Heat source unit and refrigeration apparatus

The invention claimed is: 1. A heat source unit connected to a utilization unit and configured to perform a refrigeration cycle by circulating a primary refrigerant between the heat source unit and the utilization unit, a maximum pressure of the primary refrigerant in the refrigeration cycle being higher than or equal to a critical pressure of the primary refrigerant, the heat source unit comprising: a compressor configured to suck and compress the primary refrigerant; a first heat exchanger configured to exchange heat between the primary refrigerant and outdoor air; a first expansion valve configured to decompress the primary refrigerant that has flowed out of the first heat exchanger functioning as a radiator; a receiver configured to receive the primary refrigerant that has flowed out of the first heat exchanger functioning as a radiator and passed through the first expansion valve; a first cooler configured to cool the primary refrigerant flowing from the receiver toward the utilization unit; a second cooler configured to cool the primary refrigerant flowing from the first heat exchanger functioning as a radiator toward the first expansion valve, using a coolant other than the outdoor air; and a controller configured to control cooling capability of the second cooler so that a gas refrigerant contained in the primary refrigerant flowing into the receiver after passing through the first expansion valve decreases compared to a case in which the second cooler does not cool the primary refrigerant. 2. The heat source unit of claim 1 , wherein the controller is further configured to switch the second cooler between a cooling mode of cooling the primary refrigerant and an inactive mode of cooling no primary refrigerant. 3. The heat source unit of claim 2 , wherein the controller is further configured to switch the second cooler from the inactive mode to the cooling mode, based on an index indicating a refrigerating capacity of the heat source unit. 4. The heat source unit of claim 2 , wherein the controller is further configured to switch the second cooler from the inactive mode to the cooling mode, based on a temperature of the primary refrigerant that has flowed out of the first heat exchanger functioning as a radiator and passed through the second cooler. 5. The heat source unit of claim 1 , further comprising: an auxiliary refrigerant circuit connected to the second cooler, including an auxiliary compressor, and configured to perform a refrigeration cycle by compressing a secondary refrigerant as the coolant in the auxiliary compressor. 6. The heat source unit of claim 5 , wherein the controller includes an auxiliary controller configured to adjust a rotational speed of the auxiliary compressor, based on a temperature of the primary refrigerant cooled in the second cooler. 7. The heat source unit of claim 2 , further comprising: an auxiliary refrigerant circuit connected to the second cooler, including an auxiliary compressor, and configured to perform a refrigeration cycle by compressing a secondary refrigerant as the coolant in the auxiliary compressor, wherein the controller switches the second cooler to the cooling mode by operating the auxiliary compressor and switches the second cooler to the inactive mode by stopping the auxiliary compressor. 8. The heat source unit of claim 1 , wherein the coolant supplied to the second cooler is the primary refrigerant sucked into the compressor. 9. The heat source unit of claim 2 , wherein the coolant supplied to the second cooler is the primary refrigerant sucked into the compressor. 10. The heat source unit of claim 1 , wherein the compressor includes a low-stage compressor configured to suck and compress the primary refrigerant, and a high-stage compressor configured to suck and compress the primary refrigerant discharged from the low-stage compressor, and the coolant supplied to the second cooler is the primary refrigerant sucked into the low-stage compressor. 11. The heat source unit of claim 2 , wherein the compressor includes a low-stage compressor configured to suck and compress the primary refrigerant, and a high-stage compressor configured to suck and compress the primary refrigerant discharged from the low-stage compressor, and the coolant supplied to the second cooler is the primary refrigerant sucked into the low-stage compressor. 12. The heat source unit of claim 1 , wherein the compressor includes a low-stage compressor configured to suck and compress the primary refrigerant, and a high-stage compressor configured to suck and compress the primary refrigerant discharged from the low-stage compressor, the heat source unit further comprising: a gas pipe connected to the receiver and the high-stage compressor and configured to send a gas refrigerant of the receiver to the high-stage compressor; and a decompression section placed in the gas pipe and configured to decompress the gas refrigerant flowing through the gas pipe, and the coolant supplied to the second cooler is a primary refrigerant that has passed through the decompression section in the gas pipe. 13. The heat source unit of claim 2 , wherein the compressor includes a low-stage compressor configured to suck and compress the primary refrigerant, and a high-stage compressor configured to suck and compress the primary refrigerant discharged from the low-stage compressor, the heat source unit further comprising: a gas pipe connected to the receiver and the high-stage compressor and configured to send a gas refrigerant of the receiver to the high-stage compressor; and a decompression section placed in the gas pipe and configured to decompress the gas refrigerant flowing through the gas pipe, and the coolant supplied to the second cooler is a primary refrigerant that has passed through the decompression section in the gas pipe. 14. The heat source unit of claim 9 , further comprising: a bypass pipe which is placed in parallel with the second cooler and through which the primary refrigerant flows from the first heat exchanger functioning as a radiator toward the first expansion valve; and a bypass valve provided in the bypass pipe. 15. The heat source unit of claim 11 , further comprising: a bypass pipe which is placed in parallel with the second cooler and through which the primary refrigerant flows from the first heat exchanger functioning as a radiator toward the first expansion valve; and a bypass valve provided in the bypass pipe. 16. The heat source unit of claim 13 , further comprising: a bypass pipe which is placed in parallel with the second cooler and through which the primary refrigerant flows from the first heat exchanger functioning as a radiator toward the first expansion valve; and a bypass valve provided in the bypass pipe. 17. A refrigeration apparatus comprising: the heat source unit of claim 1 ; and the utilization unit connected to the heat source unit. 18. A refrigeration apparatus comprising: the heat source unit of claim 9 ; a utilization unit including a second heat exchanger and a second expansion valve and connected to the heat source unit; and a superheat controller configured to adjust an opening degree of the second expansion valve to set a degree of superheat of the primary refrigerant at an outlet of the second heat exchanger to a target degree of superheat in an operation of the second heat exchanger functioning as an evaporator, the superheat controller being configured to set the target degree of superheat lower when the second cooler is in the c