface of the shaft, the journal bearing formed entirety from a porous sintered material, wherein the outer peripheral surface of the shaft is spaced apart from the inner peripheral surface of the shaft bore by a first distance (a) when the shaft is inserted into the shaft bore, and wherein oil contained in the refrigerant is introduced into or stored in a space defined by the distance (a) between the outer peripheral surface of the shaft and the inner peripheral surface of the shaft bore so that an oil film is formed on the shaft. 2. The double-headed swash compressor of claim 1 , wherein the cylinder block includes a groove portion formed therein, the groove portion having a length greater than a length of the journal bearing and receiving the journal bearing therein. 3. The double-headed swash compressor of claim 2 , wherein a step is formed in the groove portion spaced from the journal bearing. 4. The double-headed swash compressor of claim 1 , wherein the journal bearing includes a plurality of through-holes formed therein, the plurality of through-holes aligned with the plurality of refrigerant supply holes, and wherein each of the plurality of through-holes and each of the plurality of refrigerant holes are formed obliquely with respect to the shaft bore. 5. The double-headed swash compressor of claim 1 , further comprising a coating layer disposed intermediate the outer peripheral surface of the shaft and an inner surface of the journal bearing. 6. The double-headed swash compressor of claim 5 , wherein the coating layer is a polytetrafluoroethylene (PTFE) coating. 7. The double-headed swash compressor of claim 1 , wherein the journal bearing has an air porosity in a range of about 5% to 20% of a total volume of the journal bearing. 8. The double-headed swash compressor of claim 1 , wherein the journal bearing has an air porosity of 7% of a total volume of the journal bearing. 9. The double-headed swash compressor of claim 1 , wherein the journal bearing is formed from at least one of copper, tin, and graphite. 10. The double-headed swash compressor of claim 1 , wherein the journal bearing is formed from a solid lubricant. 11. The double-headed swash compressor of claim 10 , wherein the solid lubricant includes at least one of graphite, mica, talc, boric acid, zinc oxide, plumbic oxide, sulfur, molybden disulphide, polytestrafluoroethylene, and hexagonal boric acid. 12. The double-headed swash compressor of claim 1 , wherein the journal bearing is formed from a material composed of 87% copper, 10% tin, and 3% graphite. 13. The double-headed swash compressor of claim 1 , wherein the journal bearing is formed from a material composed of 89% copper, 10% tin, and 1% graphite. 14. The double-headed swash compressor of claim 1 , wherein the suction space is disposed between a first discharge chamber formed in the first housing and a second discharge chamber formed in the second housing, and wherein the refrigerant introduction hole is formed between a first end of the shaft and a second end of the shaft. 15. A double-headed swash compressor comprising: a cylinder block including an annular array of piston bores formed through the cylinder block, a plurality of pistons reciprocatingly received in the piston bores, a suction space formed in the cylinder block, and a shaft bore formed through the cylinder block, the shaft bore communicating with a plurality of refrigerant supply holes formed in the cylinder block, the plurality of refrigerant supply holes communicating with a plurality of compression chambers defined by the piston bores and the plurality of pistons; a first housing coupled to a first side of the cylinder block, the first housing having a first discharge chamber formed therein; a second housing coupled to a second side of the cylinder block, the second housing having a second discharge chamber formed therein, the suction space formed between the first discharge chamber and the second discharge chamber; a shaft received in the shaft bore, the shaft including a passage in fluid communication with the suction space; a swash plate coupled to the shaft in an oblique position with respect to the shaft, the swash plate operatively coupled to the plurality of pistons; and a journal bearing disposed between an inner peripheral surface of the shaft bore and an outer peripheral surface of the shaft, the journal bearing formed entirely from a porous sintered material, wherein the outer peripheral surface of the shaft is spaced apart from the inner peripheral surface of the shaft bore by a first distance (a) when the shaft is inserted into the shaft bore, wherein oil contained in the refrigerant is introduced into or stored in a space defined by the distance (a) between the outer peripheral surface of the shaft and the inner peripheral surface of the shaft bore, the space in fluid communication with the suction space. 16. The double-headed swash compressor of claim 15 , wherein the journal bearing is formed from a material composed of 89% copper, 10% tin, and 1% graphite. 17. The double-headed swash compressor of claim 15 , wherein the cylinder block includes a groove portion formed therein, the groove portion having a length greater than a length of the journal bearing, the groove portion receiving the journal bearing therein, and wherein the space extends from the groove portion. 18. A method for manufacturing a cylinder block, comprising: preparing a cylinder block, the cylinder block including an annular array of piston bores formed through the cylinder block, a plurality of pistons reciprocatingly received in the piston bores, and a shaft bore formed through the cylinder block; inserting a journal bearing formed entirely of a porous sintered material into each of a first end of the shaft bore and a second end of the shaft bore; inserting a shaft in the shaft bore, an outer peripheral surface of the shaft spaced apart from an inner peripheral surface of the shaft bore by a distance (a) when the shaft is inserted in the shaft bore; and forming through-holes through the journal bearing, the through-holes in fluid communication with the piston bores when the journal bearing is inserted in each of the first end of the shaft bore and the se