Large-scale low-temperature controllable atmospheric boundary layer test system for wind and snow simulation

What is claimed is: 1. A large-scale low-temperature controllable atmospheric boundary layer test system for wind and snow simulation, comprising an atmospheric boundary layer wind tunnel ( 1 ), a plenum chamber ( 3 ) and a refrigeration system ( 2 ), wherein the atmospheric boundary layer wind tunnel ( 1 ) is a closed return wind tunnel, the plenum chamber ( 3 ) and the refrigeration system ( 2 ) are both disposed outside the atmospheric boundary layer wind tunnel ( 1 ), and the plenum chamber ( 3 ) is disposed at an inner loop space of the closed return wind tunnel; wherein the atmospheric boundary layer wind tunnel ( 1 ) comprises an upper flow channel ( 10 ) and a lower flow channel ( 11 ) communicating with each other end to end, a power section ( 9 ) is arranged in the upper flow channel ( 10 ), a settling chamber ( 5 ), a contraction section ( 6 ) and a test section ( 7 ) are sequentially arranged in the lower flow channel ( 11 ) from upstream to downstream, corners of the closed return wind tunnel are respectively provided with a transition section ( 8 ), a fan ( 25 ) is disposed in the power section ( 9 ), and an air heat exchanger ( 18 ) is disposed in the settling chamber ( 5 ); wherein the plenum chamber ( 3 ) is divided by a partition ( 19 ) into a storage room ( 20 ) for storing snow particles and an operation room ( 21 ) provided with a snow particle vibratory spreading device ( 24 ), the storage room ( 20 ) is located at an upper part of the settling chamber ( 5 ), an air cooler ( 22 ) is disposed in the storage room ( 20 ), the operation room ( 21 ) is located at an upper part of the test section ( 7 ), and the snow particle vibratory spreading device ( 24 ) spreads snow particles that uniformly fall into the test section ( 7 ); wherein the refrigeration system ( 2 ) outputs a secondary refrigerant for heat exchange for the air cooler ( 22 ) in the plenum chamber ( 3 ) and the air heat exchanger ( 18 ) in the settling chamber ( 5 ) of the atmospheric boundary layer wind tunnel ( 1 ); wherein the refrigeration system ( 2 ) comprises a cold source system ( 27 ), the cold source system ( 27 ) comprises a primary circulation system ( 28 ), a secondary circulation system ( 29 ) and a cooling circulation system ( 30 ), the primary circulation system ( 28 ) comprises a refrigerating unit ( 31 ), a primary chilled water pump ( 32 ), a buffer tank ( 33 ), a primary circulation secondary refrigerant into-buffer-tank pipe ( 34 ), a primary circulation secondary refrigerant out-of-buffer-tank pipe ( 44 ), a secondary refrigerant into-refrigerating-unit pipe ( 35 ) and a secondary refrigerant out-of-refrigerating-unit pipe ( 45 ), the secondary circulation system ( 29 ) comprises a secondary chilled water pump ( 36 ), a secondary circulation secondary refrigerant into-buffer-tank pipe ( 37 ), a secondary circulation secondary refrigerant out-of-buffer-tank pipe ( 46 ), a secondary refrigerant into-heat-exchanger pipe ( 38 ) and a secondary refrigerant out-of-heat-exchanger pipe ( 47 ), and the cooling circulation system ( 30 ) maintains a condensation number required when the refrigerating unit ( 31 ) works; and wherein a liquid outlet of the refrigerating unit ( 31 ) communicates with a liquid inlet of the primary chilled water pump ( 32 ) through the secondary refrigerant out-of-refrigerating-unit pipe ( 45 ), a liquid outlet of the primary chilled water pump ( 32 ) communicates with a cold end liquid inlet of the buffer tank ( 33 ) through the primary circulation secondary refrigerant into-buffer-tank pipe ( 34 ), a cold end liquid outlet of the buffer tank ( 33 ) communicates with the secondary refrigerant into-refrigerating-unit pipe ( 35 ) through the primary circulation secondary refrigerant out-of-buffer-tank pipe ( 44 ), the secondary refrigerant into-refrigerating-unit pipe ( 35 ) communicates with a liquid inlet of the refrigerating unit, a hot end liquid outlet of the buffer tank ( 33 ) communicates with a liquid inlet of the secondary chilled water pump ( 36 ) through the secondary circulation secondary refrigerant out-of-buffer-tank pipe ( 46 ), a liquid outlet of the secondary chilled water pump ( 36 ) exchanges heat for the air cooler ( 22 ) and the air heat exchanger ( 18 ) through the secondary refrigerant into-heat-exchanger pipe ( 38 ), and the heat-exchanged secondary refrigerant enters a hot end liquid inlet of the buffer tank ( 33 ) through the secondary refrigerant out-of-heat-exchanger pipe ( 47 ) and the secondary circulation secondary refrigerant into-buffer-tank pipe ( 37 ). 2. The large-scale low-temperature controllable atmospheric boundary layer test system for wind and snow simulation according to claim 1 , wherein a net cross-sectional size of the test section ( 7 ) in the lower flow channel ( 11 ) is 2 meter×2 meter. 3. The large-scale low-temperature controllable atmospheric boundary layer test system for wind and snow simulation according to claim 1 , wherein a honeycomb ( 16 ) and screens ( 17 ) are disposed in the settling chamber ( 5 ), and guide vanes ( 26 ) are disposed in the transition section ( 8 ). 4. The large-scale low-temperature controllable atmospheric boundary layer test system for wind and snow simulation according to claim 1 , wherein the operation room ( 21 ) has an openable bottom, and a slide rail ( 23 ) for installing the snow particle vibratory spreading device ( 24 ) is disposed in the operation room ( 21 ). 5. The large-scale low-temperature controllable atmospheric boundary layer test system for wind and snow simulation according to claim 1 , wherein the upper flow channel ( 10 ), the lower flow channel ( 11 ) and the plenum chamber ( 3 ) are in the form of a spliced structure of cold room panels ( 12 ), a sealant is applied to splicing seams, and a structural steel frame ( 14 ) is used outside the spliced structure. 6. The large-scale low-temperature controllable atmospheric boundary layer test system for wind and snow simulation according to claim 1 , wherein the atmospheric boundary layer wind tunnel ( 1 ) is supported on a foundation ( 15 ) by a plurality of structural steel frames ( 14 ). 7. The large-scale low-temperature controllable atmospheric boundary layer test system for wind and snow simulation according to claim 1 , wherein a communicating pipe ( 4 ) is disposed between the secondary refrigerant into-heat-exchanger pipe ( 38 ) and the secondary circulation secondary refrigerant out-of-buffer-tank pipe ( 46 ), a first regulating valve ( 43 ) is disposed on the communicating pipe ( 4 ), and a second regulating valve ( 50 ) is disposed on the secondary refrigerant into-heat-exchanger pipe ( 38 ). 8. The large-scale low-temperature controllable atmospheric boundary layer test system for wind and snow simulation according to claim 1 , wherein the cooling circulation system ( 30 ) comprises a cooling tower ( 39 ), a cooling water pump ( 40 ), a cooling tower water inlet pipe ( 41 ), a cooling tower water outlet pipe ( 48 ), a condenser water inlet pipe ( 42 ) and a condenser water outlet pipe ( 49 ); the cooling tower ( 39 ) communicates with a water inlet of the cooling water pump ( 40 ) through the cooling tower water outlet pipe ( 48 ), a water outlet of the cooling water pump ( 40 ) communicates with a cold end water inlet of the refrigerating unit ( 31 ) through the condenser water inlet pipe ( 42 ), a cold end water outlet of the refrigerating unit ( 31 ) communicates with the condenser water outlet pipe ( 49 ), the condenser water outlet pipe ( 49 ) communicates with the cooling tower water inlet pipe ( 41 ), and the cooling tower water inlet pipe ( 41 ) communicates with a water inlet of the cooling tower ( 39 ). 9. A method of use of the large-scale low-temperature controllable a