Dual loop cooling system energy storage and reuse
First Claim
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1. A method, comprising:
- responsive to a first condition, transferring cooling capacity from a first coolant loop to a heat exchanger, the first condition including a temperature of the first coolant loop being less than a first threshold;
storing cooling capacity transferred from the first coolant loop in a phase change material (PCM) inside the heat exchanger;
responsive to a second condition, transferring heat from a second coolant loop to the heat exchanger, the second condition including a temperature of the second coolant loop being more than a second threshold, the second threshold being higher than the first threshold; and
a first valve positioned between the heat exchanger and the first coolant loop for the first coolant loop to bypass the heat exchanger, and a second valve positioned between the heat exchanger and the second coolant loop for the second coolant loop to bypass the heat exchanger.
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Abstract
Methods and systems are provided for a dual loop coolant system used to control an engine temperature. In one example, cooling capacity is transferred from a low temperature loop to a heat exchanger, and cooling capacity stored in the heat exchanger is transferred to a high temperature loop (e.g., an engine coolant loop). The flow of coolant from the dual loop coolant system to the heat exchanger may be regulated responsive to a temperature of the coolant in each of the low temperature loop and the high temperature loop.
12 Citations
8 Claims
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1. A method, comprising:
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responsive to a first condition, transferring cooling capacity from a first coolant loop to a heat exchanger, the first condition including a temperature of the first coolant loop being less than a first threshold; storing cooling capacity transferred from the first coolant loop in a phase change material (PCM) inside the heat exchanger; responsive to a second condition, transferring heat from a second coolant loop to the heat exchanger, the second condition including a temperature of the second coolant loop being more than a second threshold, the second threshold being higher than the first threshold; and a first valve positioned between the heat exchanger and the first coolant loop for the first coolant loop to bypass the heat exchanger, and a second valve positioned between the heat exchanger and the second coolant loop for the second coolant loop to bypass the heat exchanger. - View Dependent Claims (2, 3, 4, 5, 6)
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7. A system, comprising:
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a heat exchanger coupled to each of a first coolant loop and a second coolant loop; a bypass valve configured to flow a first coolant from the first coolant loop through a first set of tubes inside the heat exchanger, the first set of tubes configured to maintain the first coolant separate from a phase change material (PCM) inside the heat exchanger but in heat exchange relation with the PCM; a coolant valve configured to flow a second coolant from the second coolant loop through a second set of tubes, the second set of tubes inside the heat exchanger configured to maintain the second coolant separate from the first coolant in the first set of tubes and separate from the PCM, while maintaining the second coolant in heat exchange relation with the PCM inside the heat exchanger; and a controller storing computer-readable instructions executable to; position the bypass valve in a first position to flow the first coolant through the first set of tubes, responsive to a temperature of the first coolant loop being less than a first threshold, and position the bypass valve in a second position to block the first coolant from flowing through the first set of tubes, responsive to the temperature of the first coolant loop being more than the first threshold. - View Dependent Claims (8)
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Specification