RU2024116289A - FIBER LASER WITH COMPRESSION COOLING - Google Patents

Claims (10)

1. A compression-cooled fiber laser, including a housing, inside the housing there is an optical part of the fiber laser, a laser cooling device, the optical part includes a cold plate, a pump laser and an amplifying fiber part mounted on the cold plate; the laser refrigeration device includes a compressor, a condenser, a refrigerant pipe, an expansion valve and a fan, characterized in that the housing has a first interior space and a second interior space, an optical part is located in the first interior space, and the laser refrigeration device is located in the second interior space; The cold plate includes a coolant pipe of the cold plate, the coolant pipe is connected to the coolant pipe of the laser refrigeration device for circulating and handling the coolant. 2. The compression-cooled fiber laser of claim 1, wherein the cold plate is a flat panel structure and is a recessed tube cold plate that has a first cold plate surface on which the semiconductor laser is mounted and an opposing second cold plate surface, the cold plate is mounted vertically on the inside of the laser housing, and the second surface of the cold plate serves as an interface between the first interior space and the second interior space. 3. The compression-cooled fiber laser of claim 2, wherein the housing has a body cabinet top plate and a corresponding body cabinet bottom plate, and four side panels between the top and bottom frame plates, each of which represents, respectively, a first side plate, a second a side plate, a third side plate and a fourth side plate connected in series; the first side plate is opposite the third side plate, the second side plate is opposite the fourth side plate, and the housing surrounds the inner space, the inner space is divided into a first inner space next to the first side plate and a second inner space next to the third side plate; the first surface of the cold plate faces inward of the first housing side plate, and the second surface of the cold plate faces the third housing side plate. 4. A fiber laser with compression cooling according to claim 3, in which the upper plate of the housing cabinet is equipped with a first ventilation hole, and the lower plate of the housing cabinet is equipped with a second ventilation hole, an air circulation channel is formed between the two ventilation holes from bottom to top, the first group of fans is located on the bottom side of the top plate of the cabinet and/or a second group of fans is located on the top side of the bottom plate of the cabinet; The rotation direction of the fan is set to accelerate the air flow coming from the vents on the bottom of the laser body and then flowing out of the vents on the top of the laser body. 5. The compression-cooled fiber laser of claim 3, wherein four sides around the cold plate contact the top plate of the body cabinet, the bottom plate of the body, the second side plate and the fourth side plate of the body, respectively, wherein the cold plate and the body together form a sealed first internal space, the second surface of the cold plate forms a complete separation surface between the first interior space and the second interior space, such that air passing between the first vent hole and the second vent hole will not pass through the first interior space. 6. The compression-cooled fiber laser of claim 4, wherein the laser cooling device is installed in the second internal space, the condenser is located on the upper side of the second internal space, the condenser includes a condensation fin arrangement with a refrigerant duct recessed therein, wherein a condensation fin device is located between the compressor device and the first ventilation hole; a first vent hole is located on an upper side of the second inner space, a second vent hole is located on a lower side of the second inner space; the condensation fin device is installed at the bottom of the first ventilation hole on the top plate of the cabinet, the condensation fin device has a plurality of gaps between the fins, and the plurality of gaps between the fins forms an air circulation path from bottom to top. 7. The compression-cooled fiber laser of claim 6, wherein the cold plate is a single-sided recessed-tube cold plate or a double-sided recessed-tube cold plate, the first vent hole is located in a portion of the corresponding second interior space of the cabinet top plate, and the second vent hole is located in a portion of the corresponding second interior space of the bottom plate of the cabinet; a first group of fans is located on the lower side of the first vent, and an upper side of the group of condensation fins and/or a second group of fans is located between the compressor and the second vent. 8. The compression-cooled fiber laser of claim 3, wherein the air-cooled laser includes an optoelectronic interface portion, wherein the optoelectronic interface portion includes a plurality of optoelectronic interfaces, the second housing side plate has an optoelectronic interface mounting area near the first side plate, and a surface area heat sink near the third side plate; wherein the optoelectronic interface mounting area is used to install at least some or all of the interfaces of the optoelectronic interface portion, the optoelectronic interface mounting area of the second side plate corresponds to a side of the first internal space, the heat sink surface area of the second side plate corresponds to a side of the second internal space, in the heat sink surface area of the second side The plate is provided with a surface structure to enhance heat dissipation. 9. The compression-cooled fiber laser according to claim 8, wherein the optoelectronic interface part is used for optoelectronic connection between the laser main unit and the external environment, including an equipment power supply input port, a fuse interface, a control signal input interface, an optical cable output interface, an area Optoelectronic interface setup is used to install all interfaces of the optoelectronic interface part. 10. The compression-cooled fiber laser according to claim 9, further comprising a laser drive part, and the pump laser unit is more than one semiconductor laser, and also includes an N+1 forward and reverse fiber combiner, the amplifying fiber part is an amplifying an ytterbium-doped fiber, as well as a first diffraction grating and a second diffraction grating located at both ends of the ytterbium-doped amplification fiber; N+1 forward and reverse fiber combiner is used to transmit the combined pump light emitted by the pump laser unit to the amplifying fiber part, the laser refrigeration device also includes an electromagnetic four-way reversing valve, a refrigerant storage tank and a variable frequency compressor connected to the condenser and a cold plate refrigerant line through a refrigerant line, wherein the refrigerant line and the cold plate refrigerant line are filled with refrigerant, the laser refrigeration device also includes a drying filter, the drying filter is located between the condenser and the thermal expansion valve, and the condenser uses a parallel flow aluminum heat exchanger.