Ice maker and method of making and harvesting ice

What is claimed is: 1. A system operable in an ice-making mode and in an ice-harvesting mode, the system comprising: a working-fluid circuit through which a working fluid flows, the working-fluid circuit including a compressor, an expansion device, and an ice-making heat exchanger, wherein the expansion device is disposed downstream of the compressor, wherein the ice-making heat exchanger is disposed between the expansion device and the compressor along the working-fluid circuit; an ice mold configured to receive water from a water-supply conduit when the system is operating in the ice-making mode, wherein the ice mold is in a heat-transfer relationship with the ice-making heat exchanger; and a warming-fluid circuit including a warming-fluid tank, a warming-fluid-supply conduit, and a warming-fluid-return conduit, wherein the ice mold defines a channel configured to receive a warming fluid from the warming-fluid-supply conduit when the system is operating in the ice-harvesting mode, wherein the warming fluid from the warming-fluid-supply conduit has a higher temperature than the water from the water-supply conduit, and wherein the warming fluid is fluidly isolated from the working fluid that circulates through the working-fluid circuit, wherein the warming-fluid-supply tank is fluid coupled to the warming-fluid tank and the channel defined by the ice mold such that: (i) the warming-fluid tank supplies the warming fluid to the warming-fluid-supply conduit and (ii) the warming-fluid-supply conduit supplies the warming fluid to the channel, and wherein the warming-fluid-return conduit is fluidly coupled to the warming-fluid tank and the channel defined by the ice mold such that: (i) the warming-fluid-return conduit receives the warming fluid from the channel and (ii) the warming-fluid-return conduit provides the warming fluid from the channel to the warming-fluid tank. 2. The system of claim 1 , wherein the working-fluid circuit includes a fluid-heating heat exchanger in a heat-transfer relationship with the warming fluid in the warming-fluid tank, wherein the fluid-heating heat exchanger is in fluid communication with the compressor such that working fluid discharged from the compressor is received in the fluid-heating heat exchanger prior to flowing to the expansion device. 3. The system of claim 2 , wherein the fluid-heating heat exchanger is disposed inside of the warming-fluid tank. 4. The system of claim 2 , further comprising: a pump that pumps warming fluid from the warming-fluid tank through the warming-fluid-supply conduit, the channel and the warming-fluid-return conduit; and a control module configured to operate the pump in the ice-harvesting mode and shutdown the pump in the ice-making mode. 5. The system of claim 2 , wherein the working fluid discharged from the compressor is received in the fluid-heating heat exchanger in the ice-harvesting mode and in the ice-making mode. 6. The system of claim 5 , wherein the working-fluid circuit includes a heat exchanger that is spaced apart from the warming-fluid tank and is in fluid communication with the fluid-heating heat exchanger and the expansion device such that the heat exchanger receives working fluid from the fluid-heating heat exchanger and provides working fluid to the expansion device. 7. The system of claim 1 , further comprising a cold-water tank in fluid communication with the water-supply conduit, wherein the working-fluid circuit includes a water-cooling heat exchanger in a heat-transfer relationship with the cold-water tank, wherein the water-cooling heat exchanger is in fluid communication with the expansion device such that working fluid from the expansion device is received in the water-cooling heat exchanger prior to flowing to the compressor. 8. The system of claim 7 , wherein the water-cooling heat exchanger is disposed inside of the cold-water tank. 9. The system of claim 7 , wherein the working-fluid circuit includes a valve in fluid communication with the expansion device, the ice-making heat exchanger and the water-cooling heat exchanger, and wherein the valve is movable between a first position in which the valve allows fluid flow from the expansion device to the ice-making heat exchanger and restricts fluid flow from the expansion device to the water-cooling heat exchanger and a second position in which the valve allows fluid flow from the expansion device to the water-cooling heat exchanger and restricts fluid flow from the expansion device to the ice-making heat exchanger. 10. The system of claim 9 , wherein the valve is in the first position when the system is in the ice-making mode, and wherein the valve is in the second position when the system is in the ice-harvesting mode. 11. The system of claim 1 , wherein the compressor is a scroll compressor. 12. The system of claim 1 , wherein the warming fluid is water. 13. The system of claim 1 , wherein the warming fluid is water with an additive that raises a boiling point of the warming fluid to a temperature higher than the boiling point of water. 14. A system operable in an ice-making mode and in an ice-harvesting mode, the system comprising: a working-fluid circuit through which a working fluid flows, the working-fluid circuit including a compressor, an expansion device, and an ice-making heat exchanger, wherein the expansion device is disposed downstream of the compressor, wherein the ice-making heat exchanger is disposed between the expansion device and the compressor along the working-fluid circuit; an ice mold configured to receive water from a water-supply conduit when the system is operating in the ice-making mode, wherein the ice mold is in a heat-transfer relationship with the ice-making heat exchanger; and a cold-water tank in fluid communication with the water-supply conduit, the working-fluid circuit including a water-cooling heat exchanger in a heat-transfer relationship with the cold-water tank, wherein the water-cooling heat exchanger is in fluid communication with the expansion device such that working fluid from the expansion device is received in the water-cooling heat exchanger prior to flowing to the compressor. 15. The system of claim 14 , wherein the ice mold defines a channel configured to receive a warming fluid from a warming-fluid-supply conduit while the system is operating in the ice-harvesting mode, wherein the warming fluid from the warming-fluid-supply conduit has a higher temperature than the water from the water-supply conduit, and wherein the warming fluid is fluidly isolated from the working fluid that circulates through the working-fluid circuit. 16. The system of claim 15 , wherein the warming fluid is water. 17. The system of claim 15 , wherein the warming fluid is water with an additive that raises a boiling point of the warming fluid to a temperature higher than the boiling point of water. 18. The system of claim 15 , further comprising: a warming-fluid tank in fluid communication with the warming-fluid-supply conduit; and a warming-fluid-return conduit in fluid communication with the channel and the warming-fluid tank. 19. The system of claim 18 , wherein the working-fluid circuit includes a fluid-heating heat exchanger in a heat-transfer relationship with the warming fluid in the warming-fluid tank, wherein the fluid-heating heat exchanger is in fluid communication with the compressor such that working fluid discharged from the compressor is received in the fluid-heating heat exchanger prior to flowing to the expansion device. 20. The syst