CN108593140A - A kind of Lunar surface temperature daytime measurement system and method - Google Patents
A kind of Lunar surface temperature daytime measurement system and method Download PDFInfo
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- CN108593140A CN108593140A CN201810268207.5A CN201810268207A CN108593140A CN 108593140 A CN108593140 A CN 108593140A CN 201810268207 A CN201810268207 A CN 201810268207A CN 108593140 A CN108593140 A CN 108593140A
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K13/00—Thermometers specially adapted for specific purposes
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05F—SYSTEMS FOR REGULATING ELECTRIC OR MAGNETIC VARIABLES
- G05F1/00—Automatic systems in which deviations of an electric quantity from one or more predetermined values are detected at the output of the system and fed back to a device within the system to restore the detected quantity to its predetermined value or values, i.e. retroactive systems
- G05F1/66—Regulating electric power
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/32—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries for charging batteries from a charging set comprising a non-electric prime mover rotating at constant speed
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/34—Parallel operation in networks using both storage and other dc sources, e.g. providing buffering
- H02J7/35—Parallel operation in networks using both storage and other dc sources, e.g. providing buffering with light sensitive cells
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02N—ELECTRIC MACHINES NOT OTHERWISE PROVIDED FOR
- H02N11/00—Generators or motors not provided for elsewhere; Alleged perpetua mobilia obtained by electric or magnetic means
- H02N11/002—Generators
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K2215/00—Details concerning sensor power supply
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- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Electromagnetism (AREA)
- Radar, Positioning & Navigation (AREA)
- Automation & Control Theory (AREA)
- Photometry And Measurement Of Optical Pulse Characteristics (AREA)
Abstract
The invention discloses a kind of Lunar surface temperature daytime measurement system and methods, wherein the system includes:Solar battery array, thermoelectric generator, power control circuit and temperature collection circuit;Wherein, solar battery array during the daytime moon for receiving solar energy, and converts the solar into electric energy, is supplied to power control circuit;Thermoelectric generator is used to the thermal energy in Isotopes source being converted to electric energy, is supplied to power control circuit;Power control circuit is used to the electric energy that solar battery array exports exporting stable voltage by power regulation and is supplied to temperature collection circuit;Power control circuit is used to the electric energy that the thermoelectric generator exports adjusting the stable voltage of output by boosting and is supplied to temperature collection circuit;Temperature collection circuit is powered by power control circuit, for realizing the acquisition and control of multi way temperature parameter, and the result of acquisition is stored.The present invention solves the problems, such as Lunar surface temperature daytime measurement.
Description
Technical field
The invention belongs to Lunar surface temperature field of measuring technique more particularly to a kind of Lunar surface temperature daytime measurements
System and method.
Background technology
The temperature of moonscape has important influence for the development and existence of moonscape detector, it is therefore desirable to the moon
The temperature of ball surface is accurately measured.Month surface detector will undergo the moonlit night up to more than ten of Earth Day when lunar surface works,
No light during moonlit night, solar cell can not export electric energy, and the only accumulator group by carrying cannot meet the power need of detector
It asks, detector cannot work during the moonlit night.The moon moon, the daytime highest temperature was up to 400K, moonlit night long-term no light and daytime moon high temperature pair
Lunar surface temperature daytime measurement system proposes harsh requirement.The existing moon surface detector in China is only capable of to daytime moon surface
Temperature measures, and can not achieve the round-the-clock continuous measurement of Lunar surface temperature.
Invention content
Present invention solves the technical problem that being:A kind of Lunar surface temperature whole day is overcome the deficiencies of the prior art and provide
Measuring system and method are waited, solves the problems, such as Lunar surface temperature daytime measurement.
The object of the invention is achieved by the following technical programs:A kind of Lunar surface temperature daytime measurement system, packet
It includes:Solar battery array, thermoelectric generator, power control circuit and temperature collection circuit;Wherein, the solar battery array is used for
Solar energy is received during the daytime moon, and converts the solar into electric energy, is supplied to the power control circuit;The thermoelectric generator
For the thermal energy in Isotopes source to be converted to electric energy, it is supplied to power control circuit;The power control circuit is used for will too
The electric energy of positive cell array output is by the stable voltage of power regulation output and is supplied to the temperature collection circuit;The power
Control circuit is used to the electric energy that the thermoelectric generator exports adjusting the stable voltage of output by boosting and be supplied to described
Temperature collection circuit;The temperature collection circuit is powered by power control circuit, for realizing the acquisition of multi way temperature parameter
With control, and the result of acquisition is stored.
In above-mentioned Lunar surface temperature daytime measurement system, further include:Temperature sensor;Wherein, the temperature sensing
Device is for acquiring Lunar surface temperature, and collection result is transferred to the temperature collection circuit.
In above-mentioned Lunar surface temperature daytime measurement system, the power control circuit include power control switching K1 and
Sun battle array adjusts circuit;Wherein, one end of the power control switching K1 is connected with the first end of sun battle array adjusting circuit
Connect, the other end of the power control switching K1 is connected with one end of the solar battery array, the solar battery array it is another
The second end that one end adjusts circuit with the sun battle array is connected, and the sun battle array adjusts third end and the 4th end difference of circuit
It is connected with the temperature collection circuit;The sun battle array adjusts electric energy of the circuit for exporting solar battery array through overpower
It adjusts the stable voltage of output and is supplied to the temperature collection circuit.
In above-mentioned Lunar surface temperature daytime measurement system, the power control circuit further includes power control switching K2
With a liter voltage regulator circuit;Wherein, the first end of described liter of voltage regulator circuit is connected with the anode of the thermoelectric generator, described
The second end for rising voltage regulator circuit is connected with the negative terminal of the thermoelectric generator, one end of the power control switching K2 and institute
The anode for stating thermoelectric generator is connected, and the other end of the power control switching K2 is connected with the negative terminal of the thermoelectric generator
It connects, the third end and the 4th end of described liter of voltage regulator circuit are connected with the temperature collection circuit respectively;The boosting is adjusted
Circuit is used to the electric energy that the thermoelectric generator exports adjusting the stable voltage of output by boosting and is supplied to the temperature
Acquisition Circuit.
In above-mentioned Lunar surface temperature daytime measurement system, the power control circuit sends out solar battery array and the temperature difference
The electric energy of electric appliance output is controlled;Wherein, during the daytime moon, power control switching K1 is closed, and power control switching K2 is closed,
The electric energy of solar battery array output gives the power control circuit, the stable voltage of the power control circuit output, for temperature
Degree Acquisition Circuit is powered;During the moonlit night, power control switching K1 is disconnected, and power control switching K2 is disconnected, thermo-electric generation
The electric energy of device output gives power control circuit, and the stable voltage of power control circuit output is supplied for temperature collection circuit
Electricity;When converting at the daytime moon to the moonlit night, power control switching K2 is disconnected first, and the electric energy of thermoelectric generator output gives power control
Circuit, the stable voltage of power control circuit output, temperature collection circuit is powered by the electric energy that thermoelectric generator exports, then is broken
Open power control switching K1;When converting in daytime moonlit night to the moon, closed power controls switch K1 first, recloses power control switching
The electric energy of K2, solar battery array output give power control circuit, and the stable voltage of power control circuit output, is temperature acquisition
Circuit is powered.
In above-mentioned Lunar surface temperature daytime measurement system, the third end that the sun battle array adjusts circuit passes through diode
D1 is connected with the temperature collection circuit.
In above-mentioned Lunar surface temperature daytime measurement system, the third end of described liter of voltage regulator circuit passes through diode D2
It is connected with the temperature collection circuit.
In above-mentioned Lunar surface temperature daytime measurement system, the sun battle array adjusts the output voltage of circuit and the liter
Pressure difference between the output voltage of voltage regulator circuit is no more than 0.3V.
According to another aspect of the present invention, a kind of Lunar surface temperature daytime measurement method, the method are additionally provided
Include the following steps:During the daytime moon, power control switching K1 is closed, and power control switching K2 is closed, solar battery array output
Electric energy give power control circuit, the stable voltage of power control circuit output is powered for temperature collection circuit;In the moon
During night, power control switching K1 is disconnected, and power control switching K2 is disconnected, and the electric energy of thermoelectric generator output gives power control
Circuit, the stable voltage of power control circuit output, is powered for temperature collection circuit;It is first when converting at the daytime moon to the moonlit night
Power control switching K2 is first disconnected, the electric energy of thermoelectric generator output gives power control circuit, and power control circuit output is steady
Fixed voltage, temperature collection circuit is powered by the electric energy that thermoelectric generator exports, then disconnects power control switching K1;At the moonlit night
When being converted to the daytime moon, closed power controls switch K1 first, recloses power control switching K2, the electric energy of solar battery array output
Power control circuit is given, the stable voltage of power control circuit output is powered for temperature collection circuit;Temperature acquisition electricity
Road powers by power control circuit, for realizing the acquisition and control of multi way temperature parameter, and the result of acquisition is deposited
Storage.
Further include following steps in above-mentioned Lunar surface temperature daytime measurement system:Temperature sensor is by the moon of acquisition
Spherical surface temperature is transferred to temperature collection circuit.
The present invention has the advantages that compared with prior art:
(1) compared with prior art, the present invention combining power supply by a kind of solar battery array of proposition and thermoelectric generator
Mode solves the problems, such as that during the existing moon surface detector moonlit night Lunar surface temperature cannot be measured, can realize moon table
The round-the-clock continuous measurement of face temperature;
(2) compared with prior art, the present invention while realizing Lunar surface temperature daytime measurement, also there is circuit
Structure, control logic are simple, the high advantage of reliability.
Description of the drawings
By reading the detailed description of hereafter preferred embodiment, various other advantages and benefit are common for this field
Technical staff will become clear.Attached drawing only for the purpose of illustrating preferred embodiments, and is not considered as to the present invention
Limitation.And throughout the drawings, the same reference numbers will be used to refer to the same parts.In the accompanying drawings:
Fig. 1 is the structure diagram of Lunar surface temperature daytime measurement system provided in an embodiment of the present invention.
Specific implementation mode
The exemplary embodiment of the disclosure is more fully described below with reference to accompanying drawings.Although showing the disclosure in attached drawing
Exemplary embodiment, it being understood, however, that may be realized in various forms the disclosure without should be by embodiments set forth here
It is limited.On the contrary, these embodiments are provided to facilitate a more thoroughly understanding of the present invention, and can be by the scope of the present disclosure
Completely it is communicated to those skilled in the art.It should be noted that in the absence of conflict, embodiment in the present invention and
Feature in embodiment can be combined with each other.The present invention will be described in detail below with reference to the accompanying drawings and embodiments.
Fig. 1 is the structure diagram of Lunar surface temperature daytime measurement system provided in an embodiment of the present invention.Such as Fig. 1 institutes
Show, which includes:Solar battery array 1, thermoelectric generator 2, power control circuit 3, temperature
Spend Acquisition Circuit 4 and temperature sensor 5.Wherein,
Solar battery array 1 converts the solar into electric energy, is supplied to power control for receiving solar energy during the daytime moon
Circuit processed, output voltage are 0~7.2V.
Thermoelectric generator 2 is supplied to power control circuit, exports for the thermal energy in Isotopes source to be converted to electric energy
Voltage is 0~1.5V.
Power control circuit 3, including power control switching K1, power control switching K2, sun battle array adjust circuit 31 and rise
Voltage regulator circuit 32.The first end 10 that one end of power control switching K1 adjusts circuit 31 with sun battle array is connected, power control
The other end of switch K1 is connected with one end of solar battery array 1, and the other end and the sun battle array of solar battery array 1 adjust circuit 31
Second end 20 be connected, sun battle array adjust circuit 31 third end 30 and the 4th end 40 be connected respectively with temperature collection circuit 4
It connects;Further, the third end 30 of sun battle array adjusting circuit 31 is connected by diode D1 with temperature collection circuit 4.
The first end 50 for rising voltage regulator circuit 32 is connected with the anode of thermoelectric generator 2, and the of liter voltage regulator circuit 32
Two ends 60 are connected with the negative terminal of thermoelectric generator 2, and one end of power control switching K2 is connected with the anode of thermoelectric generator 2
It connects, the other end of power control switching K2 is connected with the negative terminal of thermoelectric generator 2, rises 70 He of third end of voltage regulator circuit 32
4th end 80 is connected with temperature collection circuit 4 respectively.Further, the third end 70 for rising voltage regulator circuit 32 passes through diode
D2 is connected with temperature collection circuit 4.
Specifically, the one end power control switching K1 connects solar battery array output plus terminal, other end connects sun battle array tune
Economize on electricity road;The one end power control switching K2 connects thermoelectric generator anode, and other end connects thermoelectric generator negative terminal;Sun battle array
It adjusts the electric energy that circuit is used to export sun battle array and exports stable voltage 5.1V by power regulation, rise voltage regulator circuit and be used for
The electric energy of thermoelectric generator output is adjusted into the stable voltage 5.3V of output by boosting.During the daytime moon, power control switching
K1 is closed, and power control switching K2 is closed, and the electric energy of solar battery array output gives power control circuit, and power control circuit is defeated
Go out stable voltage 5.1V, is powered for temperature collection circuit.During the moonlit night, power control switching K2 is disconnected, power control
It makes switch K2 to disconnect, the electric energy of thermoelectric generator output gives power control circuit, the stable voltage of power control circuit output
5.3V is powered for temperature collection circuit.When converting at the daytime moon to the moonlit night, power control switching K2, temperature difference hair are disconnected first
The electric energy of electric appliance output gives power control circuit, the stable voltage 5.3V of power control circuit output, temperature collection circuit by
The electric energy power supply of thermoelectric generator output, then disconnect power control switching K1.When converting in daytime moonlit night to the moon, closed power first
Switch K1 is controlled, power control switching K2 is reclosed, the electric energy of solar battery array output gives power control circuit, power control
The voltage 5.1V that circuit output is stablized, is powered for temperature collection circuit.
Temperature collection circuit 4, powers by power control circuit, for realizing the acquisition and control of multi way temperature parameter,
And the result of acquisition is stored.
Temperature sensor 5, for realizing the acquisition of Lunar surface temperature, collection result gives temperature collection circuit.
The present embodiment using based on solar battery array and thermoelectric generator joint power supply by the way of, realize moon daytime during and the moon
Round-the-clock continuous measurement is carried out to Lunar surface temperature during night.
It, can be during the daytime moon and moonlit night to moon table after existing moon surface detector uses temperature measurement system of the present invention
Face temperature is continuously measured, it is ensured that obtains the round-the-clock temperature data of moonscape.
Relative to existing lunar surface detector temperature measuring circuit, variation of the invention is mainly reflected in isotope temperature difference hair
The application of electric appliance and the improvement of power control circuit, the electricity that power control circuit can export solar energy and thermoelectric generator
It can carry out coordination control.During the daytime moon, power control switching K1 is closed, and power control switching K2 is closed, and solar battery array is defeated
The electric energy gone out gives power control circuit, and the stable voltage 5.1V of power control circuit output is supplied for temperature collection circuit
Electricity.During the moonlit night, power control switching K2 is disconnected, and power control switching K2 is disconnected, and the electric energy of thermoelectric generator output is given
Power control circuit, the stable voltage 5.3V of power control circuit output, is powered for temperature collection circuit.In the daytime moon to the moon
When night converts, power control switching K2 is disconnected first, then disconnect power control switching K1, when converting in daytime moonlit night to the moon, first
Closed power controls switch K1, recloses power control switching K2.
When the daytime moon to the moonlit night of the present embodiment converts, temperature measurement system workflow is as shown in table 1.
Table daytime in January to moonlit night inversion temperature measuring system workflow
When the daytime moonlit night of the present embodiment to the moon converts, temperature measurement system workflow is as shown in table 2.
2 moonlit night of table to daytime moon inversion temperature measuring system workflow
The present embodiment additionally provides a kind of Lunar surface temperature daytime measurement method, and this method comprises the following steps:
During the daytime moon, power control switching K1 is closed, and power control switching K2 is closed, the electricity that solar battery array 1 exports
Power control circuit 3 can be given, power control circuit 3 exports stable voltage, is powered for temperature collection circuit 4;
During the moonlit night, power control switching K1 is disconnected, and power control switching K2 is disconnected, the electricity that thermoelectric generator 2 exports
Power control circuit 3 can be given, power control circuit 3 exports stable voltage, is powered for temperature collection circuit 4;
When converting at the daytime moon to the moonlit night, power control switching K2 is disconnected first, and the electric energy that thermoelectric generator 2 exports gives work(
Rate control circuit 3, power control circuit 3 export stable voltage, the electricity that temperature collection circuit 4 is exported by thermoelectric generator 2
It can power, then disconnect power control switching K1;
When converting in daytime moonlit night to the moon, closed power controls switch K1 first, recloses power control switching K2, sun electricity
The electric energy of 1 output of pond battle array gives power control circuit 3, and power control circuit 3 exports stable voltage, is temperature collection circuit 4
It is powered;
Temperature collection circuit 4 is powered by power control circuit, for realizing the acquisition and control of multi way temperature parameter, and
The result of acquisition is stored.
The Lunar surface temperature daytime measurement method further includes following steps:Temperature sensor 5 is by the moon table of acquisition
Face temperature is transferred to temperature collection circuit 4.
Embodiment described above is the present invention more preferably specific implementation mode, and those skilled in the art is in this hair
The usual variations and alternatives carried out in bright technical proposal scope should be all included within the scope of the present invention.
Claims (10)
1. a kind of Lunar surface temperature daytime measurement system, it is characterised in that including:Solar battery array (1), thermoelectric generator
(2), power control circuit (3) and temperature collection circuit (4);Wherein,
The solar battery array (1) converts the solar into electric energy for receiving solar energy during the daytime moon, is supplied to described
Power control circuit (3);
The thermoelectric generator (2) is supplied to power control for the thermal energy in Isotopes source to be converted to electric energy during the moonlit night
Circuit processed;
The electric energy that the power control circuit (3) is used to export solar battery array (1) is by the stable electricity of power regulation output
It presses and is supplied to the temperature collection circuit (4);
The electric energy that the power control circuit (3) is used to export the thermoelectric generator (2) adjusts output by boosting and stablizes
Voltage and be supplied to the temperature collection circuit (4);
The temperature collection circuit (4) is powered by power control circuit, for realizing the acquisition and control of multi way temperature parameter,
And the result of acquisition is stored.
2. Lunar surface temperature daytime measurement system according to claim 1, it is characterised in that further include:Temperature sensing
Device (5);Wherein, the temperature sensor (5) is for acquiring Lunar surface temperature, and collection result is transferred to the temperature acquisition
Circuit (4).
3. Lunar surface temperature daytime measurement system according to claim 1, it is characterised in that:The power control electricity
Road (3) includes that power control switching K1 and sun battle array adjust circuit (31);Wherein,
The first end that one end of the power control switching K1 adjusts circuit (31) with the sun battle array is connected, the power control
The other end of system switch K1 is connected with one end of the solar battery array (1), the other end of the solar battery array (1) and institute
The second end for stating sun battle array adjusting circuit (31) is connected, and the sun battle array adjusts third end and the 4th end difference of circuit (31)
It is connected with the temperature collection circuit (4);
The sun battle array adjusts the electric energy that circuit (31) is used to export solar battery array (1) and exports stabilization by power regulation
Voltage is simultaneously supplied to the temperature collection circuit (4).
4. Lunar surface temperature daytime measurement system according to claim 3, it is characterised in that:The power control electricity
Road (3) further includes power control switching K2 and liter voltage regulator circuit (32);Wherein,
The first end of described liter of voltage regulator circuit (32) is connected with the anode of the thermoelectric generator (2), and the boosting is adjusted
The second end of circuit (32) is connected with the negative terminal of the thermoelectric generator (2), one end of the power control switching K2 and institute
The anode for stating thermoelectric generator (2) is connected, the other end of the power control switching K2 and bearing for the thermoelectric generator (2)
End is connected, and the third end and the 4th end of described liter of voltage regulator circuit (32) are connected with the temperature collection circuit (4) respectively;
The electric energy that described liter of voltage regulator circuit (32) is used to export the thermoelectric generator (2) adjusts output by boosting and stablizes
Voltage and be supplied to the temperature collection circuit (4).
5. Lunar surface temperature daytime measurement system according to claim 4, it is characterised in that:The power control electricity
The electric energy that road (3) exports solar battery array (1) and thermoelectric generator (2) controls;Wherein,
During the daytime moon, power control switching K1 is closed, and power control switching K2 is closed, the electric energy of solar battery array (1) output
Give the power control circuit (3), the stable voltage of power control circuit (3) output is temperature collection circuit (4) into
Row power supply;
During the moonlit night, power control switching K1 is disconnected, and power control switching K2 is disconnected, the electric energy of thermoelectric generator (2) output
Power control circuit (3) is given, the stable voltage of power control circuit (3) output is powered for temperature collection circuit (4);
When converting at the daytime moon to the moonlit night, power control switching K2 is disconnected first, and the electric energy of thermoelectric generator (2) output gives power
Control circuit (3), the stable voltage of power control circuit (3) output, temperature collection circuit (4) are defeated by thermoelectric generator (2)
The electric energy power supply gone out, then disconnect power control switching K1;
When converting in daytime moonlit night to the moon, closed power controls switch K1 first, recloses power control switching K2, solar battery array
(1) electric energy exported gives power control circuit (3), and the stable voltage of power control circuit (3) output, is temperature collection circuit
(4) it is powered.
6. Lunar surface temperature daytime measurement system according to claim 3, it is characterised in that:The sun battle array is adjusted
The third end of circuit (31) is connected by diode D1 with the temperature collection circuit (4).
7. Lunar surface temperature daytime measurement system according to claim 4, it is characterised in that:The boosting adjusts electricity
The third end on road (32) is connected by diode D2 with the temperature collection circuit (4).
8. Lunar surface temperature daytime measurement system according to claim 4, it is characterised in that:The sun battle array is adjusted
Pressure difference between the output voltage of circuit (31) and the output voltage of described liter of voltage regulator circuit (32) is no more than 0.3V.
9. a kind of Lunar surface temperature daytime measurement method, which is characterized in that described method includes following steps:
During the daytime moon, power control switching K1 is closed, and power control switching K2 is closed, the electric energy of solar battery array (1) output
Power control circuit (3) is given, the stable voltage of power control circuit (3) output is powered for temperature collection circuit (4);
During the moonlit night, power control switching K1 is disconnected, and power control switching K2 is disconnected, the electric energy of thermoelectric generator (2) output
Power control circuit (3) is given, the stable voltage of power control circuit (3) output is powered for temperature collection circuit (4);
When converting at the daytime moon to the moonlit night, power control switching K2 is disconnected first, and the electric energy of thermoelectric generator (2) output gives power
Control circuit (3), the stable voltage of power control circuit (3) output, temperature collection circuit (4) are defeated by thermoelectric generator (2)
The electric energy power supply gone out, then disconnect power control switching K1;
When converting in daytime moonlit night to the moon, closed power controls switch K1 first, recloses power control switching K2, solar battery array
(1) electric energy exported gives power control circuit (3), and the stable voltage of power control circuit (3) output, is temperature collection circuit
(4) it is powered;
Temperature collection circuit (4) is powered by power control circuit, for realizing the acquisition and control of multi way temperature parameter, and will
The result of acquisition is stored.
10. Lunar surface temperature daytime measurement method according to claim 9, it is characterised in that further include walking as follows
Suddenly:The Lunar surface temperature of acquisition is transferred to temperature collection circuit (4) by temperature sensor (5).
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Application publication date: 20180928 |