US 12,309,983 B2
Refrigeration system or a heat pump and method of operating a refrigeration system or a heat pump
Ryan Wayne Schumacher, Bloomington, MN (US); Esteban Canade Tarquini, Rubi (ES); and Peadar Conneely, Galway (IE)
Assigned to THERMO KING LLC, Minneapolis, MN (US)
Filed by THERMO KING LLC, Minneapolis, MN (US)
Filed on Feb. 1, 2023, as Appl. No. 18/162,832.
Claims priority of application No. 22382082 (EP), filed on Feb. 1, 2022.
Prior Publication US 2023/0247810 A1, Aug. 3, 2023
Int. Cl. H05K 7/20 (2006.01)
CPC H05K 7/20936 (2013.01) [H05K 7/20336 (2013.01)] 12 Claims
OG exemplary drawing
 
1. A refrigeration system or heat pump, comprising:
a compressor, a condenser, a liquid line, an expansion device, an evaporator and a suction line;
a flow path for a vapor compression cycle, the flow path extending through the compressor, the condenser, the liquid line, the expansion device, the evaporator, and the suction line to the compressor;
a power converter or power module configured to supply electrical power; and
a heat pipe having a first portion and a second portion;
wherein the first portion of the heat pipe and the power converter or power module are configured such that a first thermal coupling is formed between the first portion of the heat pipe and the power converter or power module,
wherein the second portion of the heat pipe and a component of the refrigeration system or heat pump are configured such that a second thermal coupling is formed between the second portion of the heat pipe and the component,
wherein the heat pipe is configured to receive heat from the power converter or power module at the first portion, transfer the heat from the first portion to the second portion and transfer the heat from the second portion to the component of the refrigeration system or heat pump so as to cool the power converter or power module,
wherein the refrigeration system or heat pump further comprises an economizer heat exchanger, an injection line and an additional expansion device,
wherein the additional expansion device is fluidically connected to the liquid line so as to receive fluid from the liquid line and is configured to expand the fluid received from the liquid line so as to form expanded fluid,
wherein the compressor is configured to receive the expanded fluid from the additional expansion device via the injection line,
wherein the economizer heat exchanger is configured to thermally couple the injection line to the liquid line such that heat is transferred from the injection line to the liquid line,
wherein the refrigeration system or heat pump further comprises a further injection line and a further expansion device,
wherein a first portion of the injection line fluidically connects the additional expansion device to the economizer heat exchanger,
wherein a second portion of the injection line fluidically connects the economizer heat exchanger to the compressor,
wherein the further expansion device is fluidically connected to the liquid line so as to receive fluid from the liquid line and is configured to expand the fluid received from the liquid line so as to form expanded fluid,
wherein the second portion of the injection line is configured to receive the expanded fluid from the further expansion device via the further injection line,
wherein the second portion of the heat pipe, the second portion of the injection line and the further injection line are configured such that a second thermal coupling is formed between the second portion of the heat pipe, the second portion of the injection line and the further injection line.
 
5. A refrigeration system or heat pump, comprising:
a compressor, a condenser, a liquid line, an expansion device, an evaporator and a suction line;
a flow path for a vapor compression cycle, the flow path extending through the compressor, the condenser, the liquid line, the expansion device, the evaporator, and the suction line to the compressor;
a power converter or power module configured to supply electrical power; and
a heat pipe having a first portion and a second portion;
wherein the first portion of the heat pipe and the power converter or power module are configured such that a first thermal coupling is formed between the first portion of the heat pipe and the power converter or power module,
wherein the second portion of the heat pipe and a component of the refrigeration system or heat pump are configured such that a second thermal coupling is formed between the second portion of the heat pipe and the component,
wherein the heat pipe is configured to receive heat from the power converter or power module at the first portion, transfer the heat from the first portion to the second portion and transfer the heat from the second portion to the component of the refrigeration system or heat pump so as to cool the power converter or power module,
wherein the refrigeration system or heat pump further comprises a suction to liquid line heat exchanger,
wherein the suction to liquid line heat exchanger is configured to thermally couple the suction line to the liquid line such that heat is transferred from the liquid line to the suction line,
wherein the second portion of the heat pipe and the suction to liquid line heat exchanger are configured such that a second thermal coupling is formed between the second portion of the heat pipe and the suction to liquid line heat exchanger,
wherein the refrigeration system or heat pump further comprises an injection line and an additional expansion device,
wherein the additional expansion device is fluidically connected to the liquid line so as to receive fluid from the liquid line and is configured to expand the fluid received from the liquid line so as to form expanded fluid,
wherein the liquid to suction line heat exchanger is configured to receive the expanded fluid from the additional expansion device via the injection line.
 
9. A refrigeration system or heat pump, comprising:
a compressor, a condenser, a liquid line, an expansion device, an evaporator and a suction line;
a flow path for a vapor compression cycle, the flow path extending through the compressor, the condenser, the liquid line, the expansion device, the evaporator, and the suction line to the compressor;
a power converter or power module configured to supply electrical power; and
a heat pipe having a first portion and a second portion;
wherein the first portion of the heat pipe and the power converter or power module are configured such that a first thermal coupling is formed between the first portion of the heat pipe and the power converter or power module,
wherein the second portion of the heat pipe and a component of the refrigeration system or heat pump are configured such that a second thermal coupling is formed between the second portion of the heat pipe and the component,
wherein the heat pipe is configured to receive heat from the power converter or power module at the first portion, transfer the heat from the first portion to the second portion and transfer the heat from the second portion to the component of the refrigeration system or heat pump so as to cool the power converter or power module,
wherein the refrigeration system or heat pump further comprises a suction to liquid line heat exchanger, an injection line and an additional expansion device,
wherein the suction to liquid line heat exchanger is configured to thermally couple the suction line to the liquid line such that heat is transferred from the liquid line to the suction line,
wherein the additional expansion device is fluidically connected to the liquid line so as to receive fluid from the liquid line and is configured to expand the fluid received from the liquid line so as to form expanded fluid,
wherein the liquid to suction line heat exchanger is configured to receive the expanded fluid from the additional expansion device via the injection line,
wherein the second portion of the heat pipe and the injection line are configured such that a second thermal coupling is formed between the second portion of the heat pipe and the injection line.