Heat transfer circuit with increased bearing lubricant temperature, and method of supplying thereof

What is claimed is: 1 . A heat transfer circuit, comprising: a compressor for compressing a working fluid, the compressor including a gas bearing; a condenser for cooling the working fluid with a first process fluid; an expander for expanding the working fluid; an evaporator for heating the working fluid with a second process fluid; a main flow path of the working fluid extending from the compressor through the condenser, the expander, the evaporator, and back to the compressor; a lubricant stream including an inlet and an outlet, the inlet receiving a portion of the working fluid from the main flow path and the outlet supplying the portion of the working fluid to the gas bearing of the compressor, the portion of the working fluid includes one or more refrigerants that are each gaseous at the outlet of the lubricant stream, the one or more refrigerants including an HFO refrigerant; and a heat exchanger configured to increase a temperature of the working fluid flowing through the outlet of the lubricant stream, the working fluid and a third process fluid flowing separately through the heat exchanger, the third process fluid heating the working fluid as the working fluid and the third process fluid flow through the heat exchanger. 2 . The heat transfer circuit of claim 1 , wherein the portion of the working fluid supplied to the gas bearing from the lubricant stream has a superheat of at or about 4.0° F. or greater than 4.0° F. 3 . The heat transfer circuit of claim 2 , wherein the portion of the working fluid at the inlet of the lubricant stream has a superheat of less than 4.0° F. 4 . The heat transfer circuit of claim 2 , wherein the superheat of the portion of the working fluid supplied to the gas bearing is at or about 5.0° F. or greater than 5.0° F. 5 . The heat transfer circuit of claim 1 , wherein the inlet of the lubricant stream connects to the main flow path at the evaporator or after the evaporator and before the condenser. 6 . The heat transfer circuit of claim 1 , wherein the inlet of the lubricant stream connects to the main flow path after the compressor and before the condenser. 7 . The heat transfer circuit of claim 1 , further comprising: a cooling circuit including the heat exchanger and the third process fluid flowing through the cooling circuit. 8 . The heat transfer circuit of claim 7 , wherein the cooling circuit includes one of a variable frequency drive and a motor of the compressor, the third process fluid cooling the one of the variable frequency drive and the motor of the compressor. 9 . The heat transfer circuit of claim 1 , wherein the compressor is an oil-free compressor. 10 . A method of supplying lubricant to a gas bearing of a compressor in a heat transfer circuit, the heat transfer circuit including the compressor, a condenser, an expander, an evaporator, and a heat exchanger, a working fluid flowing through the heat transfer circuit, the working fluid including an HFO refrigerant, the method comprising: heating the working fluid in the evaporator with a process fluid; compressing and further heating at least a portion of the working fluid heated in the evaporator, the further heating including the heat exchanger heating the portion of the working fluid heated in the evaporator with a second process fluid, the working fluid and a second process fluid flowing separately through the heat exchanger, and the second process fluid heating the working fluid as the working fluid and the third process fluid flow through the heat exchanger, and the compressing including one of the compressor and an auxiliary compressor compressing the portion of the working fluid heated in the evaporator; and supplying the compressed and further heated portion of the working fluid to the gas bearing of the compressor as the lubricant. 11 . The method of claim 10 , wherein the compressed and further heated portion of the working fluid supplied to gas bearing has a superheat of at or about 4.0° F. or greater than 4.0° F. 12 . The method of claim 10 , wherein the compressing includes the compressor compressing the working fluid heated in the evaporator, and the portion of the working fluid heated by the heat exchanger is a portion of the working fluid compressed by the compressor. 13 . The method of claim 10 , wherein a cooling circuit includes the heat exchanger, and the third process fluid flows through the cooling circuit. 14 . The method of claim 10 , wherein the cooling circuit includes one of a variable frequency drive and a motor of the compressor, and the method further comprising: cooling the one of the variable frequency drive and the motor of the compressor with the third process fluid, which heats the third process fluid.