CN107388519A - Air conditioner and its efficiency computational methods - Google Patents
Air conditioner and its efficiency computational methods Download PDFInfo
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- CN107388519A CN107388519A CN201710775542.XA CN201710775542A CN107388519A CN 107388519 A CN107388519 A CN 107388519A CN 201710775542 A CN201710775542 A CN 201710775542A CN 107388519 A CN107388519 A CN 107388519A
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Abstract
The invention discloses a kind of air conditioner and its efficiency computational methods, the described method comprises the following steps:Obtain current working, the power and air conditioner power consumption of compressor of air conditioner;Obtain the housing heat dissipation capacity Q of compressorloss;Obtain the temperature t of gas returning port in compressor, exhaust outlet, outdoor heat exchanger first end and indoor heat exchanger first end1、t2、t4And t7, wherein, t1According to t4With indoor environment temperature t9Generation;When the current working of air conditioner is cooling condition, respectively according to t1、t2、t4And t7The corresponding refrigerant enthalpy and lubricating oil enthalpy for generating gas returning port, exhaust outlet, outdoor heat exchanger first end and indoor heat exchanger first end;The mixture enthalpy h of above-mentioned each temperature detecting point is generated according to the refrigerant enthalpy of above-mentioned each temperature detecting point and lubricating oil enthalpy1、h2、h4And h7;According to the power of compressor, Qloss、h1、h2、h4And h7Generate the refrigerating capacity of air conditioner;And the efficiency of air conditioner is generated according to air conditioner power consumption and refrigerating capacity.
Description
Technical field
The present invention relates to air conditioner technical field, the efficiency computational methods of more particularly to a kind of air conditioner, a kind of air conditioner
With a kind of non-transitorycomputer readable storage medium.
Background technology
It is comfortably the problem of user more pays close attention to that whether air conditioner, which saves,.
Current air conditioner is difficult to maintain preferable fortune operationally due to that can not know the situation of change of efficiency
Row state, cooling or heating effect and energy-efficient performance are not ideal enough.
The content of the invention
It is contemplated that at least solves one of technical problem in above-mentioned technology to a certain extent.Therefore, the present invention
One purpose is the efficiency computational methods for proposing a kind of air conditioner, can real-time and accurately detect the efficiency of air conditioner.
Second object of the present invention is to propose a kind of air conditioner.
Third object of the present invention is to propose a kind of non-transitorycomputer readable storage medium.
Fourth object of the present invention is the efficiency computational methods for proposing another air conditioner.
The 5th purpose of the present invention is to propose another air conditioner.
The 6th purpose of the present invention is to propose another non-transitorycomputer readable storage medium.
To reach above-mentioned purpose, a kind of efficiency computational methods for air conditioner that first aspect present invention embodiment proposes include
Following steps:Obtain current working, the power and air conditioner power consumption of compressor of air conditioner;The housing for obtaining compressor dissipates
Heat Qloss;Obtain the gas returning port temperature t of gas returning port in compressor1, in the compressor exhaust outlet exhaust port temperatures t2, room
The outdoor heat exchanger first end temperature t of external heat exchanger first end4With the indoor heat exchanger first end temperature of indoor heat exchanger first end
Spend t7, wherein, the gas returning port temperature t1According to indoor environment temperature t9With outdoor heat exchanger first end temperature t4Generation;Work as institute
When the current working for stating air conditioner is cooling condition, according to the gas returning port temperature t of gas returning port in the compressor1Generate gas returning port
Refrigerant enthalpy h1 refrigerantWith lubricating oil enthalpy h1 lubricating oil, according to the exhaust port temperatures t of exhaust outlet in the compressor2Generation row
The refrigerant enthalpy h of gas port2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, according to the outdoor heat exchanger of the outdoor heat exchanger first end
One end temperature t4Generate the refrigerant enthalpy h of outdoor heat exchanger first end4 refrigerantsWith lubricating oil enthalpy h4 lubricating oilWith according to the interior
The indoor heat exchanger first end temperature t of heat exchanger first end7Generate the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerantsAnd profit
Lubricating oil enthalpy h7 lubricating oil;According to the refrigerant enthalpy h of the gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oilGenerate the mixing of gas returning port
Thing enthalpy h1, according to the refrigerant enthalpy h of the exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oilGenerate the mixture enthalpy of exhaust outlet
Value h2, according to the refrigerant enthalpy h of the outdoor heat exchanger first end4 refrigerantsWith lubricating oil enthalpy h4 lubricating oilGenerate outdoor heat exchanger
The mixture enthalpy h of first end4With the refrigerant enthalpy h according to the indoor heat exchanger first end7 refrigerantsWith lubricating oil enthalpy
h7 lubricating oilGenerate the mixture enthalpy h of indoor heat exchanger first end7;According to the power of the compressor, the housing of the compressor
Heat dissipation capacity Qloss, the gas returning port mixture enthalpy h1, exhaust outlet mixture enthalpy h2, outdoor heat exchanger first end it is mixed
Compound enthalpy h4With the mixture enthalpy h of indoor heat exchanger first end7Generate the refrigerating capacity of air conditioner;And according to the air-conditioning
Device power consumption and the refrigerating capacity generate the efficiency of the air conditioner.
The efficiency computational methods of air conditioner according to embodiments of the present invention, by the current working, the compression that obtain air conditioner
The housing heat dissipation capacity Q of the power of machine, air conditioner power consumption and compressorloss, and obtain gas returning port in compressor, exhaust outlet,
The temperature of outdoor heat exchanger first end and indoor heat exchanger first end, and when air conditioner is in cooling condition according to above-mentioned each
The temperature of individual position generates the refrigerant enthalpy and lubricating oil enthalpy of above-mentioned each position, and further generates the mixed of each position
Compound enthalpy, the housing heat dissipation capacity Q of power, compressor then in conjunction with compressorloss, above-mentioned each position mixture enthalpy
The efficiency of air conditioner is obtained with air conditioner power consumption, thereby, it is possible to real-time and accurately detect the efficiency of air conditioner, so as to just
In the running status for optimizing air conditioner according to the real-time energy efficiency of air conditioner, reach energy-conservation and improve the purpose of refrigeration.
In addition, the efficiency computational methods of the air conditioner proposed according to the above embodiment of the present invention can also have following add
Technical characteristic:
According to one embodiment of present invention, according to the gas returning port temperature t of gas returning port in the compressor1Generate gas returning port
Refrigerant enthalpy h1 refrigerantSpecifically include:Obtain the indoor heat exchanger middle portion temperature t in the middle part of indoor heat exchanger6;According to described time
Gas port temperature t1With indoor heat exchanger middle portion temperature t6Generate suction superheat Δ t1;According to the suction superheat Δ t1And room
Interior heat exchanger middle portion temperature t6Generate the modifying factor D of gas returning port refrigerant enthalpy1;According to the indoor heat exchanger middle portion temperature
t6Generate the enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation;According to the modifying factor D of the gas returning port refrigerant enthalpy1, institute
State the enthalpy h of saturation refrigerantAir-breathing saturationGenerate the refrigerant enthalpy h1 refrigerant.Further, air-breathing is generated according to below equation
At a temperature of saturation refrigerant enthalpy hAir-breathing saturation:hAir-breathing saturation=a1+a2t6+a3t2 6+a4t3 6+a5, wherein, a1-a5It is corresponding for refrigerant
Saturation region coefficient.
Further, the enthalpy h of saturation refrigerant under suction temperature is generated according to below equationAir-breathing saturation:
hAir-breathing saturation=a1+a2t6+a3t2 6+a4t3 6+a5, wherein, a1-a5For saturation region coefficient corresponding to refrigerant.
Further, the modifying factor D of gas returning port refrigerant enthalpy is generated according to below equation1:
D1=1+d1Δt1+d2(Δt1)2+d3(Δt1)t6+d4(Δt1)2t6+d5(Δt1)t2 6+d6(Δt1)2t2 6, wherein,
d1-d6For overheated zone coefficient corresponding to refrigerant.
Further, according to the indoor heat exchanger first end temperature t of the indoor heat exchanger first end7Generate indoor heat exchange
The refrigerant enthalpy h of device first end7 refrigerantsSpecifically include:According to the indoor heat exchanger first end temperature t7With the indoor heat exchange
Device middle portion temperature t6Generate degree of superheat Δ t7;According to the degree of superheat Δ t7With the indoor heat exchanger middle portion temperature t6Generate room
The modifying factor D of interior heat exchanger first end refrigerant enthalpy7;According to the amendment of the indoor heat exchanger first end refrigerant enthalpy
Factor D7With the enthalpy h of the saturation refrigerantAir-breathing saturationGenerate the refrigerant enthalpy h7 refrigerants。
Further, the modifying factor D of indoor heat exchanger first end refrigerant enthalpy is generated according to below equation7:
Wherein, d1-d6
For overheated zone coefficient corresponding to refrigerant.
According to one embodiment of present invention, the exhaust port temperatures t according to exhaust outlet in the compressor2Generation institute
State the refrigerant enthalpy h of exhaust outlet2 refrigerantsSpecifically include:Obtain the outdoor heat exchanger middle portion temperature t in the middle part of outdoor heat exchanger3;Root
According to the exhaust port temperatures t of exhaust outlet in the compressor2With the outdoor heat exchanger middle portion temperature t3Generate discharge superheat Δ
t2;According to the discharge superheat Δ t2With the outdoor heat exchanger middle portion temperature t3Generate the amendment of exhaust outlet refrigerant enthalpy
Factor D2:According to the outdoor heat exchanger middle portion temperature t3Generate the enthalpy h of saturation refrigerant under delivery temperatureIt is vented saturation;According to institute
State the modifying factor D of exhaust outlet refrigerant enthalpy2, under the delivery temperature saturation refrigerant enthalpy hIt is vented saturationGenerate the row
The refrigerant enthalpy h of gas port2 refrigerants。
Further, the modifying factor D of exhaust outlet refrigerant enthalpy is generated according to below equation2:
D2=1+d1Δt2+d2(Δt2)2+d3(Δt2)t3+d4(Δt2)2t3+d5(Δt2)t2 3+d6(Δt2)2t2 3Wherein,
d1-d6For overheated zone coefficient corresponding to refrigerant.
According to one embodiment of present invention, the refrigerant enthalpy of the outdoor heat exchanger first end is generated according to below equation
Value h4 refrigerants:
Wherein, c1-c4For fauna number is subcooled corresponding to refrigerant.
According to one embodiment of present invention, the refrigerating capacity of air conditioner is generated according to below equation:
Wherein, QRefrigerating capacityFor the Air conditioner refrigerating capacity, PCompressorFor compressor horsepower.
According to one embodiment of present invention, the lubricating oil enthalpy of each temperature detecting point is calculated according to below equation
hI lubricating oil, wherein, i is positive integer,
hI lubricating oil=-0.0808+1.7032ti+0.0025t2 i, wherein, tiFor the temperature of temperature detecting point.
According to one embodiment of present invention, the mixture enthalpy h of each temperature detecting point is calculated according to below equationi,
Wherein, i is positive integer,
hi=(1-Cg)hI refrigerants+CghI lubricating oil
Cg=f/104, wherein, CgFor mixture oil content, f is the running frequency of the compressor.
According to one embodiment of present invention, the housing heat dissipation capacity Q of compressor is generated according to below equationloss:
Qloss=5.67 × 10-8×ACompressor((t2+273.15)4-(t8+273.15)4+(9.4+0.052×(t2-t8))×
ACompressor×(t2-t8), wherein, ACompressorFor the surface area of compressor housing, t8 is the temperature at outdoor heat exchanger fin.
According to one embodiment of present invention, the gas returning port temperature t is generated according to below equation1:
t1=a*t9+b*t4+ c*f, f are the running frequency of compressor, and a, b, c is fitting coefficient.
To reach above-mentioned purpose, a kind of air conditioner that second aspect of the present invention embodiment proposes includes memory, processor
And the computer program that can be run on the memory and on the processor is stored in, calculating described in the computing device
During machine program, the efficiency computational methods for the air conditioner that first aspect present invention embodiment proposes are realized.
Air conditioner according to embodiments of the present invention, real-time and accurately efficiency can be detected.
To reach above-mentioned purpose, a kind of non-transitory computer-readable storage medium that third aspect present invention embodiment proposes
Matter, is stored thereon with computer program, and the computer program realizes first aspect present invention embodiment when being executed by processor
The efficiency computational methods of the air conditioner of proposition.
Non-transitorycomputer readable storage medium according to embodiments of the present invention, by the computer journey for performing its storage
Sequence, the efficiency of air conditioner can be real-time and accurately detected, consequently facilitating optimizing air conditioner according to the real-time energy efficiency of air conditioner
Running status, reach energy-conservation and improve the purpose of refrigeration.
To reach above-mentioned purpose, the efficiency computational methods bag for another air conditioner that fourth aspect present invention embodiment proposes
Include following steps:Obtain current working, the power and air conditioner power consumption of compressor of air conditioner;Obtain the housing of compressor
Heat dissipation capacity Qloss;Obtain the gas returning port temperature t of gas returning port in compressor1, in the compressor exhaust outlet exhaust port temperatures t2、
The second end of indoor heat exchanger temperature t at the end of indoor heat exchanger second5With the indoor heat exchanger first end of indoor heat exchanger first end
Temperature t7, wherein, the gas returning port temperature t1According to indoor environment temperature t9With outdoor heat exchanger first end temperature t4Generation;When
When the current working of the air conditioner is heating condition, according to the gas returning port temperature t of gas returning port in the compressor1Generate return-air
The refrigerant enthalpy h of mouth1 refrigerantWith lubricating oil enthalpy h1 lubricating oil, according to the exhaust port temperatures t of exhaust outlet in the compressor2Generation
The refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, according to the indoor heat exchanger at the end of indoor heat exchanger second
Second end temperature t5Generate the refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerantsWith lubricating oil enthalpy h5 lubricating oilWith according to the room
The indoor heat exchanger first end temperature t of interior heat exchanger first end7Generate the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerantsWith
Lubricating oil enthalpy h7 lubricating oil;According to the refrigerant enthalpy h of the gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oilGenerate the mixed of gas returning port
Compound enthalpy h1, according to the refrigerant enthalpy h of the exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oilGenerate the mixture of exhaust outlet
Enthalpy h2, according to the refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerantsWith lubricating oil enthalpy h5 lubricating oilGenerate indoor heat exchange
The mixture enthalpy h at the end of device second5With the refrigerant enthalpy h according to the indoor heat exchanger first end7 refrigerantsWith lubricating oil enthalpy
h7 lubricating oilGenerate the mixture enthalpy h of indoor heat exchanger first end7;According to the power of the compressor, the housing of the compressor
Heat dissipation capacity Qloss, the gas returning port mixture enthalpy h1, exhaust outlet mixture enthalpy h2, the end of indoor heat exchanger second it is mixed
Compound enthalpy h5With the mixture enthalpy h of indoor heat exchanger first end7Generate the heating capacity of air conditioner;And according to the air-conditioning
Device power consumption and the heating capacity generate the efficiency of the air conditioner.
The efficiency computational methods of air conditioner according to embodiments of the present invention, by the current working, the compression that obtain air conditioner
The housing heat dissipation capacity Q of the power of machine, air conditioner power consumption and compressorloss, and obtain gas returning port in compressor, exhaust outlet,
The end of indoor heat exchanger second and the temperature of indoor heat exchanger first end, and when air conditioner is in heating condition according to above-mentioned each
The temperature of individual position generates the refrigerant enthalpy and lubricating oil enthalpy of above-mentioned each position, and further generates the mixed of each position
Compound enthalpy, the housing heat dissipation capacity Q of power, compressor then in conjunction with compressorloss, above-mentioned each position mixture enthalpy
The efficiency of air conditioner is obtained with air conditioner power consumption, thereby, it is possible to real-time and accurately detect the efficiency of air conditioner, so as to just
In the running status for optimizing air conditioner according to the real-time energy efficiency of air conditioner, reach energy-conservation and improve the purpose of heating effect.
In addition, the efficiency computational methods of the air conditioner proposed according to the above embodiment of the present invention can also have following add
Technical characteristic:
According to one embodiment of present invention, the gas returning port temperature t according to gas returning port in the compressor1Generate back
The refrigerant enthalpy h of gas port1 refrigerantSpecifically include:Obtain the outdoor heat exchanger middle portion temperature t in the middle part of outdoor heat exchanger3;According to institute
State gas returning port temperature t1With the outdoor heat exchanger middle portion temperature t3Generate suction superheat Δ t1;According to the suction superheat
Δt1With the outdoor heat exchanger middle portion temperature t3Generate the modifying factor D of gas returning port refrigerant enthalpy1;Changed according to the outdoor
Hot device middle portion temperature t3Generate the enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation;According to the gas returning port refrigerant enthalpy
Modifying factor D1, under the suction temperature saturation refrigerant enthalpy hAir-breathing saturationGenerate the refrigerant enthalpy h of the gas returning port1 refrigerant。
Further, the enthalpy h of saturation refrigerant under the suction temperature is generated according to below equationAir-breathing saturation:
Wherein, a1-a5For saturation region coefficient corresponding to refrigerant.
Further, the modifying factor D of the gas returning port refrigerant enthalpy is generated according to below equation1:
Wherein, d1-d6For
Overheated zone coefficient corresponding to refrigerant.
Further, the exhaust port temperatures t according to exhaust outlet in the compressor2Generate the refrigeration of the exhaust outlet
Agent enthalpy h2 refrigerantsSpecifically include:Obtain the indoor heat exchanger middle portion temperature t in the middle part of indoor heat exchanger6;According to the indoor heat exchange
Indoor heat exchanger middle portion temperature t in the middle part of device6With the exhaust port temperatures t of exhaust outlet in the compressor2Generate discharge superheat Δ
t2;According to the discharge superheat Δ t2With the indoor heat exchanger middle portion temperature t6Generate the amendment of exhaust outlet refrigerant enthalpy
Factor D2;According to the indoor heat exchanger middle portion temperature t in the middle part of the indoor heat exchanger6Generate saturation refrigerant under delivery temperature
Enthalpy hIt is vented saturation;According to the modifying factor D of the exhaust outlet refrigerant enthalpy2, under the delivery temperature saturation refrigerant enthalpy
hIt is vented saturationGenerate the refrigerant enthalpy h of the exhaust outlet2 refrigerants。
Further, the modifying factor D of the exhaust outlet refrigerant enthalpy is generated according to below equation2:
D2=1+d1Δt2+d2(Δt2)2+d3(Δt2)t6+d4(Δt2)2t6+d5(Δt2)t2 6+d6(Δt2)2t2 6, wherein,
d1-d6For overheated zone coefficient corresponding to refrigerant.
Further, the indoor heat exchanger first end temperature t according to the indoor heat exchanger first end7Generate respectively
The refrigerant enthalpy h of the indoor heat exchanger first end7 refrigerantsSpecifically include:Changed according to the interior in the middle part of the indoor heat exchanger
Hot device middle portion temperature t6With the indoor heat exchanger first end temperature t7Generate degree of superheat Δ t7;According to the degree of superheat Δ t7With
The indoor heat exchanger middle portion temperature t6Generate the modifying factor D of indoor heat exchanger first end refrigerant enthalpy7;According to the room
The modifying factor D of interior heat exchanger first end refrigerant enthalpy7, under the delivery temperature saturation refrigerant enthalpy hIt is vented saturationGeneration
The refrigerant enthalpy h of the indoor heat exchanger first end7 refrigerants。
Further, the modifying factor D of the indoor heat exchanger first end refrigerant enthalpy is generated according to below equation7:
Wherein, d1-d6
For overheated zone coefficient corresponding to refrigerant.
According to one embodiment of present invention, the refrigerant enthalpy at the end of indoor heat exchanger second is calculated according to below equation
Value h5 refrigerants:
h5 refrigerants=c1+c2t5+c3t2 5+c4t3 5, wherein, c1-c4For fauna number is subcooled corresponding to refrigerant.
According to one embodiment of present invention, the heating capacity of the air conditioner is generated according to equation below:
Wherein, QHeating capacityFor the heating capacity of air conditioner, PCompressorFor compressor horsepower.
According to one embodiment of present invention, the lubricating oil enthalpy of each temperature detecting point is calculated according to below equation
hI lubricating oil, wherein, i is positive integer,
hI lubricating oil=-0.0808+1.7032ti+0.0025t2 i, wherein, tiFor the temperature of temperature detecting point.
According to one embodiment of present invention, the mixture enthalpy h of each temperature detecting point is calculated according to below equationi,
Wherein, i is positive integer,
hi=(1-Cg)hI refrigerants+CghI lubricating oil
Cg=f/104, wherein, CgFor mixture oil content, f is the running frequency of the compressor.
According to one embodiment of present invention, the housing heat dissipation capacity Q of compressor is generated according to below equationloss:
Qloss=5.67 × 10-8×ACompressor((t2+273.15)4-(t8+273.15)4+(9.4+0.052×(t2-t8))×
ACompressor×(t2-t8), wherein, ACompressorFor the surface area of compressor housing, t8 is the temperature at outdoor heat exchanger fin.
According to one embodiment of present invention, the gas returning port temperature t is generated according to below equation1:
t1=a*t9+b*t4+ c*f, f are the running frequency of compressor, and a, b, c is fitting coefficient.
To reach above-mentioned purpose, another air conditioner that fifth aspect present invention embodiment proposes includes memory, processing
Device and the computer program that can be run on the memory and on the processor is stored in, meter described in the computing device
During calculation machine program, the efficiency computational methods for the air conditioner that fourth aspect present invention embodiment proposes are realized.
Air conditioner according to embodiments of the present invention, real-time and accurately efficiency can be detected.
To reach above-mentioned purpose, the computer-readable storage of another non-transitory that sixth aspect present invention embodiment proposes
Medium, is stored thereon with computer program, and the computer program realizes that fourth aspect present invention is implemented when being executed by processor
The efficiency computational methods for the air conditioner that example proposes.
Non-transitorycomputer readable storage medium according to embodiments of the present invention, by the computer journey for performing its storage
Sequence, the efficiency of air conditioner can be real-time and accurately detected, consequently facilitating optimizing air conditioner according to the real-time energy efficiency of air conditioner
Running status, reach energy-conservation and improve the purpose of heating effect.
Brief description of the drawings
Fig. 1 is the flow chart according to the efficiency computational methods of the air conditioner of the embodiment of the present invention;
Fig. 2 is the structural representation according to the air conditioner of one embodiment of the invention;
Fig. 3 is the block diagram according to the efficiency computing system of the air conditioner of the embodiment of the present invention;
Fig. 4 is the flow chart according to the efficiency computational methods of another air conditioner of the embodiment of the present invention;
Fig. 5 is the block diagram according to the efficiency computing system of another air conditioner of the embodiment of the present invention.
Embodiment
Embodiments of the invention are described below in detail, the example of the embodiment is shown in the drawings, wherein from beginning to end
Same or similar label represents same or similar element or the element with same or like function.Below with reference to attached
The embodiment of figure description is exemplary, it is intended to for explaining the present invention, and is not considered as limiting the invention.
The air conditioner of the embodiment of the present invention and its efficiency computational methods are described below in conjunction with the accompanying drawings.
Fig. 1 is the flow chart according to the efficiency computational methods of the air conditioner of the embodiment of the present invention.
As shown in figure 1, the efficiency computational methods of the air conditioner of the embodiment of the present invention, comprise the following steps:
S101, obtain the current working of air conditioner, the power of compressor and air conditioner power consumption.
The current working of air conditioner, the power P of compressor can be monitored in real time by the electric-control system of air conditionerCompressorAnd air-conditioning
Device power consumption PPower consumption。
S102, obtain the housing heat dissipation capacity Q of compressorloss。
S103, obtain the gas returning port temperature t of gas returning port in compressor1, in compressor exhaust outlet exhaust port temperatures t2, room
The outdoor heat exchanger first end temperature t of external heat exchanger first end4With the indoor heat exchanger first end temperature of indoor heat exchanger first end
Spend t7, wherein, gas returning port temperature t1According to indoor environment temperature t9With outdoor heat exchanger first end temperature t4Generation.
The air conditioner of the embodiment of the present invention can be single-stage vapor compression formula air conditioner, as shown in Fig. 2 the embodiment of the present invention
Air conditioner may include compressor, four-way valve, outdoor heat exchanger, restricting element and indoor heat exchanger.
In one embodiment of the invention, the housing heat dissipation capacity Q of compressor can be calculated by convection current, radiation formulaloss,
The housing heat dissipation capacity Q of compressor can be specifically generated according to below equationloss:
Qloss=5.67 × 10-8×ACompressor((t2+273.15)4-(t8+273.15)4+(9.4+0.052×(t2-t8))×
ACompressor×(t2-t8),
Wherein, ACompressorFor the surface area of compressor housing, it can wait acquisition by looking into pressure contracting type number;t8Changed for outdoor
Temperature at hot device fin, i.e. outdoor environment temperature, as shown in Fig. 2 it can be by the room that is disposed in the outdoor at heat exchanger fin
Outer temperature sensor detects to obtain.
In one embodiment of the invention, can be by setting temperature sensor to detect respectively in corresponding temperature test point
The temperature of the temperature detecting point.Specifically, as shown in Fig. 2 by within the compressor at gas returning port gas returning port temperature can be set to pass
Sensor is to detect gas returning port temperature t1, within the compressor exhaust ports exhaust port temperatures sensor is set to detect exhaust port temperatures
t2, at outdoor heat exchanger first end outdoor heat exchanger first end temperature sensor is set to detect outdoor heat exchanger first end temperature
Spend t4, indoors indoor heat exchanger first end temperature sensor is set to detect indoor heat exchanger first end at heat exchanger first end
Temperature t7And at heat exchanger fin indoor temperature transmitter is set to detect indoor environment temperature t indoors9。
Wherein, each temperature sensor effectively contacts with the refrigerant tube wall of corresponding temperature test point, and to refrigerant
Tube wall, especially the position of temperature sensor is set to take Insulation.For example, temperature sensor can be close to copper pipe setting,
And sealing is wound to copper pipe by being incubated adhesive tape.Thereby, it is possible to improve the reliability and accuracy of temperature detection.
In one embodiment of the invention, gas returning port temperature t can be generated according to below equation1:
t1=a*t9+b*t4+ c*f, f are compressor operating frequency, and a, b, c is fitting coefficient.
S104, when the current working of air conditioner is cooling condition, according to the gas returning port temperature t of gas returning port in compressor1
Generate the refrigerant enthalpy h of gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oil, according to the exhaust port temperatures t of exhaust outlet in compressor2
Generate the refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, according to the outdoor heat exchanger of outdoor heat exchanger first end
First end temperature t4Generate the refrigerant enthalpy h of outdoor heat exchanger first end4 refrigerantsWith lubricating oil enthalpy h4 lubricating oilChanged with according to interior
The indoor heat exchanger first end temperature t of hot device first end7Generate the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerantsAnd lubrication
Oily enthalpy h7 lubricating oil。
Herein it should be noted that when the current working of air conditioner is cooling condition, outdoor heat exchanger makees condenser, room
External heat exchanger first end is condensator outlet, and indoor heat exchanger makees evaporator, and indoor heat exchanger first end is evaporator outlet, room
The interior end of heat exchanger second is evaporator inlet.
Because the refrigerant of different temperatures test point and the state of the mixture of lubricating oil are different, therefore different temperatures detects
The refrigerant enthalpy and lubricating oil enthalpy of point are different.In one embodiment of the invention, rule of thumb formula can calculate
To refrigerant enthalpy and lubricating oil enthalpy.
Illustrate that rule of thumb formula obtains the refrigerant enthalpy h of gas returning port separately below1 refrigerantWith lubricating oil enthalpy h1 lubricating oil、
The refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, outdoor heat exchanger first end refrigerant enthalpy h4 refrigerantsAnd profit
Lubricating oil enthalpy h4 lubricating oil, indoor heat exchanger first end refrigerant enthalpy h7 refrigerantsWith lubricating oil enthalpy h7 lubricating oilDetailed process.
For the refrigerant enthalpy h of gas returning port in compressor1 refrigerant, when the current working of air conditioner is cooling condition, pressure
The refrigerant superheat of the gas returning port of contracting machine, the refrigerant enthalpy h that suction superheat calculates gas returning port can be combined1 refrigerant。
Specifically, the indoor heat exchanger middle portion temperature t in the middle part of indoor heat exchanger can be obtained6, wherein, as shown in Fig. 2 indoor
Indoor heat exchanger middle portion temperature t in the middle part of heat exchanger6Can be warm by the indoor heat exchanger middle part set in the middle part of heat exchanger indoors
Degree sensor detects to obtain.
Then can be according to gas returning port temperature t1With indoor heat exchanger middle portion temperature t6Generate suction superheat Δ t1, and according to
Suction superheat Δ t1With indoor heat exchanger middle portion temperature t6Generate the modifying factor D of gas returning port refrigerant enthalpy1, and according to
Indoor heat exchanger middle portion temperature t6Generate the enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation.Wherein, suction superheat Δ t1For
Gas returning port temperature t1With indoor heat exchanger middle portion temperature t6Difference, i.e. Δ t1=t1-t6.The modifying factor of gas returning port refrigerant enthalpy
D1=1+d1Δt1+d2(Δt1)2+d3(Δt1)t6+d4(Δt1)2t6+d5(Δt1)t2 6+d6(Δt1)2t2 6, wherein, d1-d6For system
Overheated zone coefficient corresponding to cryogen.The enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation=a1+a2t6+a3t2 6+a4t3 6+a5, its
In, a1-a5For saturation region coefficient corresponding to refrigerant.
In the modifying factor D of generation gas returning port refrigerant enthalpy1, saturation refrigerant enthalpy hAir-breathing saturationAfterwards, can further root
According to the modifying factor D of gas returning port refrigerant enthalpy1, saturation refrigerant enthalpy hAir-breathing saturationGenerate refrigerant enthalpy h1 refrigerant, h1 refrigerant
=D1·hAir-breathing saturation+d7, wherein, d7For overheated zone coefficient corresponding to refrigerant.
Similarly, for the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerants, when the current working of air conditioner is refrigeration
During operating mode, the refrigerant superheat of indoor heat exchanger first end, position refrigerant superheat degree can be combined and calculate indoor heat exchanger the
The refrigerant enthalpy h of one end7 refrigerants。
Specifically, can be according to indoor heat exchanger first end temperature t7With indoor heat exchanger middle portion temperature t6Generate degree of superheat Δ
t7, and according to degree of superheat Δ t7With indoor heat exchanger middle portion temperature t6Generate the amendment of indoor heat exchanger first end refrigerant enthalpy
Factor D7, and the modifying factor D of the indoor heat exchanger first end refrigerant enthalpy according to generation7With the enthalpy of saturation refrigerant
hAir-breathing saturationGenerate refrigerant enthalpy h7 refrigerants.Wherein, Δ t7=t7-t6,
h7 refrigerants=D7·
hAir-breathing saturation+d7, wherein, d1-d7For overheated zone coefficient corresponding to refrigerant.
For the refrigerant enthalpy h of exhaust outlet in compressor2 refrigerants, when the current working of air conditioner is cooling condition, pressure
The refrigerant superheat of the exhaust outlet of contracting machine, the refrigerant enthalpy h that discharge superheat calculates exhaust outlet can be combined2 refrigerants。
Specifically, the outdoor heat exchanger middle portion temperature t in the middle part of outdoor heat exchanger can be obtained3, wherein, as shown in Fig. 2 outdoor
Outdoor heat exchanger middle portion temperature t in the middle part of heat exchanger3Temperature in the middle part of the outdoor heat exchanger that is set in the middle part of outdoor heat exchanger can be passed through
Degree sensor detects to obtain.
Then, can be according to the exhaust port temperatures t of exhaust outlet in compressor2With outdoor heat exchanger middle portion temperature t3Generation exhaust
Degree of superheat Δ t2, and according to discharge superheat Δ t2With outdoor heat exchanger middle portion temperature t3Generation exhaust outlet refrigerant enthalpy is repaiied
Positive divisor D2, and according to outdoor heat exchanger middle portion temperature t3Generate the enthalpy h of saturation refrigerant under delivery temperatureIt is vented saturation.Wherein,
Discharge superheat Δ t2For the exhaust port temperatures t of exhaust outlet in compressor2With outdoor heat exchanger middle portion temperature t3Difference, i.e. Δ t2
=t2-t3.The modifying factor D of exhaust outlet refrigerant enthalpy2=1+d1Δt2+d2(Δt2)2+d3(Δt2)t3+d4(Δt2)2t3+d5
(Δt2)t2 3+d6(Δt2)2t2 3, wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.Saturation refrigerant under delivery temperature
Enthalpy hIt is vented saturation=a1+a2t3+a3t2 3+a4t3 3+a5, wherein, a1-a5For saturation region coefficient corresponding to refrigerant.
In the modifying factor D of generation exhaust outlet refrigerant enthalpy2, under delivery temperature saturation refrigerant enthalpy hIt is vented saturationAfterwards,
Can be further according to the modifying factor D of exhaust outlet refrigerant enthalpy2, under delivery temperature saturation refrigerant enthalpy hIt is vented saturationGeneration
The refrigerant enthalpy h of exhaust outlet2 refrigerants, h2 refrigerants=D2·hIt is vented saturation+d7, wherein, d7For overheated zone coefficient corresponding to refrigerant.
For the refrigerant enthalpy h of outdoor heat exchanger first end4 refrigerants, when the current working of air conditioner is cooling condition,
The refrigerant supercooling of outdoor heat exchanger first end, it can directly calculate the refrigerant enthalpy h of outdoor heat exchanger first end4 refrigerants:Wherein, c1-c4For fauna number is subcooled corresponding to refrigerant.
Saturation region coefficient, overheated zone coefficient and the species of supercooling fauna number and refrigerant have corresponding to above-mentioned refrigerant
Close, R410A refrigerants and saturation region coefficient corresponding to R32 refrigerants, overheated zone coefficient are respectively illustrated in table 1 and crosses cold-zone
Coefficient:
Table 1
Thus, each coefficient value can be obtained according to the species of refrigerant and the corresponding relation of such as table 1, is examined with calculating each temperature
The refrigerant enthalpy of measuring point.
In other embodiments of the invention, the result of calculation of software can be also directly invoked, or is obtained by other approach
The refrigerant enthalpy of each temperature detecting point.For example, can also be according to sky when the current working of air conditioner is cooling condition
Adjust low pressure, the gas returning port temperature t in device1, indoor heat exchanger first end temperature t7Respectively obtain the refrigerant enthalpy of gas returning port
h1With the refrigerant enthalpy h of indoor heat exchanger first end7, and can be according to the high-pressure in air conditioner, exhaust port temperatures t2, room
External heat exchanger first end temperature t4Respectively obtain the refrigerant enthalpy h of exhaust outlet2With the refrigerant enthalpy of outdoor heat exchanger first end
h4。
For the lubricating oil enthalpy h of each temperature detecting pointI lubricating oil, can be calculated according to below equation:
hI lubricating oil=-0.0808+1.7032ti+0.0025t2 i,
Wherein, i is positive integer, tiFor the temperature of temperature detecting point.Thus, the lubricating oil enthalpy of gas returning port can be calculated out
Value h1 lubricating oil, exhaust outlet lubricating oil enthalpy h2 lubricating oil, outdoor heat exchanger first end lubricating oil enthalpy h4 lubricating oilAnd indoor heat exchanger
The lubricating oil enthalpy h of first end7 lubricating oil。
S105, according to the refrigerant enthalpy h of gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oilGenerate the mixture enthalpy of gas returning port
Value h1, according to the refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oilGenerate the mixture enthalpy h of exhaust outlet2, according to
The refrigerant enthalpy h of outdoor heat exchanger first end4 refrigerantsWith lubricating oil enthalpy h4 lubricating oilGenerate the mixture of outdoor heat exchanger first end
Enthalpy h4With the refrigerant enthalpy h according to indoor heat exchanger first end7 refrigerantsWith lubricating oil enthalpy h7 lubricating oilGenerate indoor heat exchanger the
The mixture enthalpy h of one end7。
Specifically, the mixture enthalpy h of each temperature detecting point can be calculated according to below equationi:
hi=(1-Cg)hI refrigerants+CghI lubricating oil
Cg=f/104,
Wherein, CgFor mixture oil content, f is the running frequency of compressor.Thus, the mixed of gas returning port can be calculated out
Compound enthalpy h1, exhaust outlet mixture enthalpy h2, outdoor heat exchanger first end mixture enthalpy h4With indoor heat exchanger first
The mixture enthalpy h at end7。
S106, according to the power of compressor, the housing heat dissipation capacity Q of compressorloss, gas returning port mixture enthalpy h1, exhaust
The mixture enthalpy h of mouth2, outdoor heat exchanger first end mixture enthalpy h4With the mixture enthalpy of indoor heat exchanger first end
h7Generate the refrigerating capacity of air conditioner.
Specifically, the refrigerating capacity of air conditioner can be generated according to below equation:Wherein,
QRefrigerating capacityFor Air conditioner refrigerating capacity, PCompressorFor compressor horsepower.
S107, the efficiency of air conditioner is generated according to air conditioner power consumption and refrigerating capacity.
Because the current working of air conditioner is cooling condition, thus can be generated according to air conditioner power consumption and refrigerating capacity empty
The refrigeration efficiency of device is adjusted, specifically, the refrigeration efficiency of air conditioner is the ratio between the refrigerating capacity of air conditioner and power consumption, i.e. EER=
QRefrigerating capacity/PPower consumption。
, can also be according to operation shape of the refrigeration efficiency of air conditioner to current air conditioner after the refrigeration efficiency of generation air conditioner
State is adjusted.For example, the power of compressor can be improved when the refrigeration efficiency of air conditioner is relatively low, to improve air conditioner
Refrigerating capacity, and the energy consumption of relative reduction air conditioner, so as to save, additionally it is possible to improve the comfortableness of user.
The efficiency computational methods of air conditioner according to embodiments of the present invention, by the current working, the compression that obtain air conditioner
The housing heat dissipation capacity of the power of machine, air conditioner power consumption and compressor, and obtain gas returning port in compressor, exhaust outlet, outdoor
The temperature of heat exchanger first end and indoor heat exchanger first end, and when air conditioner is in cooling condition according to above-mentioned each position
The temperature put generates the refrigerant enthalpy and lubricating oil enthalpy of above-mentioned each position, and further generates the mixture of each position
Enthalpy, the housing heat dissipation capacity of power, compressor then in conjunction with compressor, the mixture enthalpy and air conditioner of above-mentioned each position
Power consumption obtains the efficiency of air conditioner, thereby, it is possible to real-time and accurately detect the efficiency of air conditioner, consequently facilitating according to sky
The running status of the real-time energy efficiency optimization air conditioner of device is adjusted, reaches energy-conservation and improves the purpose of refrigeration.
Corresponding above-described embodiment, the present invention also propose a kind of air conditioner.
The air conditioner of the embodiment of the present invention, including memory, processor and storage are on a memory and can be on a processor
The computer program of operation, during computing device computer program, the air conditioner that the above embodiment of the present invention proposes can be achieved
Efficiency computational methods.
Air conditioner according to embodiments of the present invention, real-time and accurately efficiency can be detected.
Corresponding above-described embodiment, the present invention also propose a kind of non-transitorycomputer readable storage medium.
The non-transitorycomputer readable storage medium of the embodiment of the present invention, is stored thereon with computer program, the calculating
When machine program is executed by processor, the efficiency computational methods for the air conditioner that the above embodiment of the present invention proposes can be achieved.
Non-transitorycomputer readable storage medium according to embodiments of the present invention, by the computer journey for performing its storage
Sequence, the efficiency of air conditioner can be real-time and accurately detected, consequently facilitating optimizing air conditioner according to the real-time energy efficiency of air conditioner
Running status, reach energy-conservation and improve the purpose of refrigeration.
Corresponding above-described embodiment, the present invention also propose a kind of efficiency computing system of air conditioner.
As shown in figure 3, the efficiency computing system of the air conditioner of the embodiment of the present invention, including exhaust port temperatures sensor 02,
Outdoor heat exchanger first end temperature sensor 04, indoor heat exchanger first end temperature sensor 07 and gas returning port temperature generation mould
Block 00, acquisition module 10, mixture enthalpy generation module 20, refrigerating capacity generation module 30, efficiency generation module 40.
Wherein, exhaust port temperatures sensor 02 is used for the exhaust port temperatures t for obtaining exhaust outlet in compressor2;Outdoor heat exchange
Device first end temperature sensor 04 is used for the outdoor heat exchanger first end temperature t for obtaining outdoor heat exchanger first end4;Indoor heat exchange
Device first end temperature sensor 07 is used for the indoor heat exchanger first end temperature t for obtaining indoor heat exchanger first end7。
The air conditioner of the embodiment of the present invention can be single-stage vapor compression formula air conditioner, as shown in Fig. 2 the embodiment of the present invention
Air conditioner may include compressor 100, four-way valve 200, outdoor heat exchanger 300, restricting element 400 and indoor heat exchanger 500.
As shown in Fig. 2 gas returning port temperature sensor 01 can be set within the compressor at gas returning port, exhaust port temperatures sensor
02 settable exhaust ports, outdoor heat exchanger first end temperature sensor 04 may be provided at outdoor heat exchanger first within the compressor
Indoor heat exchanger first end can be set in end, indoor heat exchanger first end temperature sensor 07.Wherein, each temperature sensor with
The refrigerant tube wall of corresponding temperature test point effectively contacts, and to the position of refrigerant tube wall, especially setting temperature sensor
Take Insulation.For example, temperature sensor can be close to copper pipe setting, and copper pipe is wound by being incubated adhesive tape close
Envelope.Thereby, it is possible to improve the reliability and accuracy of temperature detection.
Gas returning port temperature generation module 00 is used for according to indoor environment temperature t9With outdoor heat exchanger first end temperature t4Generation
Gas returning port temperature t1;Acquisition module 10 be used for obtain the current working of air conditioner, the power of compressor, air conditioner power consumption with
And the housing heat dissipation capacity Q of compressorloss;Mixture enthalpy generation module 20 is used for when the current working of air conditioner is cooling condition
When, according to the gas returning port temperature t of gas returning port in compressor1Generate the refrigerant enthalpy h of gas returning port1 refrigerantWith lubricating oil enthalpy
h1 lubricating oil, according to the exhaust port temperatures t of exhaust outlet in compressor2Generate the refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy
h2 lubricating oil, according to the outdoor heat exchanger first end temperature t of outdoor heat exchanger first end4Generate the refrigerant of outdoor heat exchanger first end
Enthalpy h4 refrigerantsWith lubricating oil enthalpy h4 lubricating oilWith the indoor heat exchanger first end temperature t according to indoor heat exchanger first end7Generate room
The refrigerant enthalpy h of interior heat exchanger first end7 refrigerantsWith lubricating oil enthalpy h7 lubricating oil, and the refrigerant enthalpy according to gas returning port
h1 refrigerantWith lubricating oil enthalpy h1 lubricating oilGenerate the mixture enthalpy h of gas returning port1, according to the refrigerant enthalpy h of exhaust outlet2 refrigerantsAnd profit
Lubricating oil enthalpy h2 lubricating oilGenerate the mixture enthalpy h of exhaust outlet2, according to the refrigerant enthalpy h of outdoor heat exchanger first end4 refrigerantsWith
Lubricating oil enthalpy h4 lubricating oilGenerate the mixture enthalpy h of outdoor heat exchanger first end4With the refrigeration according to indoor heat exchanger first end
Agent enthalpy h7 refrigerantsWith lubricating oil enthalpy h7 lubricating oilGenerate the mixture enthalpy h of indoor heat exchanger first end7;Refrigerating capacity generation module
30 are used for power, the housing heat dissipation capacity Q of compressor according to compressorloss, gas returning port mixture enthalpy h1, exhaust outlet it is mixed
Compound enthalpy h2, outdoor heat exchanger first end mixture enthalpy h4With the mixture enthalpy h of indoor heat exchanger first end7Generation
The refrigerating capacity of air conditioner;Efficiency generation module 40 is used for the efficiency that air conditioner is generated according to air conditioner power consumption and refrigerating capacity.
Wherein, gas returning port temperature generation module 00, acquisition module 10, mixture enthalpy generation module 20, refrigerating capacity generation
Module 30 and efficiency generation module 40 may be disposed in the electric-control system of air conditioner.Acquisition module 10 can monitor air conditioner in real time
Current working, the power P of compressorCompressorWith air conditioner power consumption PPower consumption.In one embodiment of the invention, acquisition module
10 can calculate the housing heat dissipation capacity Q of compressor by convection current, radiation formulaloss, specifically compressor can be generated according to below equation
Housing heat dissipation capacity Qloss:
Qloss=5.67 × 10-8×ACompressor((t2+273.15)4-(t8+273.15)4+(9.4+0.052×(t2-t8))×
ACompressor×(t2-t8),
Wherein, ACompressorFor the surface area of compressor housing, it can wait acquisition by looking into pressure contracting type number;t8Changed for outdoor
Temperature at hot device fin, i.e. outdoor environment temperature, as shown in Fig. 2 it can be by the room that is disposed in the outdoor at heat exchanger fin
The outer detection of temperature sensor 08 obtains.
Herein it should be noted that when the current working of air conditioner is cooling condition, outdoor heat exchanger makees condenser, room
External heat exchanger first end is condensator outlet, and indoor heat exchanger makees evaporator, and indoor heat exchanger first end is evaporator outlet, room
The interior end of heat exchanger second is evaporator inlet.
In one embodiment of the invention, as shown in Fig. 2 at heat exchanger fin indoor environment can be set to sense indoors
Device 09 is to detect indoor environment temperature t9, further, gas returning port temperature generation module 00 can generate return-air according to below equation
Mouth temperature t1:
t1=a*t9+b*t4+ c*f, f are compressor operating frequency, and a, b, c is fitting coefficient.
Because the refrigerant of different temperatures test point and the state of the mixture of lubricating oil are different, therefore different temperatures detects
The refrigerant enthalpy and lubricating oil enthalpy of point are different.In one embodiment of the invention, mixture enthalpy generation module 20
Rule of thumb refrigerant enthalpy and lubricating oil enthalpy can be calculated by formula.
Illustrate that rule of thumb formula obtains the refrigerant enthalpy of gas returning port to mixture enthalpy generation module 20 separately below
h1 refrigerantWith lubricating oil enthalpy h1 lubricating oil, exhaust outlet refrigerant enthalpy h2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, outdoor heat exchanger first
The refrigerant enthalpy h at end4 refrigerantsWith lubricating oil enthalpy h4 lubricating oil, indoor heat exchanger first end refrigerant enthalpy h7 refrigerantsAnd lubricating oil
Enthalpy h7 lubricating oilDetailed process.
For the refrigerant enthalpy h of gas returning port in compressor1 refrigerant, when the current working of air conditioner is cooling condition, pressure
The refrigerant superheat of the gas returning port of contracting machine, mixture enthalpy generation module 20 can combine the refrigeration that suction superheat calculates gas returning port
Agent enthalpy h1 refrigerant。
Specifically, the indoor heat exchanger in the middle part of indoor heat exchanger can be obtained by indoor heat exchanger middle portion temperature sensor 06
Middle portion temperature t6, wherein, as shown in Fig. 2 indoor heat exchanger middle portion temperature sensor 06 may be provided in the middle part of indoor heat exchanger.
Then mixture enthalpy generation module 20 can be according to gas returning port temperature t1With indoor heat exchanger middle portion temperature t6Generation is inhaled
Gas degree of superheat Δ t1, and according to suction superheat Δ t1With indoor heat exchanger middle portion temperature t6Generate gas returning port refrigerant enthalpy
Modifying factor D1, and according to indoor heat exchanger middle portion temperature t6Generate the enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation.Its
In, suction superheat Δ t1 is gas returning port temperature t1With indoor heat exchanger middle portion temperature t6Difference, i.e. Δ t1=t1-t6.Gas returning port
The modifying factor D of refrigerant enthalpy1=1+d1Δt1+d2(Δt1)2+d3(Δt1)t6+d4(Δt1)2t6+d5(Δt1)t2 6+d6(Δ
t1)2t2 6, wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.The enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation=a1+
a2t6+a3t2 6+a4t3 6+a5, wherein, a1-a5For saturation region coefficient corresponding to refrigerant.
In the modifying factor D of generation gas returning port refrigerant enthalpy1, saturation refrigerant enthalpy hAir-breathing saturationAfterwards, mixture enthalpy
Generation module 20 can be further according to the modifying factor D of gas returning port refrigerant enthalpy1, saturation refrigerant enthalpy hAir-breathing saturationGeneration
Refrigerant enthalpy h1 refrigerant, h1 refrigerant=D1·hAir-breathing saturation+d7, wherein, d7For overheated zone coefficient corresponding to refrigerant.
Similarly, for the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerants, when the current working of air conditioner is refrigeration
During operating mode, the refrigerant superheat of indoor heat exchanger first end, mixture enthalpy generation module 20 can combine the position refrigerant mistake
Temperature calculates the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerants。
Specifically, mixture enthalpy generation module 20 can be according to indoor heat exchanger first end temperature t7In indoor heat exchanger
Portion temperature t6Generate degree of superheat Δ t7, and according to degree of superheat Δ t7With indoor heat exchanger middle portion temperature t6Generate indoor heat exchanger the
The modifying factor D of one end refrigerant enthalpy7, and the modifying factor of the indoor heat exchanger first end refrigerant enthalpy according to generation
D7With the enthalpy h of saturation refrigerantAir-breathing saturationGenerate refrigerant enthalpy h7 refrigerants.Wherein, Δ t7=t7-t6,
h7 refrigerants=D7·
hAir-breathing saturation+d7, wherein, d1-d7For overheated zone coefficient corresponding to refrigerant.
For the refrigerant enthalpy h of exhaust outlet in compressor2 refrigerants, when the current working of air conditioner is cooling condition, pressure
The refrigerant superheat of the exhaust outlet of contracting machine, mixture enthalpy generation module 20 can combine the refrigeration that discharge superheat calculates exhaust outlet
Agent enthalpy h2 refrigerants。
Specifically, the outdoor heat exchanger in the middle part of outdoor heat exchanger can be obtained by outdoor heat exchanger middle portion temperature sensor 03
Middle portion temperature t3, wherein, as shown in Fig. 2 outdoor heat exchanger middle portion temperature sensor 03 may be provided in the middle part of outdoor heat exchanger.
Then, mixture enthalpy generation module 20 can be according to the exhaust port temperatures t of exhaust outlet in compressor2And outdoor heat exchange
Device middle portion temperature t3Generate discharge superheat Δ t2, and according to discharge superheat Δ t2With outdoor heat exchanger middle portion temperature t3Generation
The modifying factor D of exhaust outlet refrigerant enthalpy2, and according to outdoor heat exchanger middle portion temperature t3Generate saturation system under delivery temperature
The enthalpy h of cryogenIt is vented saturation.Wherein, discharge superheat Δ t2For the exhaust port temperatures t of exhaust outlet in compressor2And outdoor heat exchanger
Middle portion temperature t3Difference, i.e. Δ t2=t2-t3.The modifying factor D of exhaust outlet refrigerant enthalpy2=1+d1Δt2+d2(Δt2)2+d3
(Δt2)t3+d4(Δt2)2t3+d5(Δt2)t2 3+d6(Δt2)2t2 3, wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.Row
The enthalpy h of saturation refrigerant at a temperature of gasIt is vented saturation=a1+a2t3+a3t2 3+a4t3 3+a5, wherein, a1-a5To satisfy corresponding to refrigerant
With fauna number.
In the modifying factor D of generation exhaust outlet refrigerant enthalpy2, under delivery temperature saturation refrigerant enthalpy hIt is vented saturationAfterwards,
Mixture enthalpy generation module 20 can be further according to the modifying factor D of exhaust outlet refrigerant enthalpy2, saturation system under delivery temperature
The enthalpy h of cryogenIt is vented saturationGenerate the refrigerant enthalpy h of exhaust outlet2 refrigerants, h2 refrigerants=D2·hIt is vented saturation+d7, wherein, d7For refrigerant
Corresponding overheated zone coefficient.
For the refrigerant enthalpy h of outdoor heat exchanger first end4 refrigerants, when the current working of air conditioner is cooling condition,
The refrigerant supercooling of outdoor heat exchanger first end, mixture enthalpy generation module 20 can directly calculate outdoor heat exchanger first end
Refrigerant enthalpy h4 refrigerants:Wherein, c1-c4For fauna number is subcooled corresponding to refrigerant.
Saturation region coefficient, overheated zone coefficient and the species of supercooling fauna number and refrigerant have corresponding to above-mentioned refrigerant
Close, R410A refrigerants and saturation region coefficient corresponding to R32 refrigerants, overheated zone coefficient are respectively illustrated in table 1 and crosses cold-zone
Coefficient.Thus, each coefficient value can be obtained according to the species of refrigerant and the corresponding relation of such as table 1, to calculate each temperature detection
The refrigerant enthalpy of point.
In other embodiments of the invention, mixture enthalpy generation module 20 can also directly invoke the calculating knot of software
Fruit, or the refrigerant enthalpy by each temperature detecting point of other approach acquisition.For example, when the current working of air conditioner is
During cooling condition, mixture enthalpy generation module 20 can also be according to the low pressure in air conditioner, gas returning port temperature t1, interior changes
Hot device first end temperature t7Respectively obtain the refrigerant enthalpy h of gas returning port1With the refrigerant enthalpy h of indoor heat exchanger first end7,
And can be according to the high-pressure in air conditioner, exhaust port temperatures t2, outdoor heat exchanger first end temperature t4Respectively obtain exhaust outlet
Refrigerant enthalpy h2With the refrigerant enthalpy h of outdoor heat exchanger first end4。
For the lubricating oil enthalpy h of each temperature detecting pointI lubricating oil, mixture enthalpy generation module 20 can be according to following public affairs
Formula is calculated:
hI lubricating oil=-0.0808+1.7032ti+0.0025t2 i,
Wherein, i is positive integer, tiFor the temperature of temperature detecting point.Thus, the lubricating oil enthalpy of gas returning port can be calculated out
Value h1 lubricating oil, exhaust outlet lubricating oil enthalpy h2 lubricating oil, outdoor heat exchanger first end lubricating oil enthalpy h4 lubricating oilAnd indoor heat exchanger
The lubricating oil enthalpy h of first end7 lubricating oil。
Further, mixture enthalpy generation module 20 can calculate the mixture of each temperature detecting point according to below equation
Enthalpy hi:
hi=(1-Cg)hI refrigerants+CghI lubricating oil
Cg=f/104,
Wherein, CgFor mixture oil content, f is the running frequency of compressor.Thus, the mixed of gas returning port can be calculated out
Compound enthalpy h1, exhaust outlet mixture enthalpy h2, outdoor heat exchanger first end mixture enthalpy h4With indoor heat exchanger first
The mixture enthalpy h at end7。
In an embodiment of the present invention, refrigerating capacity generation module 30 can generate the refrigerating capacity of air conditioner according to below equation:Wherein, QRefrigerating capacityFor Air conditioner refrigerating capacity, PCompressorFor compressor horsepower.
Because the current working of air conditioner is cooling condition, thus efficiency generation module 40 can be according to air conditioner power consumption
With the refrigeration efficiency of refrigerating capacity generation air conditioner, specifically, the refrigeration efficiency of air conditioner is the refrigerating capacity and power consumption work(of air conditioner
The ratio between rate, i.e. EER=QRefrigerating capacity/PPower consumption。
, can also be according to operation shape of the refrigeration efficiency of air conditioner to current air conditioner after the refrigeration efficiency of generation air conditioner
State is adjusted.For example, the power of compressor can be improved when the refrigeration efficiency of air conditioner is relatively low, to improve air conditioner
Refrigerating capacity, and the energy consumption of relative reduction air conditioner, so as to save, additionally it is possible to improve the comfortableness of user.
The efficiency computing system of air conditioner according to embodiments of the present invention, the current work of air conditioner is obtained by acquisition module
Condition, the power of compressor, the housing heat dissipation capacity of air conditioner power consumption and compressor, and obtained by corresponding temperature sensor
Gas returning port in compressor, exhaust outlet, the temperature of outdoor heat exchanger first end and indoor heat exchanger first end, and at air conditioner
By mixture enthalpy generation module, refrigerating capacity generation module and efficiency generation module according to above-mentioned each position when cooling condition
The temperature put generates the refrigerant enthalpy and lubricating oil enthalpy of above-mentioned each position, and further generates the mixture of each position
Enthalpy, the housing heat dissipation capacity of power, compressor then in conjunction with compressor, the mixture enthalpy and air conditioner of above-mentioned each position
Power consumption obtains the efficiency of air conditioner, thereby, it is possible to real-time and accurately detect the efficiency of air conditioner, consequently facilitating according to sky
The running status of the real-time energy efficiency optimization air conditioner of device is adjusted, reaches energy-conservation and improves the purpose of refrigeration.
The air conditioner and its efficiency computational methods and system of above-described embodiment can detect the refrigeration efficiency of air conditioner, for inspection
The heat efficiency of air conditioner is surveyed, the present invention also proposes the efficiency computational methods of another air conditioner.
As shown in figure 4, the efficiency computational methods of another air conditioner of the embodiment of the present invention, comprise the following steps:
S401, obtain the current working of air conditioner, the power of compressor and air conditioner power consumption.
The current working of air conditioner, the power P of compressor can be monitored in real time by the electric-control system of air conditionerCompressorAnd air-conditioning
Device power consumption PPower consumption。
S402, obtain the housing heat dissipation capacity Q of compressorloss。
S403, obtain the gas returning port temperature t of gas returning port in compressor1, in compressor exhaust outlet exhaust port temperatures t2, room
The second end of indoor heat exchanger temperature t at the interior end of heat exchanger second5With the indoor heat exchanger first end temperature of indoor heat exchanger first end
Spend t7, wherein, gas returning port temperature t1According to indoor environment temperature t9With outdoor heat exchanger first end temperature t4Generation.
In one embodiment of the invention, the housing heat dissipation capacity Q of compressor can be calculated by convection current, radiation formulaloss,
The housing heat dissipation capacity Q of compressor can be specifically generated according to below equationloss:
Qloss=5.67 × 10-8×ACompressor((t2+273.15)4-(t8+273.15)4+(9.4+0.052×(t2-t8))×
ACompressor×(t2-t8),
Wherein, ACompressorFor the surface area of compressor housing, it can wait acquisition by looking into pressure contracting type number;t8Changed for outdoor
Temperature at hot device fin, i.e. outdoor environment temperature, as shown in Fig. 2 it can be by the room that is disposed in the outdoor at heat exchanger fin
Outer temperature sensor detects to obtain.
As shown in Fig. 2 can be by setting gas returning port temperature sensor at gas returning port within the compressor to detect gas returning port temperature
Spend t1, within the compressor exhaust ports exhaust port temperatures sensor is set to detect exhaust port temperatures t2, heat exchanger second indoors
Indoor heat exchanger the second end temperature sensor is set to detect the second end of indoor heat exchanger temperature t at end5Heat exchanger indoors
End sets indoor heat exchanger first end temperature sensor to detect indoor heat exchanger first end temperature t7, in outdoor heat exchanger
Outdoor heat exchanger first end temperature sensor is set to detect outdoor heat exchanger first end temperature t at first end4And indoors
Indoor temperature transmitter is set to detect indoor environment temperature t at heat exchanger fin9。
Wherein, each temperature sensor effectively contacts with the refrigerant tube wall of corresponding temperature test point, and to refrigerant
Tube wall, especially the position of temperature sensor is set to take Insulation.For example, temperature sensor can be close to copper pipe setting,
And sealing is wound to copper pipe by being incubated adhesive tape.Thereby, it is possible to improve the reliability and accuracy of temperature detection.
In one embodiment of the invention, gas returning port temperature t can be generated according to below equation1:
t1=a*t9+b*t4+ c*f, f are compressor operating frequency, and a, b, c is fitting coefficient.
S404, when the current working of air conditioner is heating condition, according to the gas returning port temperature t of gas returning port in compressor1
Generate the refrigerant enthalpy h of gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oil, according to the exhaust port temperatures t of exhaust outlet in compressor2
Generate the refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, according to the indoor heat exchanger at the end of indoor heat exchanger second
Second end temperature t5Generate the refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerantsWith lubricating oil enthalpy h5 lubricating oilChanged with according to interior
The indoor heat exchanger first end temperature t of hot device first end7Generate the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerantsAnd lubrication
Oily enthalpy h7 lubricating oil。
Herein it should be noted that when the current working of air conditioner is heating condition, outdoor heat exchanger makees evaporator, room
Interior heat exchanger makees condenser, and indoor heat exchanger first end is condenser inlet, and the end of indoor heat exchanger second is condensator outlet.
Because the refrigerant of different temperatures test point and the state of the mixture of lubricating oil are different, therefore different temperatures detects
The refrigerant enthalpy and lubricating oil enthalpy of point are different.In one embodiment of the invention, rule of thumb formula can calculate
To refrigerant enthalpy and lubricating oil enthalpy.
Illustrate that rule of thumb formula obtains the refrigerant enthalpy h of gas returning port separately below1 refrigerantWith lubricating oil enthalpy h1 lubricating oil、
The refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, the end of indoor heat exchanger second refrigerant enthalpy h5 refrigerantsAnd profit
Lubricating oil enthalpy h5 lubricating oilWith the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerantsWith lubricating oil enthalpy h7 lubricating oilDetailed process.
For the refrigerant enthalpy h of gas returning port in compressor1 refrigerant, when the current working of air conditioner is heating condition, pressure
The refrigerant superheat of the gas returning port of contracting machine, the refrigerant enthalpy h that suction superheat calculates gas returning port can be combined1 refrigerant。
Specifically, the outdoor heat exchanger middle portion temperature t in the middle part of outdoor heat exchanger can be obtained3, wherein, as shown in Fig. 2 outdoor
Outdoor heat exchanger middle portion temperature t in the middle part of heat exchanger3Temperature in the middle part of the outdoor heat exchanger that is set in the middle part of outdoor heat exchanger can be passed through
Degree sensor detects to obtain.
Then can be according to gas returning port temperature t1With outdoor heat exchanger middle portion temperature t3Generate suction superheat Δ t1, and according to
Suction superheat Δ t1With outdoor heat exchanger middle portion temperature t3Generate the modifying factor D of gas returning port refrigerant enthalpy1, and according to
Outdoor heat exchanger middle portion temperature t3Generate the enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation.Wherein, suction superheat Δ t1For
Gas returning port temperature t1With outdoor heat exchanger middle portion temperature t3Difference, i.e. Δ t1=t1-t3.The modifying factor of gas returning port refrigerant enthalpyWherein, d1-d6For refrigerant pair
The overheated zone coefficient answered.The enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation=a1+a2t3+a3t2 3+a4t3 3+a5, wherein, a1-a5
For saturation region coefficient corresponding to refrigerant.
In the modifying factor D of generation gas returning port refrigerant enthalpy1, saturation refrigerant enthalpy hAir-breathing saturationAfterwards, can further root
According to the modifying factor D of gas returning port refrigerant enthalpy1, saturation refrigerant enthalpy hAir-breathing saturationGenerate refrigerant enthalpy h1 refrigerant, h1 refrigerant
=D1·hAir-breathing saturation+d7, wherein, d7For overheated zone coefficient corresponding to refrigerant.
For the refrigerant enthalpy h of exhaust outlet in compressor2 refrigerants, when the current working of air conditioner is heating condition, pressure
The refrigerant superheat of the exhaust outlet of contracting machine, the refrigerant enthalpy h that discharge superheat calculates exhaust outlet can be combined2 refrigerants。
Specifically, the indoor heat exchanger middle portion temperature t in the middle part of indoor heat exchanger can be obtained6, wherein, as shown in Fig. 2 indoor
Indoor heat exchanger middle portion temperature t in the middle part of heat exchanger6Can be warm by the indoor heat exchanger middle part set in the middle part of heat exchanger indoors
Degree sensor detects to obtain.
Then, can be according to the exhaust port temperatures t of exhaust outlet in compressor2With indoor heat exchanger middle portion temperature t6Generation exhaust
Degree of superheat Δ t2, and the indoor heat exchanger middle portion temperature t in the middle part of indoor heat exchanger6Generate saturation refrigerant under delivery temperature
Enthalpy hIt is vented saturation, and according to discharge superheat Δ t2With indoor heat exchanger middle portion temperature t6Generate exhaust outlet refrigerant enthalpy
Modifying factor D2.Wherein, discharge superheat Δ t2For the exhaust port temperatures t of exhaust outlet in compressor2With temperature in the middle part of indoor heat exchanger
Spend t6Difference, i.e. Δ t2=t2-t6.The enthalpy h of saturation refrigerant under delivery temperatureIt is vented saturation=a1+a2t6+a3t2 6+a4t3 6+a5, its
In, a1-a5For saturation region coefficient corresponding to refrigerant.The modifying factor D of exhaust outlet refrigerant enthalpy2=1+d1Δt2+d2(Δ
t2)2+d3(Δt2)t6+d4(Δt2)2t6+d5(Δt2)t2 6+d6(Δt2)2t2 6, wherein, d1-d6For overheated zone corresponding to refrigerant
Coefficient.
In the modifying factor D of generation exhaust outlet refrigerant enthalpy2Afterwards, can further repairing according to exhaust outlet refrigerant enthalpy
Positive divisor D2, under delivery temperature saturation refrigerant enthalpy hIt is vented saturationGenerate the refrigerant enthalpy h of exhaust outlet2 refrigerants, h2 refrigerants=
D2·hIt is vented saturation+d7, wherein, d7For overheated zone coefficient corresponding to refrigerant.
Similarly, for the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerants, when the current working of air conditioner is heating
During operating mode, the refrigerant superheat of indoor heat exchanger first end, position refrigerant superheat degree can be combined and calculate indoor heat exchanger the
The refrigerant enthalpy h of one end7 refrigerants。
Specifically, can be according to indoor heat exchanger first end temperature t7With indoor heat exchanger middle portion temperature t6Generate degree of superheat Δ
t7, and according to degree of superheat Δ t7With indoor heat exchanger middle portion temperature t6Generate the amendment of indoor heat exchanger first end refrigerant enthalpy
Factor D7, and the modifying factor D of the indoor heat exchanger first end refrigerant enthalpy according to generation7With the enthalpy of saturation refrigerant
hIt is vented saturationGenerate refrigerant enthalpy h7 refrigerants.Wherein, Δ t7=t7-t6,
h7 refrigerants=D7·
hIt is vented saturation+d7, wherein, wherein, d1-d7For overheated zone coefficient corresponding to refrigerant.
For the refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerants, when the current working of air conditioner is heating condition,
The refrigerant supercooling at the end of indoor heat exchanger second, it can directly calculate the refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerants:h5 refrigerants
=c1+c2t5+c3t2 5+c4t3 5, wherein, c1-c4For fauna number is subcooled corresponding to refrigerant.
Saturation region coefficient, overheated zone coefficient and the species of supercooling fauna number and refrigerant have corresponding to above-mentioned refrigerant
Close, R410A refrigerants and saturation region coefficient corresponding to R32 refrigerants, overheated zone coefficient are respectively illustrated in table 1 and crosses cold-zone
Coefficient.Thus, each coefficient value can be obtained according to the species of refrigerant and the corresponding relation of such as table 1, to calculate each temperature detection
The refrigerant enthalpy of point.
In other embodiments of the invention, the result of calculation of software can be also directly invoked, or is obtained by other approach
The refrigerant enthalpy of each temperature detecting point.For example, can also be according to sky when the current working of air conditioner is heating condition
Adjust high-pressure, the gas returning port temperature t in device1, indoor heat exchanger first end temperature t7Respectively obtain the refrigerant enthalpy of gas returning port
h1With the refrigerant enthalpy h of indoor heat exchanger first end7, and can be according to the high-pressure in air conditioner, exhaust port temperatures t2, room
Interior the second end of heat exchanger temperature t5Respectively obtain the refrigerant enthalpy h of exhaust outlet2With the refrigerant enthalpy at the end of indoor heat exchanger second
h5。
For the lubricating oil enthalpy h of each temperature detecting pointI lubricating oil, can be calculated according to below equation:
hI lubricating oil=-0.0808+1.7032ti+0.0025t2 i,
Wherein, i is positive integer, tiFor the temperature of temperature detecting point.Thus, the lubricating oil enthalpy of gas returning port can be calculated out
Value h1 lubricating oil, exhaust outlet lubricating oil enthalpy h2 lubricating oil, the end of indoor heat exchanger second lubricating oil enthalpy h5 lubricating oilAnd indoor heat exchanger
The lubricating oil enthalpy h of first end7 lubricating oil。
S405, according to the refrigerant enthalpy h of gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oilGenerate the mixture enthalpy of gas returning port
Value h1, according to the refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oilGenerate the mixture enthalpy h of exhaust outlet2, according to
The refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerantsWith lubricating oil enthalpy h5 lubricating oilGenerate the mixture at the end of indoor heat exchanger second
Enthalpy h5With the refrigerant enthalpy h according to indoor heat exchanger first end7 refrigerantsWith lubricating oil enthalpy h7 lubricating oilGenerate indoor heat exchanger the
The mixture enthalpy h of one end7。
Specifically, the mixture enthalpy h of each temperature detecting point can be calculated according to below equationi:
hi=(1-Cg)hI refrigerants+CghI lubricating oil
Cg=f/104,
Wherein, CgFor mixture oil content, f is the running frequency of compressor.Thus, the mixed of gas returning port can be calculated out
Compound enthalpy h1, exhaust outlet mixture enthalpy h2, the end of indoor heat exchanger second mixture enthalpy h5With indoor heat exchanger first
The mixture enthalpy h at end7。
S406, according to the power of compressor, the housing heat dissipation capacity Q of compressorloss, gas returning port mixture enthalpy h1, exhaust
The mixture enthalpy h of mouth2, the end of indoor heat exchanger second mixture enthalpy h5With the mixture enthalpy of indoor heat exchanger first end
h7Generate the heating capacity of air conditioner.
Specifically, the heating capacity of air conditioner can be generated according to below equation:Wherein,
QHeating capacityFor heating capacity of air conditioner, PCompressorFor compressor horsepower.
S407, the efficiency of air conditioner is generated according to air conditioner power consumption and heating capacity.
Because the current working of air conditioner is heating condition, thus can be generated according to air conditioner power consumption and heating capacity empty
The heat efficiency of device is adjusted, specifically, the heat efficiency of air conditioner is the ratio between the heating capacity of air conditioner and power consumption, i.e. COP=
QHeating capacity/PPower consumption。
, can also be according to operation shape of the heat efficiency of air conditioner to current air conditioner after the heat efficiency of generation air conditioner
State is adjusted.For example, the power of compressor can be improved when the heat efficiency of air conditioner is relatively low, to improve air conditioner
Heating capacity, and the energy consumption of relative reduction air conditioner, so as to save, additionally it is possible to improve the comfortableness of user.
The efficiency computational methods of air conditioner according to embodiments of the present invention, by the current working, the compression that obtain air conditioner
The housing heat dissipation capacity of the power of machine, air conditioner power consumption and compressor, and obtain gas returning port in compressor, exhaust outlet, interior
The end of heat exchanger second and the temperature of indoor heat exchanger first end, and when air conditioner is in heating condition according to above-mentioned each position
The temperature put generates the refrigerant enthalpy and lubricating oil enthalpy of above-mentioned each position, and further generates the mixture of each position
Enthalpy, the housing heat dissipation capacity of power, compressor then in conjunction with compressor, the mixture enthalpy and air conditioner of above-mentioned each position
Power consumption obtains the efficiency of air conditioner, thereby, it is possible to real-time and accurately detect the efficiency of air conditioner, consequently facilitating according to sky
The running status of the real-time energy efficiency optimization air conditioner of device is adjusted, reaches energy-conservation and improves the purpose of heating effect.
Corresponding above-described embodiment, the present invention also propose another air conditioner.
The air conditioner of the embodiment of the present invention, including memory, processor and storage are on a memory and can be on a processor
The computer program of operation, during computing device computer program, it is empty that the another kind that the above embodiment of the present invention proposes can be achieved
Adjust the efficiency computational methods of device.
Air conditioner according to embodiments of the present invention, real-time and accurately efficiency can be detected.
Corresponding above-described embodiment, the present invention also propose a kind of non-transitorycomputer readable storage medium.
The non-transitorycomputer readable storage medium of the embodiment of the present invention, is stored thereon with computer program, the calculating
When machine program is executed by processor, the efficiency computational methods for another air conditioner that the above embodiment of the present invention proposes can be achieved.
Non-transitorycomputer readable storage medium according to embodiments of the present invention, by the computer journey for performing its storage
Sequence, the efficiency of air conditioner can be real-time and accurately detected, consequently facilitating optimizing air conditioner according to the real-time energy efficiency of air conditioner
Running status, reach energy-conservation and improve the purpose of heating effect.
Corresponding above-described embodiment, the present invention also propose the efficiency computing system of another air conditioner.
As shown in figure 5, the efficiency computing system of the air conditioner of the embodiment of the present invention, including exhaust port temperatures sensor 02,
The second end of indoor heat exchanger temperature sensor 05, indoor heat exchanger first end temperature sensor 07, outdoor heat exchanger first end temperature
Spend sensor 04 and gas returning port temperature generation module 00, acquisition module 10, mixture enthalpy generation module 20, heating capacity generation
Module 50, efficiency generation module 40.
Wherein, exhaust port temperatures sensor 02 is used for the exhaust port temperatures t for obtaining exhaust outlet in compressor2;Indoor heat exchange
The second end of device temperature sensor 05 is used for the second end of the indoor heat exchanger temperature t for obtaining the end of indoor heat exchanger second5;Indoor heat exchange
Device first end temperature sensor 07 is used for the indoor heat exchanger first end temperature t for obtaining indoor heat exchanger first end7;Outdoor heat exchange
Device first end temperature sensor 04 is used for the outdoor heat exchanger first end temperature t for obtaining outdoor heat exchanger first end4。
The air conditioner of the embodiment of the present invention can be single-stage vapor compression formula air conditioner, as shown in Fig. 2 the embodiment of the present invention
Air conditioner may include compressor 100, four-way valve 200, outdoor heat exchanger 300, restricting element 400 and indoor heat exchanger 500.
As shown in Fig. 2 gas returning port temperature sensor 01 can be set within the compressor at gas returning port, exhaust port temperatures sensor
02 settable exhaust ports, the second end of indoor heat exchanger temperature sensor 05 may be provided at indoor heat exchanger second within the compressor
End, indoor heat exchanger first end temperature sensor 07 may be provided at indoor heat exchanger first end, outdoor heat exchanger first end temperature
Sensor 04 may be provided at outdoor heat exchanger first end.Wherein, refrigeration of each temperature sensor with corresponding temperature test point
Agent tube wall effectively contacts, and to refrigerant tube wall, especially sets the position of temperature sensor to take Insulation.For example, can
Temperature sensor is close into copper pipe to set, and sealing is wound to copper pipe by being incubated adhesive tape.Thereby, it is possible to improve temperature inspection
The reliability and accuracy of survey.
Gas returning port temperature generation module 00 is used for according to indoor environment temperature t9With outdoor heat exchanger first end temperature t4Generation
Gas returning port temperature t1;Acquisition module 10 be used for obtain the current working of air conditioner, the power of compressor, air conditioner power consumption with
And the housing heat dissipation capacity Q of compressorloss;Mixture enthalpy generation module 20 is used for when the current working of air conditioner is heating condition
When, according to the gas returning port temperature t of gas returning port in the compressor1Generate the refrigerant enthalpy h of gas returning port1 refrigerantWith lubricating oil enthalpy
h1 lubricating oil, according to the exhaust port temperatures t of exhaust outlet in the compressor2Generate the refrigerant enthalpy h of exhaust outlet2 refrigerantsAnd lubricating oil
Enthalpy h2 lubricating oil, according to the second end of indoor heat exchanger temperature t at the end of indoor heat exchanger second5Generate the end of indoor heat exchanger second
Refrigerant enthalpy h5 refrigerantsWith lubricating oil enthalpy h5 lubricating oilWith the indoor heat exchanger first end according to the indoor heat exchanger first end
Temperature t7Generate the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerantsWith lubricating oil enthalpy h7 lubricating oil, and according to the return-air
The refrigerant enthalpy h of mouth1 refrigerantWith lubricating oil enthalpy h1 lubricating oilGenerate the mixture enthalpy h of gas returning port1, according to the exhaust outlet
Refrigerant enthalpy h2 refrigerantsWith lubricating oil enthalpy h2 lubricating oilGenerate the mixture enthalpy h of exhaust outlet2, according to the indoor heat exchanger
The refrigerant enthalpy h at two ends5 refrigerantsWith lubricating oil enthalpy h5 lubricating oilGenerate the mixture enthalpy h at the end of indoor heat exchanger second5And basis
The refrigerant enthalpy h of the indoor heat exchanger first end7 refrigerantsWith lubricating oil enthalpy h7 lubricating oilGenerate the mixed of indoor heat exchanger first end
Compound enthalpy h7;Heating capacity generation module 50 is used for power, the housing heat dissipation capacity Q of compressor according to compressorloss, gas returning port
Mixture enthalpy h1, exhaust outlet mixture enthalpy h2, the end of indoor heat exchanger second mixture enthalpy h5And indoor heat exchanger
The mixture enthalpy h of first end7Generate the heating capacity of air conditioner;Efficiency generation module 40 be used for according to air conditioner power consumption and
Heating capacity generates the efficiency of air conditioner.
Wherein, gas returning port temperature generation module 00, acquisition module 10, mixture enthalpy generation module 20, heating capacity generation
Module 50 and efficiency generation module 40 may be disposed in the electric-control system of air conditioner.Acquisition module 10 can monitor air conditioner in real time
Current working, the power P of compressorCompressorWith air conditioner power consumption PPower consumption.In one embodiment of the invention, acquisition module
10 can calculate the housing heat dissipation capacity Q of compressor by convection current, radiation formulaloss, specifically compressor can be generated according to below equation
Housing heat dissipation capacity Qloss:
Qloss=5.67 × 10-8×ACompressor((t2+273.15)4-(t8+273.15)4+(9.4+0.052×(t2-t8))×
ACompressor×(t2-t8),
Wherein, ACompressorFor the surface area of compressor housing, it can wait acquisition by looking into pressure contracting type number;t8Changed for outdoor
Temperature at hot device fin, i.e. outdoor environment temperature, as shown in Fig. 2 it can be by the room that is disposed in the outdoor at heat exchanger fin
The outer detection of temperature sensor 08 obtains.
Herein it should be noted that when the current working of air conditioner is heating condition, outdoor heat exchanger makees evaporator, room
Interior heat exchanger makees condenser, and indoor heat exchanger first end is condenser inlet, and the end of indoor heat exchanger second is condensator outlet.
In one embodiment of the invention, as shown in Fig. 2 at heat exchanger fin indoor environment can be set to sense indoors
Device 09 is to detect indoor environment temperature t9, further, gas returning port temperature generation module 00 can generate return-air according to below equation
Mouth temperature t1:
t1=a*t9+b*t4+ c*f, f are compressor operating frequency, and a, b, c is fitting coefficient.
Because the refrigerant of different temperatures test point and the state of the mixture of lubricating oil are different, therefore different temperatures detects
The refrigerant enthalpy and lubricating oil enthalpy of point are different.In one embodiment of the invention, mixture enthalpy generation module 20
Rule of thumb refrigerant enthalpy and lubricating oil enthalpy can be calculated by formula.
Illustrate that rule of thumb formula obtains the refrigerant enthalpy of gas returning port to mixture enthalpy generation module 20 separately below
h1 refrigerantWith lubricating oil enthalpy h1 lubricating oil, exhaust outlet refrigerant enthalpy h2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, indoor heat exchanger second
The refrigerant enthalpy h at end5 refrigerantsWith lubricating oil enthalpy h5 lubricating oilWith the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerantsAnd lubrication
Oily enthalpy h7 lubricating oilDetailed process.
For the refrigerant enthalpy h of gas returning port in compressor1 refrigerant, when the current working of air conditioner is heating condition, pressure
The refrigerant superheat of the gas returning port of contracting machine, mixture enthalpy generation module 20 can combine the refrigeration that suction superheat calculates gas returning port
Agent enthalpy h1 refrigerant。
Specifically, mixture enthalpy generation module 20 can obtain the outdoor heat exchanger middle portion temperature in the middle part of outdoor heat exchanger
t3, wherein, as shown in Fig. 2 the outdoor heat exchanger middle portion temperature t in the middle part of outdoor heat exchanger3Can be by being set in the middle part of outdoor heat exchanger
The outdoor heat exchanger middle portion temperature sensor put detects to obtain.
Then mixture enthalpy generation module 20 can be according to gas returning port temperature t1With outdoor heat exchanger middle portion temperature t3Generation is inhaled
Gas degree of superheat Δ t1, and according to suction superheat Δ t1With outdoor heat exchanger middle portion temperature t3Generate gas returning port refrigerant enthalpy
Modifying factor D1, and according to outdoor heat exchanger middle portion temperature t3Generate the enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation.Its
In, suction superheat Δ t1For gas returning port temperature t1With outdoor heat exchanger middle portion temperature t3Difference, i.e. Δ t1=t1-t3.Gas returning port
The modifying factor of refrigerant enthalpy
Wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.The enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation=a1+a2t3+
a3t2 3+a4t3 3+a5, wherein, a1-a5For saturation region coefficient corresponding to refrigerant.
In the modifying factor D of generation gas returning port refrigerant enthalpy1, saturation refrigerant enthalpy hAir-breathing saturationAfterwards, mixture enthalpy
Generation module 20 can be further according to the modifying factor D of gas returning port refrigerant enthalpy1, saturation refrigerant enthalpy hAir-breathing saturationGeneration
Refrigerant enthalpy h1 refrigerant, h1 refrigerant=D1·hAir-breathing saturation+d7, wherein, d7For overheated zone coefficient corresponding to refrigerant.
For the refrigerant enthalpy h of exhaust outlet in compressor2 refrigerants, when the current working of air conditioner is heating condition, pressure
The refrigerant superheat of the exhaust outlet of contracting machine, mixture enthalpy generation module 20 can combine the refrigeration that discharge superheat calculates exhaust outlet
Agent enthalpy h2 refrigerants。
Specifically, mixture enthalpy generation module 20 can obtain the indoor heat exchanger middle portion temperature in the middle part of indoor heat exchanger
t6, wherein, as shown in Fig. 2 the indoor heat exchanger middle portion temperature t in the middle part of indoor heat exchanger6Can be by being set in the middle part of heat exchanger indoors
The indoor heat exchanger middle portion temperature sensor put detects to obtain.
Then, mixture enthalpy generation module 20 can be according to the exhaust port temperatures t of exhaust outlet in compressor2With indoor heat exchange
Device middle portion temperature t6Generate discharge superheat Δ t2, and the indoor heat exchanger middle portion temperature t in the middle part of indoor heat exchanger6Generation
The enthalpy h of saturation refrigerant under delivery temperatureIt is vented saturation, and according to discharge superheat Δ t2With indoor heat exchanger middle portion temperature t6It is raw
Into the modifying factor D of exhaust outlet refrigerant enthalpy value2.Wherein, discharge superheat Δ t2For the exhaust port temperatures of exhaust outlet in compressor
t2With indoor heat exchanger middle portion temperature t6Difference, i.e. Δ t2=t2-t6.The enthalpy h of saturation refrigerant under delivery temperatureIt is vented saturation=a1+
a2t6+a3t2 6+a4t3 6+a5, wherein, a1-a5For saturation region coefficient corresponding to refrigerant.The modifying factor of exhaust outlet refrigerant enthalpy
D2=1+d1Δt2+d2(Δt2)2+d3(Δt2)t6+d4(Δt2)2t6+d5(Δt2)t2 6+d6(Δt2)2t2 6, wherein, d1-d6For system
Overheated zone coefficient corresponding to cryogen.
In the modifying factor D of generation exhaust outlet refrigerant enthalpy2Afterwards, mixture enthalpy generation module 20 can further basis
The modifying factor D of exhaust outlet refrigerant enthalpy2, under delivery temperature saturation refrigerant enthalpy hIt is vented saturationGenerate the refrigeration of exhaust outlet
Agent enthalpy h2 refrigerants, h2 refrigerants=D2·hIt is vented saturation+d7, wherein, d7For overheated zone coefficient corresponding to refrigerant.
Similarly, for the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerants, when the current working of air conditioner is heating
During operating mode, the refrigerant superheat of indoor heat exchanger first end, mixture enthalpy generation module 20 can combine the position refrigerant mistake
Temperature calculates the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerants。
Specifically, mixture enthalpy generation module 20 can be according to indoor heat exchanger first end temperature t7In indoor heat exchanger
Portion temperature t6Generate degree of superheat Δ t7, and according to degree of superheat Δ t7With indoor heat exchanger middle portion temperature t6Generate indoor heat exchanger the
The modifying factor D of one end refrigerant enthalpy7, and the modifying factor of the indoor heat exchanger first end refrigerant enthalpy according to generation
D7With the enthalpy h of saturation refrigerantIt is vented saturationGenerate refrigerant enthalpy h7 refrigerants.Wherein, Δ t7=t7-t6,h7 refrigerants=D7·hIt is vented saturation+d7,
Wherein, wherein, d1-d7For overheated zone coefficient corresponding to refrigerant.
For the refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerants, when the current working of air conditioner is heating condition,
The refrigerant supercooling at the end of indoor heat exchanger second, mixture enthalpy generation module 20 can directly calculate the end of indoor heat exchanger second
Refrigerant enthalpy h5 refrigerants:h5 refrigerants=c1+c2t5+c3t2 5+c4t3 5, wherein, c1-c4For fauna number is subcooled corresponding to refrigerant.
Saturation region coefficient, overheated zone coefficient and the species of supercooling fauna number and refrigerant have corresponding to above-mentioned refrigerant
Close, R410A refrigerants and saturation region coefficient corresponding to R32 refrigerants, overheated zone coefficient are respectively illustrated in table 1 and crosses cold-zone
Coefficient.Thus, each coefficient value can be obtained according to the species of refrigerant and the corresponding relation of such as table 1, to calculate each temperature detection
The refrigerant enthalpy of point.
In other embodiments of the invention, mixture enthalpy generation module 20 can also directly invoke the calculating knot of software
Fruit, or the refrigerant enthalpy by each temperature detecting point of other approach acquisition.For example, when the current working of air conditioner is
During heating condition, mixture enthalpy generation module 20 can also be according to the high-pressure in air conditioner, gas returning port temperature t1, interior changes
Hot device first end temperature t7Respectively obtain the refrigerant enthalpy h of gas returning port1With the refrigerant enthalpy h of indoor heat exchanger first end7,
And can be according to the high-pressure in air conditioner, exhaust port temperatures t2, the second end of indoor heat exchanger temperature t5Respectively obtain exhaust outlet
Refrigerant enthalpy h2With the refrigerant enthalpy h at the end of indoor heat exchanger second5。
For the lubricating oil enthalpy h of each temperature detecting pointI lubricating oil, mixture enthalpy generation module 20 can be according to following public affairs
Formula is calculated:
hI lubricating oil=-0.0808+1.7032ti+0.0025t2 i,
Wherein, i is positive integer, tiFor the temperature of temperature detecting point.Thus, the lubricating oil enthalpy of gas returning port can be calculated out
Value h1 lubricating oil, exhaust outlet lubricating oil enthalpy h2 lubricating oil, the end of indoor heat exchanger second lubricating oil enthalpy h5 lubricating oilAnd indoor heat exchanger
The lubricating oil enthalpy h of first end7 lubricating oil。
Further, mixture enthalpy generation module 20 can calculate the mixture of each temperature detecting point according to below equation
Enthalpy hi:
hi=(1-Cg)hI refrigerants+CghI lubricating oil
Cg=f/104,
Wherein, CgFor mixture oil content, f is the running frequency of compressor.Thus, the mixed of gas returning port can be calculated out
Compound enthalpy h1, exhaust outlet mixture enthalpy h2, the end of indoor heat exchanger second mixture enthalpy h5With indoor heat exchanger first
The mixture enthalpy h at end7。
In an embodiment of the present invention, heating capacity generation module 50 can generate the heating capacity of air conditioner according to below equation:Wherein, QHeating capacityFor heating capacity of air conditioner, PCompressorFor compressor horsepower.
Because the current working of air conditioner is heating condition, thus efficiency generation module 40 can be according to air conditioner power consumption
With the heat efficiency of heating capacity generation air conditioner, specifically, the heat efficiency of air conditioner is the heating capacity and power consumption work(of air conditioner
The ratio between rate, i.e. COP=QHeating capacity/PPower consumption。
, can also be according to operation shape of the heat efficiency of air conditioner to current air conditioner after the heat efficiency of generation air conditioner
State is adjusted.For example, the power of compressor can be improved when the heat efficiency of air conditioner is relatively low, to improve air conditioner
Heating capacity, and the energy consumption of relative reduction air conditioner, so as to save, additionally it is possible to improve the comfortableness of user.
The efficiency computing system of air conditioner according to embodiments of the present invention, the current work of air conditioner is obtained by acquisition module
Condition, the power of compressor, the housing heat dissipation capacity of air conditioner power consumption and compressor, and obtained by corresponding temperature sensor
Gas returning port in compressor, exhaust outlet, the temperature of the end of indoor heat exchanger second and indoor heat exchanger first end, and at air conditioner
By mixture enthalpy generation module, heating capacity generation module and efficiency generation module according to above-mentioned each position when heating condition
The temperature put generates the refrigerant enthalpy and lubricating oil enthalpy of above-mentioned each position, and further generates the mixture of each position
Enthalpy, the housing heat dissipation capacity of power, compressor then in conjunction with compressor, the refrigerant enthalpy and air conditioner of above-mentioned each position
Power consumption obtains the efficiency of air conditioner, thereby, it is possible to real-time and accurately detect the efficiency of air conditioner, consequently facilitating according to sky
The running status of the real-time energy efficiency optimization air conditioner of device is adjusted, reaches energy-conservation and improves the purpose of heating effect.
In summary, the air conditioner of the embodiment of the present invention and its efficiency computational methods and system, by obtaining air conditioner system
The physical property of refrigerant and the physical property of lubricating oil in refrigerant cycle system, and combine the mixture of refrigerant and lubricating oil
Physical property and the leakage enthusiasm condition of compressor the power of air conditioner is calculated, and the energy of air conditioner is further calculated
Effect, so as to be able to real-time and accurately detect the refrigeration efficiency and heat efficiency of air conditioner.
In the description of the invention, it is to be understood that term " " center ", " longitudinal direction ", " transverse direction ", " length ", " width ",
" thickness ", " on ", " under ", "front", "rear", "left", "right", " vertical ", " level ", " top ", " bottom ", " interior ", " outer ", " up time
The orientation or position relationship of the instruction such as pin ", " counterclockwise ", " axial direction ", " radial direction ", " circumference " be based on orientation shown in the drawings or
Position relationship, it is for only for ease of and describes the present invention and simplify description, rather than indicates or imply that signified device or element must
There must be specific orientation, with specific azimuth configuration and operation, therefore be not considered as limiting the invention.
In addition, term " first ", " second " are only used for describing purpose, and it is not intended that instruction or hint relative importance
Or the implicit quantity for indicating indicated technical characteristic.Thus, define " first ", the feature of " second " can be expressed or
Implicitly include one or more this feature.In the description of the invention, " multiple " are meant that two or more,
Unless otherwise specifically defined.
In the present invention, unless otherwise clearly defined and limited, term " installation ", " connected ", " connection ", " fixation " etc.
Term should be interpreted broadly, for example, it may be fixedly connected or be detachably connected, or integrally;Can be that machinery connects
Connect or electrically connect;Can be joined directly together, can also be indirectly connected by intermediary, can be in two elements
The connection in portion or the interaction relationship of two elements.For the ordinary skill in the art, can be according to specific feelings
Condition understands the concrete meaning of above-mentioned term in the present invention.
In the present invention, unless otherwise clearly defined and limited, fisrt feature can be with "above" or "below" second feature
It is that the first and second features directly contact, or the first and second features pass through intermediary mediate contact.Moreover, fisrt feature exists
Second feature " on ", " top " and " above " but fisrt feature are directly over second feature or oblique upper, or be merely representative of
Fisrt feature level height is higher than second feature.Fisrt feature second feature " under ", " lower section " and " below " can be
One feature is immediately below second feature or obliquely downward, or is merely representative of fisrt feature level height and is less than second feature.
In the description of this specification, reference term " one embodiment ", " some embodiments ", " example ", " specifically show
The description of example " or " some examples " etc. means specific features, structure, material or the spy for combining the embodiment or example description
Point is contained at least one embodiment or example of the present invention.In this manual, to the schematic representation of above-mentioned term not
Identical embodiment or example must be directed to.Moreover, specific features, structure, material or the feature of description can be with office
Combined in an appropriate manner in one or more embodiments or example.In addition, in the case of not conflicting, the skill of this area
Art personnel can be tied the different embodiments or example and the feature of different embodiments or example described in this specification
Close and combine.
Although embodiments of the invention have been shown and described above, it is to be understood that above-described embodiment is example
Property, it is impossible to limitation of the present invention is interpreted as, one of ordinary skill in the art within the scope of the invention can be to above-mentioned
Embodiment is changed, changed, replacing and modification.
Claims (32)
1. the efficiency computational methods of a kind of air conditioner, it is characterised in that comprise the following steps:
Obtain current working, the power and air conditioner power consumption of compressor of air conditioner;
Obtain the housing heat dissipation capacity Q of compressorloss;
Obtain the gas returning port temperature t of gas returning port in compressor1, in the compressor exhaust outlet exhaust port temperatures t2, outdoor heat exchange
The outdoor heat exchanger first end temperature t of device first end4With the indoor heat exchanger first end temperature t of indoor heat exchanger first end7, its
In, the gas returning port temperature t1According to indoor environment temperature t9With the outdoor heat exchanger first end temperature t4Generation;
When the current working of the air conditioner is cooling condition, according to the gas returning port temperature t of gas returning port in the compressor1It is raw
Into the refrigerant enthalpy h of gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oil, according to the exhaust port temperatures of exhaust outlet in the compressor
t2Generate the refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, according to the outdoor of the outdoor heat exchanger first end
Heat exchanger first end temperature t4Generate the refrigerant enthalpy h of outdoor heat exchanger first end4 refrigerantsWith lubricating oil enthalpy h4 lubricating oilAnd basis
The indoor heat exchanger first end temperature t of the indoor heat exchanger first end7Generate the refrigerant enthalpy of indoor heat exchanger first end
h7 refrigerantsWith lubricating oil enthalpy h7 lubricating oil;
According to the refrigerant enthalpy h of the gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oilGenerate the mixture enthalpy h of gas returning port1,
According to the refrigerant enthalpy h of the exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oilGenerate the mixture enthalpy h of exhaust outlet2, according to
The refrigerant enthalpy h of the outdoor heat exchanger first end4 refrigerantsWith lubricating oil enthalpy h4 lubricating oilGenerate the mixed of outdoor heat exchanger first end
Compound enthalpy h4With the refrigerant enthalpy h according to the indoor heat exchanger first end7 refrigerantsWith lubricating oil enthalpy h7 lubricating oilGeneration is indoor
The mixture enthalpy h of heat exchanger first end7;
According to the power of the compressor, the housing heat dissipation capacity Q of the compressorloss, the gas returning port mixture enthalpy h1、
The mixture enthalpy h of the exhaust outlet2, the outdoor heat exchanger first end mixture enthalpy h4With the indoor heat exchanger
The mixture enthalpy h of one end7Generate the refrigerating capacity of air conditioner;And
The efficiency of the air conditioner is generated according to the air conditioner power consumption and the refrigerating capacity.
2. the efficiency computational methods of air conditioner as claimed in claim 1, it is characterised in that according to gas returning port in the compressor
Gas returning port temperature t1Generate the refrigerant enthalpy h of gas returning port1 refrigerantSpecifically include:
Obtain the indoor heat exchanger middle portion temperature t in the middle part of indoor heat exchanger6;
According to the gas returning port temperature t1With the indoor heat exchanger middle portion temperature t6Generate suction superheat Δ t1;
According to the suction superheat Δ t1With the indoor heat exchanger middle portion temperature t6Generate the amendment of gas returning port refrigerant enthalpy
Factor D1;
According to the indoor heat exchanger middle portion temperature t6Generate the enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation;
According to the modifying factor D of the gas returning port refrigerant enthalpy1, the saturation refrigerant enthalpy hAir-breathing saturationGenerate the refrigeration
Agent enthalpy h1 refrigerant。
3. the efficiency computational methods of air conditioner as claimed in claim 2, it is characterised in that the suction is generated according to below equation
The enthalpy h of saturation refrigerant at a temperature of gasAir-breathing saturation:
hAir-breathing saturation=a1+a2t6+a3t2 6+a4t3 6+a5, wherein, a1-a5For saturation region coefficient corresponding to refrigerant.
4. the efficiency computational methods of air conditioner as claimed in claim 2, it is characterised in that returned according to below equation generation
The modifying factor D of gas port refrigerant enthalpy1:
D1=1+d1Δt1+d2(Δt1)2+d3(Δt1)t6+d4(Δt1)2t6+d5(Δt1)t2 6+d6(Δt1)2t2 6,
Wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.
5. the efficiency computational methods of air conditioner as claimed in claim 3, it is characterised in that according to the indoor heat exchanger first
The indoor heat exchanger first end temperature t at end7Generate the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerantsSpecifically include:
According to the indoor heat exchanger first end temperature t7With the indoor heat exchanger middle portion temperature t6Generate degree of superheat Δ t7;
According to the degree of superheat Δ t7With the indoor heat exchanger middle portion temperature t6Generate indoor heat exchanger first end refrigerant enthalpy
Modifying factor D7;
According to the modifying factor D of the indoor heat exchanger first end refrigerant enthalpy7With the enthalpy h of the saturation refrigerantAir-breathing saturation
Generate the refrigerant enthalpy h7 refrigerants。
6. the efficiency computational methods of air conditioner as claimed in claim 5, it is characterised in that the room is generated according to below equation
The modifying factor D of interior heat exchanger first end refrigerant enthalpy7:
<mrow>
<msub>
<mi>D</mi>
<mn>7</mn>
</msub>
<mo>=</mo>
<mn>1</mn>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>1</mn>
</msub>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>2</mn>
</msub>
<msup>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<mn>2</mn>
</msup>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>3</mn>
</msub>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<msub>
<mi>t</mi>
<mn>6</mn>
</msub>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>4</mn>
</msub>
<msup>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<mn>2</mn>
</msup>
<msub>
<mi>t</mi>
<mn>6</mn>
</msub>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>5</mn>
</msub>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<msubsup>
<mi>t</mi>
<mn>6</mn>
<mn>2</mn>
</msubsup>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>6</mn>
</msub>
<msup>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<mn>2</mn>
</msup>
<msubsup>
<mi>t</mi>
<mn>6</mn>
<mn>2</mn>
</msubsup>
<mo>,</mo>
</mrow>
Wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.
7. the efficiency computational methods of air conditioner as claimed in claim 1, it is characterised in that according to exhaust outlet in the compressor
Exhaust port temperatures t2Generate the refrigerant enthalpy h of exhaust outlet2 refrigerantsSpecifically include:
Obtain the outdoor heat exchanger middle portion temperature t in the middle part of outdoor heat exchanger3;
According to the exhaust port temperatures t of exhaust outlet in the compressor2With the outdoor heat exchanger middle portion temperature t3Generate discharge superheat
Spend Δ t2;
According to the discharge superheat Δ t2With the outdoor heat exchanger middle portion temperature t3Generate the amendment of exhaust outlet refrigerant enthalpy
Factor D2;
According to the outdoor heat exchanger middle portion temperature t3Generate the enthalpy h of saturation refrigerant under delivery temperatureIt is vented saturation;
According to the modifying factor D of the exhaust outlet refrigerant enthalpy2, under the delivery temperature saturation refrigerant enthalpy hIt is vented saturationIt is raw
Into the refrigerant enthalpy h of the exhaust outlet2 refrigerants。
8. the efficiency computational methods of air conditioner as claimed in claim 7, it is characterised in that the row is generated according to below equation
The modifying factor D of gas port refrigerant enthalpy2:
D2=1+d1Δt2+d2(Δt2)2+d3(Δt2)t3+d4(Δt2)2t3+d5(Δt2)t2 3+d6(Δt2)2t2 3,
Wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.
9. the efficiency computational methods of air conditioner as claimed in claim 1, it is characterised in that the room is generated according to below equation
The refrigerant enthalpy h of external heat exchanger first end4 refrigerants:
Wherein, c1-c4For fauna number is subcooled corresponding to refrigerant.
10. the efficiency computational methods of air conditioner as claimed in claim 1, it is characterised in that air-conditioning is generated according to below equation
The refrigerating capacity of device:
Wherein, QRefrigerating capacityFor the Air conditioner refrigerating capacity, PCompressorFor the work(of the compressor
Rate.
11. the efficiency computational methods of air conditioner as claimed in claim 1, it is characterised in that calculated according to below equation each
The lubricating oil enthalpy h of temperature detecting pointI lubricating oil, wherein, i is positive integer,
hI lubricating oil=-0.0808+1.7032ti+0.0025t2 i,
Wherein, tiFor the temperature of temperature detecting point.
12. the efficiency computational methods of air conditioner as claimed in claim 1, it is characterised in that calculated according to below equation each
The mixture enthalpy h of temperature detecting pointi, wherein, i is positive integer,
hi=(1-Cg)hI refrigerants+CghI lubricating oil
Cg=f/104,
Wherein, CgFor mixture oil content, f is the running frequency of the compressor.
13. the efficiency computational methods of air conditioner as claimed in claim 1, it is characterised in that according to generating below equation
The housing heat dissipation capacity Q of compressorloss:
Qloss=5.67 × 10-8×ACompressor((t2+273.15)4-(t8+273.15)4+(9.4+0.052×(t2-t8))×ACompressor
×(t2-t8),
Wherein, ACompressorFor the surface area of compressor housing, t8For the temperature at outdoor heat exchanger fin.
14. the efficiency computational methods of air conditioner as claimed in claim 1, it is characterised in that according to generating below equation
Gas returning port temperature t1:
t1=a*t9+b*t4+ c*f, f are the running frequency of the compressor, and a, b, c is fitting coefficient.
15. a kind of air conditioner, it is characterised in that including memory, processor and be stored on the memory and can be described
The computer program run on processor, described in the computing device during computer program, realize as in claim 1-14
The efficiency computational methods of any described air conditioner.
16. a kind of non-transitorycomputer readable storage medium, is stored thereon with computer program, it is characterised in that the meter
The efficiency computational methods of the air conditioner as described in any in claim 1-14 are realized when calculation machine program is executed by processor.
17. the efficiency computational methods of a kind of air conditioner, it is characterised in that comprise the following steps:
Obtain current working, the power and air conditioner power consumption of compressor of air conditioner;
Obtain the housing heat dissipation capacity Q of compressorloss;
Obtain the gas returning port temperature t of gas returning port in compressor1, in the compressor exhaust outlet exhaust port temperatures t2, indoor heat exchange
The second end of indoor heat exchanger temperature t at the end of device second5With the indoor heat exchanger first end temperature t of indoor heat exchanger first end7, its
In, the gas returning port temperature t1According to indoor environment temperature t9With outdoor heat exchanger first end temperature t4Generation;
When the current working of the air conditioner is heating condition, according to the gas returning port temperature t of gas returning port in the compressor1It is raw
Into the refrigerant enthalpy h of gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oil, according to the exhaust port temperatures of exhaust outlet in the compressor
t2Generate the refrigerant enthalpy h of exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oil, according to the interior at the end of indoor heat exchanger second
The second end of heat exchanger temperature t5Generate the refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerantsWith lubricating oil enthalpy h5 lubricating oilAnd basis
The indoor heat exchanger first end temperature t of the indoor heat exchanger first end7Generate the refrigerant enthalpy of indoor heat exchanger first end
h7 refrigerantsWith lubricating oil enthalpy h7 lubricating oil;
According to the refrigerant enthalpy h of the gas returning port1 refrigerantWith lubricating oil enthalpy h1 lubricating oilGenerate the mixture enthalpy h of gas returning port1,
According to the refrigerant enthalpy h of the exhaust outlet2 refrigerantsWith lubricating oil enthalpy h2 lubricating oilGenerate the mixture enthalpy h of exhaust outlet2, according to
The refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerantsWith lubricating oil enthalpy h5 lubricating oilGenerate the mixed of the end of indoor heat exchanger second
Compound enthalpy h5With the refrigerant enthalpy h according to the indoor heat exchanger first end7 refrigerantsWith lubricating oil enthalpy h7 lubricating oilGeneration is indoor
The mixture enthalpy h of heat exchanger first end7;
According to the power of the compressor, the housing heat dissipation capacity Q of the compressorloss, the gas returning port mixture enthalpy h1、
The mixture enthalpy h of exhaust outlet2, the end of indoor heat exchanger second mixture enthalpy h5With the mixture of indoor heat exchanger first end
Enthalpy h7Generate the heating capacity of air conditioner;And
The efficiency of the air conditioner is generated according to the air conditioner power consumption and the heating capacity.
18. the efficiency computational methods of air conditioner as claimed in claim 17, it is characterised in that described according in the compressor
The gas returning port temperature t of gas returning port1Generate the refrigerant enthalpy h of gas returning port1 refrigerantSpecifically include:
Obtain the outdoor heat exchanger middle portion temperature t in the middle part of outdoor heat exchanger3;
According to the gas returning port temperature t1With the outdoor heat exchanger middle portion temperature t3Generate suction superheat Δ t1;
According to the suction superheat Δ t1With the outdoor heat exchanger middle portion temperature t3Generate the amendment of gas returning port refrigerant enthalpy
Factor D1;
According to the outdoor heat exchanger middle portion temperature t3Generate the enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation;
According to the modifying factor D of the gas returning port refrigerant enthalpy1, under the suction temperature saturation refrigerant enthalpy hAir-breathing saturationIt is raw
Into the refrigerant enthalpy h of the gas returning port1 refrigerant。
19. the efficiency computational methods of air conditioner as claimed in claim 18, it is characterised in that according to generating below equation
The enthalpy h of saturation refrigerant under suction temperatureAir-breathing saturation:
Wherein, a1-a5For saturation region coefficient corresponding to refrigerant.
20. the efficiency computational methods of air conditioner as claimed in claim 18, it is characterised in that according to generating below equation
The modifying factor D of gas returning port refrigerant enthalpy1:
<mrow>
<msub>
<mi>D</mi>
<mn>1</mn>
</msub>
<mo>=</mo>
<mn>1</mn>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>1</mn>
</msub>
<msub>
<mi>&Delta;t</mi>
<mn>1</mn>
</msub>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>2</mn>
</msub>
<msup>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>1</mn>
</msub>
<mo>)</mo>
</mrow>
<mn>2</mn>
</msup>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>3</mn>
</msub>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>1</mn>
</msub>
<mo>)</mo>
</mrow>
<msub>
<mi>t</mi>
<mn>3</mn>
</msub>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>4</mn>
</msub>
<msup>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>1</mn>
</msub>
<mo>)</mo>
</mrow>
<mn>2</mn>
</msup>
<msub>
<mi>t</mi>
<mn>3</mn>
</msub>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>5</mn>
</msub>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>1</mn>
</msub>
<mo>)</mo>
</mrow>
<msubsup>
<mi>t</mi>
<mn>3</mn>
<mn>2</mn>
</msubsup>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>6</mn>
</msub>
<msup>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>1</mn>
</msub>
<mo>)</mo>
</mrow>
<mn>2</mn>
</msup>
<msubsup>
<mi>t</mi>
<mn>3</mn>
<mn>2</mn>
</msubsup>
<mo>,</mo>
</mrow>
Wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.
21. the efficiency computational methods of air conditioner as claimed in claim 18, it is characterised in that be vented according in the compressor
The exhaust port temperatures t of mouth2Generate the refrigerant enthalpy h of exhaust outlet2 refrigerantsSpecifically include:
Obtain the indoor heat exchanger middle portion temperature t in the middle part of indoor heat exchanger6;
According to the indoor heat exchanger middle portion temperature t in the middle part of the indoor heat exchanger6With the exhaust outlet temperature of exhaust outlet in the compressor
Spend t2Generate discharge superheat Δ t2;
According to the discharge superheat Δ t2With the indoor heat exchanger middle portion temperature t6Generate the amendment of exhaust outlet refrigerant enthalpy
Factor D2;
According to the indoor heat exchanger middle portion temperature t in the middle part of the indoor heat exchanger6Generate the enthalpy of saturation refrigerant under delivery temperature
hIt is vented saturation;
According to the modifying factor D of the exhaust outlet refrigerant enthalpy2, under the delivery temperature saturation refrigerant enthalpy hIt is vented saturationIt is raw
Into the refrigerant enthalpy h of the exhaust outlet2 refrigerants。
22. the efficiency computational methods of the air conditioner described in claim 21, it is characterised in that the row is generated according to below equation
The modifying factor D of gas port refrigerant enthalpy2:
D2=1+d1Δt2+d2(Δt2)2+d3(Δt2)t6+d4(Δt2)2t6+d5(Δt2)t2 6+d6(Δt2)2t2 6,
Wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.
23. the efficiency computational methods of air conditioner as claimed in claim 21, it is characterised in that according to the indoor heat exchanger
The indoor heat exchanger first end temperature t of one end7Generate the refrigerant enthalpy h of indoor heat exchanger first end7 refrigerantsSpecifically include:
According to the indoor heat exchanger middle portion temperature t in the middle part of the indoor heat exchanger6With the indoor heat exchanger first end temperature t7It is raw
Into degree of superheat Δ t7;
According to the degree of superheat Δ t7With the indoor heat exchanger middle portion temperature t6Generate indoor heat exchanger first end refrigerant enthalpy
Modifying factor D7;
According to the modifying factor D of the indoor heat exchanger first end refrigerant enthalpy7, saturation refrigerant under the delivery temperature
Enthalpy hIt is vented saturationGenerate the refrigerant enthalpy h of the indoor heat exchanger first end7 refrigerants。
24. the efficiency computational methods of air conditioner as claimed in claim 23, it is characterised in that according to generating below equation
The modifying factor D of indoor heat exchanger first end refrigerant enthalpy7:
<mrow>
<msub>
<mi>D</mi>
<mn>7</mn>
</msub>
<mo>=</mo>
<mn>1</mn>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>1</mn>
</msub>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>2</mn>
</msub>
<msup>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<mn>2</mn>
</msup>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>3</mn>
</msub>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<msub>
<mi>t</mi>
<mn>6</mn>
</msub>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>4</mn>
</msub>
<msup>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<mn>2</mn>
</msup>
<msub>
<mi>t</mi>
<mn>6</mn>
</msub>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>5</mn>
</msub>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<msubsup>
<mi>t</mi>
<mn>6</mn>
<mn>2</mn>
</msubsup>
<mo>+</mo>
<msub>
<mi>d</mi>
<mn>6</mn>
</msub>
<msup>
<mrow>
<mo>(</mo>
<msub>
<mi>&Delta;t</mi>
<mn>7</mn>
</msub>
<mo>)</mo>
</mrow>
<mn>2</mn>
</msup>
<msubsup>
<mi>t</mi>
<mn>6</mn>
<mn>2</mn>
</msubsup>
<mo>,</mo>
</mrow>
Wherein, d1-d6For overheated zone coefficient corresponding to refrigerant.
25. the efficiency computational methods of air conditioner as claimed in claim 17, it is characterised in that according to calculating below equation
The refrigerant enthalpy h at the end of indoor heat exchanger second5 refrigerants:
h5 refrigerants=c1+c2t5+c3t2 5+c4t3 5, wherein, c1-c4For fauna number is subcooled corresponding to refrigerant.
26. the efficiency computational methods of air conditioner as claimed in claim 17, it is characterised in that according to generating equation below
The heating capacity of air conditioner:
Wherein, QHeating capacityFor the heating capacity of air conditioner, PCompressorFor compressor horsepower.
27. the efficiency computational methods of air conditioner as claimed in claim 17, it is characterised in that calculated according to below equation each
The lubricating oil enthalpy h of temperature detecting pointI lubricating oil, wherein, i is positive integer,
hI lubricating oil=-0.0808+1.7032ti+0.0025t2 i,
Wherein, tiFor the temperature of temperature detecting point.
28. the efficiency computational methods of air conditioner as claimed in claim 17, it is characterised in that calculated according to below equation each
The mixture enthalpy h of temperature detecting pointi, wherein, i is positive integer,
hi=(1-Cg)hI refrigerants+CghI lubricating oil
Cg=f/104,
Wherein, CgFor mixture oil content, f is the running frequency of the compressor.
29. the efficiency computational methods of air conditioner as claimed in claim 17, it is characterised in that according to generating below equation
The housing heat dissipation capacity Q of compressorloss:
Qloss=5.67 × 10-8×ACompressor((t2+273.15)4-(t8+273.15)4+(9.4+0.052×(t2-t8))×ACompressor
×(t2-t8),
Wherein, ACompressorFor the surface area of compressor housing, t8For the temperature at outdoor heat exchanger fin.
30. the efficiency computational methods of air conditioner as claimed in claim 17, it is characterised in that according to generating below equation
Gas returning port temperature t1:
t1=a*t9+b*t4+ c*f, f are the running frequency of the compressor, and a, b, c is fitting coefficient.
31. a kind of air conditioner, it is characterised in that including memory, processor and be stored on the memory and can be described
The computer program run on processor, described in the computing device during computer program, realize as in claim 17-30
Any described method.
32. a kind of non-transitorycomputer readable storage medium, is stored thereon with computer program, it is characterised in that the meter
The method as described in any in claim 17-30 is realized when calculation machine program is executed by processor.
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