Heat exchanger

The invention claimed is: 1. A heat exchanger, comprising a refrigerant inlet, a refrigerant outlet, a first header pipe, a second header pipe, a third header pipe, a fourth header pipe and a plurality of flat tubes, one part of the flat tubes connecting the first header pipe to the second header pipe, another part of the flat tubes connecting the third header pipe to the fourth header pipe, wherein the first header pipe comprises a first baffle comprising at least two through holes and separating the first header pipe into a first space and a second space, one of the at least two through holes is located at a center of the first baffle, and the first space and the second space are in direct communication with each other via the at least two through holes, the refrigerant inlet is directly arranged on the first header pipe and in direct communication with the first space of the first header pipe, and the second space of the first header pipe is in communication with the third header pipe, wherein a flow path, that the refrigerant entering via the refrigerant inlet flows from the first space of the first header pipe to the second header pipe along corresponding flat tubes, is defined as a first flow path; a flow path, that the refrigerant flows from the second header pipe to the second space of the first header pipe along corresponding flat tubes, is defined as a second flow path; and a flow path, that the refrigerant has already passed through the second space of the first header pipe flows from the third header pipe to the fourth header pipe along corresponding flat tubes, is defined as a third flow path; and when the refrigerant flows from the first space of the first header pipe to the second header pipe along the corresponding flat tubes, a part of the refrigerant passes through the at least two through holes in the first baffle to enter into the second space of the first header pipe, to skip the first flow path and the second flow path and directly proceed to the third flow path, to reduce a flow quantity of the refrigerant in the first flow path and the second flow path and keep a flow quantity of the refrigerant in the third flow path constant; and wherein, the second header pipe and the fourth header pipe are both not provided with any baffle and are not in direct communication with each other. 2. A heat exchanger, comprising a refrigerant inlet, a refrigerant outlet, a first header pipe, a second header pipe, a third header pipe, a fourth header pipe and a plurality of flat tubes comprising a first set of flat tubes and a second set of flat tubes, the first set of flat tubes connecting the first header pipe to the second header pipe, the second set of flat tubes connecting the third header pipe to the fourth header pipe, wherein, the first header pipe comprises a first baffle comprising at least two through holes and separating the first header pipe into a first space and a second space, one of the at least two through holes is located at a center of the first baffle, and the first space and the second space are in direct communication with each other via the at least two through holes, wherein the refrigerant inlet is directly arranged on the first header pipe and in direct communication with the first space of the first header pipe, the first space is further in communication with the second header pipe through a part of the first set of flat tubes, the second header pipe being in communication with the second space of the first header pipe through another part of the first set of flat tubes, and the second space of the first header pipe is in communication with the third header pipe, and when refrigerant entering via the refrigerant inlet flows from the first space of the first header pipe to the second header pipe along the corresponding part of the first set of flat tubes, a part of the refrigerant passes through the at least two through holes in the first baffle to enter into the second space of the first header pipe, to skip a first flow path from the first space of the first header pipe to the second header pipe and a second flow path from the second header pipe to the second space of the first header pipe and directly proceed to a third flow path from the third header pipe to the fourth header pipe, to reduce a flow quantity of the refrigerant in the first flow path and the second flow path and keep a flow quantity of the refrigerant in the third flow path constant; and wherein the second header pipe and the fourth header pipe are both not provided with any baffle and are not in direct communication with each other. 3. The heat exchanger according to claim 1 , wherein most of the refrigerant is configured to pass through the first flow path and the second flow path to enter into the second space of the first header pipe, and a small part of the refrigerant passes through the at least two through holes in the first baffle and directly enters into the second space of the first header pipe. 4. The heat exchanger according to claim 2 , wherein the third header pipe is provided with a second baffle to separate the third header pipe into a third space and a fourth space which are not in direct communication with each other, and the second space is in communication with the third space; and the refrigerant outlet is in communication with the fourth space. 5. The heat exchanger according to claim 1 , wherein the third header pipe is provided with an imperforate baffle to separate the third header pipe into a third space and a fourth space which are not in direct communication with each other, and the second space is in communication with the third space; and the refrigerant outlet is in communication with the fourth space; a flow path, that the refrigerant enters into the third space from the second space and flows to the fourth header pipe along corresponding flat tubes, is defined as the third flow path; and a flow path, that the refrigerant flows from the fourth header pipe to the fourth space of the third header pipe along corresponding flat tubes, is defined as a fourth flow path. 6. The heat exchanger according to claim 1 , wherein each of the flat tubes is a micro-channel flat tube, and the heat exchanger comprises fins welded between every two adjacent flat tubes. 7. The heat exchanger according to claim 2 , wherein most of the refrigerant is configured to pass through the first flow path and the second flow path to enter into the second space of the first header pipe, and a small part of the refrigerant passes through the at least two through holes in the first baffle and directly enters into the second space of the first header pipe. 8. The heat exchanger according to claim 2 , wherein each of the flat tubes is a micro-channel flat tube, and the heat exchanger comprises fins welded between every two adjacent flat tubes. 9. The heat exchanger according to claim 2 , wherein the heat exchanger is used as an evaporator or a cooling device, the third header pipe is provided with a second baffle to separate the third header pipe into a third space and a fourth space which are not in direct communication with each other, and the second space is in communication with the third space; and the refrigerant outlet is in communication with the fourth space. 10. The heat exchanger according to claim 1 , wherein the heat exchanger is used as an evaporator or a cooling device, the third header pipe is provided with a second baffle without a through hole to separate the third header pipe into a third space and a fourth space which are not in direct communication with each other, and the second space is in communication with the third space; and the refrigerant outlet is in communication with the fourth space; a flow path, that the refrigerant ente