Compressor and refrigeration system having same

What is claimed is: 1. A compressor, comprising: a housing ( 100 ), and a lower flange structure ( 240 ), a first compression cylinder ( 200 ) and a second compression cylinder ( 300 ), provided in the housing ( 100 ) in a bottom-to-top sequence, wherein the first compression cylinder ( 200 ) is provided with a first suction port ( 210 ) and a first exhaust port ( 220 ), the second compression cylinder ( 300 ) is provided with a second suction port ( 310 ) and a second exhaust port ( 320 ), the first exhaust port ( 220 ) is communicated with the second suction port ( 310 ) through a middle passage ( 500 ), a first control valve ( 600 ) is provided in the middle passage ( 500 ), a pin groove ( 241 ) is provided on the lower flange structure ( 240 ), and a pin ( 290 ) is provided in the pin groove ( 241 ); wherein the first compression cylinder ( 200 ) comprises a cylinder body ( 230 ), a roller ( 250 ) and a sliding vane ( 260 ), a sliding vane groove ( 231 ) is provided on an inner wall of the cylinder body ( 230 ), the roller ( 250 ) is provided in the cylinder body ( 230 ), the sliding vane ( 260 ) is provided in the sliding vane groove ( 231 ) and matched with the roller ( 250 ), a first reset member ( 271 ) is provided between the sliding vane ( 260 ) and the sliding vane groove ( 231 ), a lock groove ( 261 ) in positional correspondence to the pin groove ( 241 ) is provided on the sliding vane ( 260 ), a first cavity ( 281 ) is formed between one end of the sliding vane ( 260 ) oriented away from the roller ( 250 ) and a bottom of the sliding vane groove ( 231 ), the cylinder body ( 230 ) is provided with a first passage connecting the first cavity ( 281 ) and an inner cavity of the housing ( 100 ); a second cavity ( 282 ) is formed between a first end of the pin ( 290 ) and the sliding vane ( 260 ), a third cavity ( 283 ) is formed between a second end of the pin ( 290 ) and a bottom of the pin groove ( 241 ), a second reset member ( 272 ) is provided between the pin groove ( 241 ) and the second end of the pin ( 290 ), the lower flange structure ( 240 ) is provided with a second passage for connecting the first cavity ( 281 ) and the second cavity ( 282 ), the compressor further comprising: an intake pipeline ( 700 ), connected to the first suction port ( 210 ), a second control valve ( 800 ) being provided on the intake pipeline ( 700 ); and a high pressure pipeline ( 900 ), a low pressure pipeline ( 1000 ) and a switching device ( 1100 ), the high pressure pipeline ( 900 ) and the low pressure pipeline ( 1000 ) being communicated with the third cavity ( 283 ) through the switching device ( 1100 ), and the switching device ( 1100 ) selectively connecting the high pressure pipeline ( 900 ) or the low pressure pipeline ( 1000 ) to the third cavity ( 283 ). 2. The compressor as claimed in claim 1 , wherein the compressor further comprises a third compression cylinder ( 400 ) provided above the second compression cylinder ( 300 ), and the third compression cylinder ( 400 ) has a third suction port and a third exhaust port ( 410 ). 3. The compressor as claimed in claim 1 , wherein the compressor further comprises a first pipeline ( 1200 ), wherein a first end of the first pipeline ( 1200 ) is communicated with the third cavity ( 283 ), and the switching device ( 1000 ) selectively connects the first pipeline ( 1200 ) with the high pressure pipeline ( 900 ) or the low pressure pipeline ( 1000 ). 4. The compressor as claimed in claim 3 , wherein both the high pressure pipeline ( 900 ) and the low pressure pipeline ( 1000 ) are connected with a second end of the first pipeline ( 1200 ), and the switching device ( 1100 ) comprises: a third control valve ( 1101 ), provided on the high pressure pipeline ( 900 ); and a fourth control valve ( 1102 ), provided on the low pressure pipeline ( 1000 ). 5. The compressor as claimed in claim 3 , wherein the switching device ( 1100 ) is a three-way valve, and the first pipeline ( 1200 ), the high pressure pipeline ( 900 ) and the low pressure pipeline ( 1000 ) are all connected with the three-way valve. 6. The compressor as claimed in claim 3 , wherein a fourth exhaust port ( 110 ) is provided on the housing ( 100 ), and both ends of the high pressure pipeline ( 900 ) are connected with the fourth exhaust port ( 110 ) and a second end of the first pipeline ( 1200 ) respectively. 7. The compressor as claimed in claim 3 , wherein the second control valve ( 800 ) is a one-way valve, the compressor further comprises a second pipeline ( 1300 ), both ends of the second pipeline ( 1300 ) are connected with the intake pipeline ( 700 ) and the first pipeline ( 1200 ) respectively, and a connection end of the second pipeline ( 1300 ) to the intake pipeline ( 700 ) is located at a downstream part of the second control valve ( 800 ). 8. The compressor as claimed in claim 1 , wherein the first reset member ( 271 ) is a spring, a mounting hole ( 232 ) is provided in the cylinder body ( 230 ), and the spring penetrates into the mounting hole ( 232 ), the mounting hole ( 232 ) is a stepped through hole. 9. The compressor as claimed in claim 1 , wherein the middle passage ( 500 ) is provided outside the housing ( 100 ). 10. The compressor as claimed in claim 1 , wherein the first control valve ( 600 ) comprises: a valve seat ( 610 ), provided with a valve port ( 611 ), an inner cone surface ( 612 ) located below the valve port ( 611 ) is provided in the valve seat ( 610 ); a valve core ( 620 ), provided in the valve seat ( 610 ), the valve core ( 620 ) is provided with an outer cone surface ( 621 ) matched with the inner cone surface ( 612 ); and a third reset member ( 630 ), provided between the valve seat ( 610 ) and the valve core ( 620 ), wherein the valve core ( 620 ) is provided with an open position for opening the valve port ( 611 ) and a closed position for closing the valve port ( 611 ), when the valve core ( 620 ) is at the open position, the inner cone surface ( 612 ) and the outer cone surface ( 621 ) are separated, and when the valve core ( 620 ) is at the closed position, the inner cone surface ( 612 ) and the outer cone surface ( 621 ) are contacted. 11. A refrigeration system, comprising a compressor ( 10 ), a condenser ( 20 ), an evaporator ( 30 ) and a gas-liquid separator ( 40 ) connected in sequence, wherein the compressor ( 10 ) is the compressor as claimed in claim 1 , and an intake pipeline ( 700 ) of the compressor ( 10 ) is connected with the gas-liquid separator ( 40 ). 12. The refrigeration system as claimed in claim 11 , wherein a low pressure pipeline ( 1000 ) of the compressor is connected with the evaporator ( 30 ). 13. The compressor as claimed in claim 9 , wherein the first control valve ( 600 ) comprises: a valve seat ( 610 ), provided with a valve port ( 611 ), an inner cone surface ( 612 ) located below the valve port ( 611 ) is provided in the valve seat ( 610 ); a valve core ( 620 ), provided in the valve seat ( 610 ), the valve core ( 620 ) is provided with an outer cone surface ( 621 ) matched with the inner cone surface ( 612 ); and a third reset member ( 630 ), provided between the valve seat ( 610 ) and the valve core ( 620 ), wherein the valve core ( 620 ) is provided with an open position for opening the valve port ( 611 ) and a closed position for closing the valve port ( 611 ), when the valve core ( 620 ) is at the open position, the inner cone surface ( 612 ) and the outer cone surface ( 621 ) are separated, and when the valve core ( 620 ) is at the closed position, the inner cone surface ( 612 ) and the outer cone surface ( 621 ) are contacted. 14. A refrigeratio