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A refrigeration cycle system is capable of reducing an amount of information required to be specified in advance, reducing a computational processing load, reflecting differences in actual installation conditions, and speeding up stabilization of an operational state in which the total amount of req

A refrigeration cycle system is capable of reducing an amount of information required to be specified in advance, reducing a computational processing load, reflecting differences in actual installation conditions, and speeding up stabilization of an operational state in which the total amount of required input energy is reduced. A refrigeration cycle system is provided with a plurality of actuators, including outdoor fan motors, compressors, indoor fan motors, and the like for causing a refrigerant circuit to carry out a refrigeration cycle. A control unit obtains the slope at the current evaporation temperature and/or the current condensing temperature on a graph of the function between the actuators and the evaporation temperature or the condensing temperature, and updates the value of the target evaporation temperature and/or the target condensing temperature so that the sum of the input energy to the actuators is less that the current level.

대표청구항 ▼

1. A refrigeration cycle system adapted to circulate a refrigerant in a refrigerant circuit including a compressor, a heat-source-side heat exchanger, an expansion valve, and a usage-side heat exchanger connected together, the refrigeration cycle system comprising: a plurality of actuators configure

1. A refrigeration cycle system adapted to circulate a refrigerant in a refrigerant circuit including a compressor, a heat-source-side heat exchanger, an expansion valve, and a usage-side heat exchanger connected together, the refrigeration cycle system comprising: a plurality of actuators configured to cause a refrigeration cycle to be performed in the refrigerant circuit;a storage unit storing for each of the actuators or each type of the actuators, respectively, at least one of a relational expression indicating a relationship between an amount of energy inputted to the actuators and a refrigerant target state quantity of refrigerant flowing through the refrigerant circuit, the refrigerant target state quantity being any of a temperature control target value, a pressure control target value, or a physical-quantity control target value equivalent thereto,first information usable to create the relational expression, andsecond information usable to attain the relational expression using values inputted to the actuators and values that indicate states of the actuators corresponding to the input values;at least one refrigerant state quantity sensor configured to acquire a current refrigerant state quantity that corresponds to a value of the refrigerant target state quantity; anda control unit programmed to obtain a sum of the energy inputted to the actuators, or obtain a sum of an amount of change in the energy inputted to the actuators, based on the relational expression in a case where a change has been made from the current refrigerant state quantity, andwhile updating the value of the refrigerant target state quantity so that the sum of energy inputted to the actuators is less than a current level or so that the sum of the amount of change in the energy inputted to the actuators is a low value, control at least one of the actuators so that a value acquired by the at least one refrigerant state quantity sensor approximates an updated value of the refrigerant target state quantity. 2. The refrigeration cycle system according to claim 1, wherein the control unit is further programmed to update the value of the refrigerant target state quantity in a range in which a width of change in capacity requested by the usage-side heat exchanger satisfies a predetermined capacity condition. 3. The refrigeration cycle system according to claim 1, further comprising a heat-source-side fluid supply unit configured to supply a fluid to the heat-source-side heat exchanger to exchange heat with a refrigerant flowing through the heat-source-side heat exchanger,the plurality of actuators including a first actuator driving the compressor and a second actuator driving the heat-source-side fluid supply unit;the storage unit further storing a first relational expression indicating a relationship of an amount of energy inputted to the first actuator in relation to a control target value of a condensing temperature at which refrigerant flowing through the refrigerant circuit condenses, or information usable to create the first relational expression, anda second relational expression indicating a relationship of an amount of energy inputted to the second actuator in relation to a control target value of the condensing temperature, or information usable to create the second relational expression;the at least one refrigerant state quantity sensor being further configured to acquire a current value of the condensing temperature, andthe control unit being further programmed to obtain a sum of the energy inputted to the first actuator, or obtain a sum of an amount of change in the energy inputted to the first actuator, based on the first relational expression in a case where a change has been made from the current condensing temperature,obtain a sum of the energy inputted to the second actuator, or obtain a sum of an amount of change in the energy inputted to the second actuator, based on the second relational expression in a case where a change has been made from the current condensing temperature, andwhile updating the control target value of the condensing temperature so that the sum of the energy inputted to the first actuator and the second actuator is less than the current level or so that the sum of the amount of change in the energy inputted to the first actuator and the second actuator is a low value, control the second actuator when the usage-side heat exchanger functions as an evaporator and control the first actuator when the usage-side heat exchanger functions as a condenser so that the current value of the condensing temperature acquired by the at least one refrigerant state quantity sensor approximates an updated control target value of the condensing temperature. 4. The refrigeration cycle system according to claim 3, wherein the heat-source-side heat exchanger includes a plurality of heat-source-side heat exchangers;the compressor includes a plurality of compressors corresponding to the plurality of heat-source-side heat exchangers;the heat-source-side fluid supply unit includes a plurality of heat-source-side fluid supply units corresponding to the plurality of heat-source-side heat exchangers;the first actuator includes a plurality of first actuators corresponding to the plurality of compressors;the second actuator includes a plurality of second actuators corresponding to the plurality of heat-source-side fluid supply units;the storage unit further stores for each of the plurality of first actuators, the first relational expression or information usable to create the first relational expression, andfor each of the plurality of second actuators, the second relational expression or information usable to create the second relational expression; andthe control unit is further programmed to obtain a sum of the energy inputted to the plurality of first actuators or the sum of an amount of change in the energy inputted to the plurality of first actuators, based on each first relational expressions in a case where a change has been made from the current condensing temperature,obtain a sum of the energy inputted to the plurality of second actuators or the sum of an amount of change in the energy inputted to the plurality of second actuators, based on each second relational expressions in a case where a change has been made from the current condensing temperature, andwhile updating the control target value of the condensing temperature so that the sum of the energy inputted to the plurality of first actuators and the plurality of second actuators is less than the current level or so that the sum of the amount of change in energy inputted to the plurality of first actuators and the plurality of second actuators is a low value, control the plurality of second actuators when the usage-side heat exchanger functions as an evaporator and control the plurality of first actuators when the usage-side heat exchanger functions as a condenser so that the current value of the condensing temperature acquired by the at least one refrigerant state quantity sensor approximates the updated control target value of the condensing temperature. 5. The refrigeration cycle system according to claim 3, wherein the control unit is further programmed to calculate the sum of the amount of change in the energy inputted to the first actuator and the second actuator in a case where a change has been made from the current condensing temperature, by obtaining and totaling for each of the actuators a value attained by substituting the current condensing temperature into a formula attained from a first-order differential of the relational expression for each of the actuators based on the condensing temperature. 6. The refrigeration cycle system according to claim 3, wherein the control unit is further programmed to update the control target value of the condensing temperature and thereafter to further update the control target value of the condensing temperature when predetermined standby conditions have been satisfied. 7. The refrigeration cycle system according to claim 1, further comprising a heat-source-side fluid supply unit configured to supply a fluid to the heat-source-side heat exchanger to exchange heat with a refrigerant flowing through the heat-source-side heat exchanger; anda usage-side fluid supply unit configured to supply a fluid to the usage-side heat exchanger to exchange heat with a refrigerant flowing through the usage-side heat exchanger,the plurality of actuators includes a third actuator driving the compressor, a fourth actuator driving the usage-side fluid supply unit, and a fifth actuator driving the heat-source-side fluid supply unit;the storage unit further storing a third relational expression indicating a relationship of an amount of energy inputted to the third actuator in relation to a control target value of an evaporation temperature at which refrigerant flowing through the refrigerant circuit evaporates, or information usable to create the third relational expression; anda fourth relational expression indicating a relationship of an amount of energy inputted to the fourth actuator in relation to a control target value of the evaporation temperature, or information usable to the fourth relational expression;the at least one refrigerant state quantity sensor is further configured to acquire a current value of the evaporation temperature at which refrigerant flowing through the refrigerant circuit evaporates; andthe control unit being further programmed to obtain a sum of the energy inputted to the third actuator or a sum of an the amount of change in the energy inputted to the third actuator, based on the third relational expression in a case where a change has been made from a current evaporation temperature, andobtain a sum of the energy inputted to the fourth actuator or a sum of an amount of change in the energy inputted to the fourth actuator, based on the fourth relational expression in a case where a change has been made from the current evaporation temperature, andwhile updating the control target value of the evaporation temperature so that the sum of the energy inputted to the third actuator and the fourth actuator is less than the current level or so that the sum of the amount of change of energy inputted to the third actuator and the fourth actuator is a low value, control the third actuator when the usage-side heat exchanger functions as an evaporator and control the fifth actuator when the usage-side heat exchanger functions as a condenser so that the current value of the evaporation temperature acquired by the at least one refrigerant state quantity sensor approximates the updated control target value of the evaporation temperature. 8. The refrigeration cycle system according to claim 7, wherein the usage-side heat exchanger includes a plurality of usage-side heat exchangers;the usage-side fluid supply unit includes a plurality of usage-side fluid supply units corresponding to the plurality of usage-side heat exchangers;the fourth actuator includes a plurality of fourth actuator, corresponding to the plurality of usage-side fluid supply units;the storage unit further stores the fourth relational expression, or information usable to create the fourth relational expression, for each of the plurality of fourth actuators; andthe control unit is further programmed to obtain a sum of the energy inputted to the third actuator or a sum of an amount of change in the energy inputted to the third actuators, based on the third relational expression in a case where a change has been made from the current evaporation temperature,obtain a sum of the energy inputted to the plurality of fourth actuators or a sum of an amount of change in the energy inputted to the plurality of fourth actuators, based on each fourth relational expression in a case where a change has been made from the current evaporation temperature, andwhile updating the control target value of the evaporation temperature so that the sum of the energy inputted to the third actuator and the plurality of fourth actuators is less than the current level or so that the sum of the amount of change of energy inputted to the third actuator and the plurality of fourth actuators is a low value, control the third actuator when the usage-side heat exchangers function as evaporators and control the fifth actuator when the usage-side heat exchangers function as condensers so that the current value of the evaporation temperature acquired by the at least one refrigerant state quantity sensor approximates the updated control target value of the evaporation temperature. 9. The refrigeration cycle system according to claim 7, wherein the control unit is further programmed to calculate the sum of the amount of change in the energy inputted to the third actuator and the fourth actuator in a case where a change has been made from the current evaporation temperature, by obtaining and totaling for each of the actuators a value attained by substituting the current evaporation temperature into a formula attained from a first-order differential of the relational expression for each of the actuators based on the evaporation temperature. 10. The refrigeration cycle system according to claim 7, wherein the control unit is further programmed to update the control target value of the evaporation temperature and thereafter to further update the control target value of the evaporation temperature when predetermined standby conditions have been satisfied. 11. The refrigeration cycle system according to claim 1, further comprising a heat-source-side fluid supply unit configured to supply a fluid to the heat-source-side heat exchanger to exchange heat with a refrigerant flowing through the heat-source-side heat exchanger; anda usage-side fluid supply unit configured to supply a fluid to the usage-side heat exchanger to exchange heat with a refrigerant flowing through the usage-side heat exchanger,the plurality of actuators includes a sixth actuator driving the compressor, a seventh actuator driving the heat-source-side fluid supply unit, and an eighth actuator driving the usage-side fluid supply unit;the storage unit further storing a sixth condensing relational expression indicating a relationship of an amount of energy inputted to the sixth actuator in relation to a control target value of a condensing temperature at which refrigerant flowing through the refrigerant circuit condenses, or information usable to create the sixth condensing relational expression,a sixth evaporation relational expression indicating a relationship of an amount of energy inputted to the sixth actuator in relation to a control target value of an evaporation temperature at which refrigerant flowing through the refrigerant circuit evaporates, or information usable to create the sixth evaporation relational expression,a seventh relational expression indicating a relationship of an amount of energy inputted to the seventh actuator in relation to a control target value of a condensing temperature, or information usable to create the seventh relational expression, andan eighth relational expression indicating a relationship of an amount of energy inputted to the eighth actuator in relation to a control target value of the evaporation temperature, or information usable to create the eighth relational expression,the at least one refrigerant state quantity sensor is further configured to acquire a current value of the condensing temperature and a current value of the evaporation temperature of the refrigerant flowing through the refrigerant circuit; andthe control unit being further programmed to obtain a sum of an amount of change in the energy inputted to the sixth actuator, based on the sixth condensing relational expression in a case where a change has been made from the current condensing temperature,obtain a sum of an amount of change in the energy inputted to the seventh actuator, based on the seventh condensing relational expression in a case where a change has been made from the current condensing temperature,calculate three condensing temperature-related values attained by multiplication with the value attained from the relational expression related to the condensing temperature, the negative value of the value, and 0,obtain a sum of an amount of change in the energy inputted to the sixth actuator; based on the sixth evaporation relational expression in a case where a change has been made from the current evaporation temperature,obtain a sum of an amount of change in the energy inputted to the eighth actuator based on the eighth evaporation relational expression,calculate three evaporation temperature-related values attained by multiplication with the value attained from the relational expression related to the evaporation temperature, the negative value of the value, and 0,specify a combination having a minimum value among combinations of the sums of the three condensing temperature-related values and the three evaporation temperature-related values, andwhile updating the control target value of the condensing temperature and the control target value of the evaporation temperature by having the condensing temperature-related value and the evaporation temperature-related value of the specified combination reflected in the current condensing temperature and the current evaporation temperature, respectively, when the usage-side heat exchanger functions as an evaporator, control the seventh actuator so that the current value of the condensing temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the condensing temperature, while controlling the sixth actuator so that the current value of the evaporation temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the evaporation temperature, andwhen the usage-side heat exchanger functions as a condenser; control the sixth actuator so that the current value of the condensing temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the condensing temperature, while controlling the seventh actuator so that the current value of the evaporation temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the evaporation temperature. 12. The refrigeration cycle system according to claim 11, wherein the heat-source-side heat exchanger includes a plurality of heat-source-side heat exchangers;the compressor includes a plurality of compressors corresponding to the plurality of heat-source-side heat exchangers;the heat-source-side fluid supply unit includes a plurality of heat-source-side fluid supply units corresponding to the plurality of heat-source-side heat exchangers;the sixth actuator includes a plurality of sixth actuators corresponding to the plurality of compressors;the seventh actuator includes a plurality of seventh actuators corresponding to the plurality of heat-source-side fluid supply units;the storage unit further stores the sixth condensing relational expression or information usable to create the sixth condensing relational expression for each of the plurality of sixth actuators,the sixth evaporation relational expression or information usable to create the sixth evaporation relational expression for each of the plurality of sixth actuators, andthe seventh relational expression or information usable to create the seventh relational expression for each of the plurality of seventh actuators, andthe control unit is further programmed to obtain a sum of an amount of change in the energy inputted to the plurality of sixth actuators, based on each sixth condensing relational expression in a case where a change has been made from the current condensing temperature,obtain a sum of an amount of change in the energy inputted to the plurality of seventh actuators, based on each seventh condensing relational expression in a case where a change has been made from the current condensing temperature,calculate three condensing temperature-related values attained by multiplication with the value attained from the relational expression related to the condensing temperature, the negative value of the value, and 0,obtain a sum of an amount of change in the energy inputted to the plurality of sixth actuators, based on each sixth evaporation relational expression in a case where a change has been made from the current evaporation temperature,obtain a sum of an amount of change in the energy inputted to the eighth actuators, based on eighth evaporation relational expression in a case where a change has been made from the current evaporation temperature,calculate three evaporation temperature-related values attained by multiplication with the value attained from the relational expression related to the evaporation temperature, the negative value of the value, and 0,specify a combination having a minimum value among combinations of the sums of the three condensing temperature-related values and the three evaporation temperature-related values, andwhile updating the control target value of the condensing temperature and the control target value of the evaporation temperature by having the condensing temperature-related value and the evaporation temperature-related value of the specified combination reflected in the current condensing temperature and the current evaporation temperature, respectively, when the usage-side heat exchanger functions as an evaporator, control the plurality of seventh actuators so that the current value of the condensing temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the condensing temperature, while controlling the plurality of sixth actuators so that the current value of the evaporation temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the evaporation temperature, andwhen the usage-side heat exchanger functions as a condenser, control the plurality of sixth actuators so that the current value of the condensing temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the condensing temperature, while controlling the plurality of seventh actuators so that the current value of the evaporation temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the evaporation temperature. 13. The refrigeration cycle system according to claim 11, wherein the usage-side heat exchanger includes a plurality of usage-side heat exchangers;the usage-side fluid supply unit includes a plurality of usage-side fluid supply units corresponding to the plurality of usage-side heat exchangers;the eighth actuator includes a plurality of eighth actuators corresponding to the plurality of usage-side fluid supply units;the storage unit further stores the eighth relational expression or information usable to create the eighth relational expression for each of the plurality of eighth actuators; andthe control unit is further programmed to obtain a sum of an amount of change in the energy inputted to the sixth actuator, based on the sixth condensing relational expression in a case where a change has been made from the current condensing temperature,obtain a sum of an amount of change in the energy inputted to the sixth actuator and the seventh actuator, based on the seventh condensing relational expression in a case where a change has been made from the current evaporation temperature,calculate three condensing temperature-related values attained by multiplication with the value attained from the relational expression related to the condensing temperature, the negative value of the value, and 0,obtain a sum of an amount of change in the energy inputted to the sixth actuator, based on the sixth evaporation relational expression in a case where a change has been made from the current evaporation temperature,obtain a sum of an amount of change in the energy inputted to the sixth actuator and the plurality of eighth actuators, based on each eighth relational expression in a case where a change has been made from the current evaporation temperature,calculate three evaporation temperature-related values attained by multiplication with the value attained from the relational expression related to the evaporation temperature, the negative value of the value, and 0,specify a combination having a minimum value among combinations of the sums of the three condensing temperature-related values and the three evaporation temperature-related values, andwhile updating the control target value of the condensing temperature and the control target value of the evaporation temperature by having the condensing temperature-related value and the evaporation temperature-related value of the specified combination reflected in the current condensing temperature and the current evaporation temperature, respectively, when the usage-side heat exchanger functions as an evaporator, control the seventh actuator so that the current value of the condensing temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the condensing temperature, while controlling the sixth actuator so that the current value of the evaporation temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the evaporation temperature, andwhen the usage-side heat exchanger functions as a condenser, control the sixth actuator so that the current value of the condensing temperature acquired by the refrigerant state quantity acquisition mean at least one refrigerant state quantity sensor reaches the updated control target value of the condensing temperature, while controlling the seventh actuator so that the current value of the evaporation temperature acquired by the at least one refrigerant state quantity sensor reaches the updated control target value of the evaporation temperature. 14. The refrigeration cycle system according to claim 11, wherein the control unit is further programmed to calculate the sum of the amount of change in the energy inputted to the sixth actuator and the seventh actuator in a case where a change has been made from the current condensing temperature, by obtaining and totaling for each of the actuators a value attained by substituting the current condensing temperature into a formula attained from a first-order differential of the relational expression for each of the actuators based on the condensing temperature, andcalculate the sum of the amount of change in the energy inputted to the sixth actuator and the eighth actuator in a case where a change has been made from the current evaporation temperature, by obtaining and totaling for each of the actuators a value attained by substituting the current evaporation temperature into a formula attained from a first-order differential of the relational expression for each of the actuators based on the evaporation temperature. 15. The refrigeration cycle system according to claim 11, wherein after updating the control target value of the condensing temperature and the control target value of the evaporation temperature, the control unit is further programmed to update the control target value of the condensing temperature and the control target value of the evaporation temperature when predetermined standby conditions have been satisfied.