Scroll compressor and refrigeration cycle apparatus

The invention claimed is: 1. A scroll compressor comprising: a container including an oil sump configured to collect oil; a compression mechanism housed in the container, and configured to compress refrigerant that flows into the container; a rotating shaft configured to drive the compression mechanism, and having an oil supply passage; and an oil pump configured to be driven by rotation of the rotating shaft to supply the oil collected in the oil sump to the oil supply passage in the rotating shaft, wherein the compression mechanism includes a fixed scroll and an orbiting scroll including an orbiting bedplate and an orbiting lap formed at the orbiting bedplate, in the orbiting bedplate, an oil passage, a lap-side oil supply hole, and a thrust-surface-side oil supply hole are formed, the oil passage is configured as a passage through which the oil supplied from the oil supply passage flows from inner part of the oil passage in a radial direction of the orbiting bedplate toward outer part of the oil passage in the radial direction, the lap-side oil supply hole causes the oil passage to communicate with a lap-formation surface of the orbiting bedplate at which the orbiting lap is formed, the thrust-surface-side oil supply hole causes the oil passage to communicate with a thrust surface of the orbiting bedplate that is opposite to the lap-formation surface of the orbiting bedplate, in the oil passage, an opening and closing valve is provided, the opening and closing valve being configured to close the thrust-surface-side oil supply hole when a pressure of the oil in the oil passage is low, and open the thrust-surface-side oil supply hole when the pressure of the oil in the oil passage is high, the oil passage includes a first passage portion that is located in the inner part of the oil passage in the radial direction, and a second passage portion that is located in the outer part of the oil passage in the radial direction and outward of the first passage portion in the radial direction, the second passage portion having a larger diameter than the first passage portion, the lap-side oil supply hole extends from the first passage portion to the lap-formation surface, the thrust-surface-side oil supply hole extends from the second passage portion to the thrust surface, the opening and closing valve is disposed in the second passage portion, the opening and closing valve includes a valve body configured to slide in the oil passage to open or close the thrust-surface-side oil supply hole and an urging part configured to urge the valve body in a direction in which the thrust-surface-side oil supply hole is closed, and when a pressure of the oil that acts on the valve body in the oil passage exceeds a value of an urging force of the urging part, the valve body moves outward in the radial direction in the oil passage to open the thrust-surface-side oil supply hole. 2. The scroll compressor of claim 1 , wherein the valve body is pressed by the urging force of the urging part against a step formed by the first passage portion and the second passage portion to close the thrust-surface-side oil supply hole. 3. The scroll compressor of claim 1 , wherein a plurality of thrust-surface-side oil supply holes including the thrust-surface-side oil supply hole are provided in the orbiting bedplate and spaced from each other in the radial direction. 4. The scroll compressor of claim 1 , wherein the urging part is a compression spring that is compressed when the valve body moves outward in the radial direction. 5. The scroll compressor of claim 1 , wherein the urging part is a tension spring that is pulled when the valve body moves outward in the radial direction. 6. The scroll compressor of claim 1 , wherein the thrust-surface-side oil supply hole has a larger diameter than the lap-side oil supply hole. 7. The scroll compressor of claim 1 , wherein the scroll compressor is a low-pressure shell type scroll compressor in which the container is filled with the refrigerant that has not yet been compressed by the compression mechanism. 8. The scroll compressor of claim 1 , wherein the oil pump is a positive displacement pump. 9. The scroll compressor of claim 8 , wherein the oil pump is a trochoid pump. 10. The scroll compressor of claim 1 , further comprising: an injection pipe configured to inject the refrigerant into a lap-side suction space located around the orbiting lap or a compression chamber in the compression mechanism in which compression is being performed. 11. The scroll compressor of claim 1 , wherein the refrigerant is carbon dioxide. 12. A refrigeration cycle apparatus comprising the scroll compressor of claim 1 . 13. The scroll compressor of claim 1 , wherein a diameter of the valve body is larger than a diameter of the first passage portion. 14. A scroll compressor comprising: a container including an oil sump configured to collect oil; a compression mechanism housed in the container, and configured to compress refrigerant that flows into the container; a rotating shaft configured to drive the compression mechanism, and having an oil supply passage; and an oil pump configured to be driven by rotation of the rotating shaft to supply the oil collected in the oil sump to the oil supply passage in the rotating shaft, wherein the compression mechanism includes a fixed scroll and an orbiting scroll including an orbiting bedplate and an orbiting lap formed at the orbiting bedplate, in the orbiting bedplate, an oil passage, a lap-side oil supply hole, and a thrust-surface-side oil supply hole are formed, the oil passage is configured as a passage through which the oil supplied from the oil supply passage flows from inner part of the oil passage in a radial direction of the orbiting bedplate toward outer part of the oil passage in the radial direction, the lap-side oil supply hole causes the oil passage to communicate with a lap-formation surface of the orbiting bedplate at which the orbiting lap is formed, the thrust-surface-side oil supply hole causes the oil passage to communicate with a thrust surface of the orbiting bedplate that is opposite to the lap-formation surface of the orbiting bedplate, in the oil passage, an opening and closing valve is provided, the opening and closing valve being configured to close the thrust-surface-side oil supply hole when a pressure of the oil in the oil passage is low, and open the thrust-surface-side oil supply hole when the pressure of the oil in the oil passage is high, the opening and closing valve includes a valve body configured to slide in the oil passage to open or close the thrust-surface-side oil supply hole and an urging part configured to urge the valve body in a direction in which the thrust-surface-side oil supply hole is closed, when a pressure of the oil that acts on the valve body in the oil passage exceeds a value of an urging force of the urging part, the valve body moves outward in the radial direction in the oil passage to open the thrust-surface-side oil supply hole, the oil passage includes a first passage portion that is located in the inner part of the oil passage in the radial direction, and a second passage portion that is located in the outer part of the oil passage in the radial direction and outward of the first passage portion in the radial direction, the second passage portion having a larger diameter than the first passage portion, the lap-side oil supply hole extends from the second passage portion to the lap-formation surface, the thrust-surface-side oil supply hole extends from the second passage portion to the thrust surface, the valve body in