CN112191563A

CN112191563A - End surface cleaning device for fluorescent lamp tube

Info

Publication number: CN112191563A
Application number: CN202010770337.6A
Authority: CN
Inventors: 不公告发明人
Original assignee: Hangzhou Gence Technology Co Ltd
Current assignee: Hangzhou Gence Technology Co Ltd
Priority date: 2016-12-19
Filing date: 2016-12-19
Publication date: 2021-01-08
Also published as: CN106944382A; CN106944382B

Abstract

The invention relates to a device for producing a lamp tube of a fluorescent lamp. A fluorescent lamp tube end face cleaning device comprises a lamp tube fixing mechanism and a tube opening wiping mechanism, wherein the lamp tube fixing mechanism comprises a vertical shaft, a transposition motor for driving the vertical shaft to rotate and tube clamps which are axially distributed along a rotating shaft and connected with the vertical shaft together and can keep the lamp tube in a vertical state, the tube opening wiping mechanism comprises a wiper, a water tank and a driving mechanism, and the driving mechanism is used for enabling the wiper to move circularly through the lower part of one tube clamp in the tube clamps and the water tank. The invention provides a fluorescent lamp tube end face cleaning device with high cleaning efficiency for cleaning accumulated powder at a tube opening, and aims to solve the problem that the efficiency of manually cleaning the accumulated powder at the tube opening is low and labor-consuming.

Description

End surface cleaning device for fluorescent lamp tube

The present application is a divisional application of application No. 2016111751198, filed 2020, 12 and 29, entitled "cleaning device for end face of fluorescent lamp tube".

Technical Field

The invention relates to equipment for producing a fluorescent lamp tube, in particular to a fluorescent lamp tube end face cleaning device.

Background

In the manufacturing process of fluorescent lamp tubes, it is necessary to remove the fluorescent powder (also known as tube opening powder deposit) coated on the ends of the tubes to prevent the tube opening powder deposit from falling into the tubes and causing tube contamination. The existing method for removing the accumulated powder at the pipe orifice is manually wiping by using a rag, so the efficiency is low.

Disclosure of Invention

The invention provides a fluorescent lamp tube end face cleaning device with high cleaning efficiency for cleaning accumulated powder at a tube opening, and aims to solve the problem that the efficiency of manually cleaning the accumulated powder at the tube opening is low and labor-consuming.

The technical problem is solved by the following technical scheme: a fluorescent lamp tube end face cleaning device comprises a lamp tube fixing mechanism and a tube opening wiping mechanism, wherein the lamp tube fixing mechanism comprises a vertical shaft, a transposition motor for driving the vertical shaft to rotate and tube clamps which are axially distributed along the vertical shaft and connected with the vertical shaft together and can keep the lamp tube in a vertical state, the tube opening wiping mechanism comprises a wiper, a water tank and a driving mechanism, and the driving mechanism is used for enabling the wiper to move circularly through the lower part of one tube clamp in the tube clamps and the water tank. The wipe may be a cloth, sponge, or the like that is capable of absorbing water and is flexible. When the cleaning brush is used, the wiping object is cleaned and becomes wet when passing through the water tank, and the accumulated powder on the lamp tube is wiped off by the contact of the end part of the lamp tube when passing through the lower part of the lamp tube. When one pipe clamp is positioned on a wiping object of the pipe orifice wiping mechanism to be wiped, the next lamp tube to be wiped can be clamped on the pipe clamp which is not wiped, after the wiping is finished, the vertical shaft is driven by the transposition motor to rotate to the next tube to be wiped to the wiping object to be wiped, at the moment, the wiped lamp tube is taken down and then the lamp tube to be wiped is installed, the cycle is repeated, the wiping and the feeding and the discharging of the lamp tube can be parallel, and therefore the effect of improving the efficiency is achieved.

Preferably, the driving mechanism comprises a conveying belt, a driving roller for driving the conveying belt to rotate and a driving motor for driving the driving roller, the lower side of the conveying belt extends into the water tank, the wiper is arranged on the water absorbing layer on the surface of the conveying belt, and the lamp tube fixing mechanism enables the lamp tube to be positioned above the conveying belt and to be in contact with the water absorbing layer of the conveying belt.

Preferably, the driving mechanism further comprises a first squeezing roller, and the first squeezing roller presses the water absorbing layer to remove water in the water absorbing layer before the water absorbing layer is contacted with the lamp tube after being cleaned by the water tank. The wiping effect can be prevented from being influenced by too much water contained in the wiping material during wiping.

The water tank is provided with a pair of light-transmitting windows, the water clarity feedback mechanism comprises a projection plate and a laser tube, and light emitted by the laser tube irradiates the projection plate through the light-transmitting windows. When the water is too dirty and turbid, the transparent light is attenuated more, and the light cannot be effectively irradiated on the projection plate, and a user judges whether the water is turbid or not by judging whether the light emitted by the laser tube is irradiated on the projection plate or not.

The laser tube heating device comprises a laser tube, a heating structure and a radiator, wherein the laser tube is a green laser diode, the heating structure comprises a heat conduction substrate and a surface mounted resistor arranged on the heat conduction substrate, the radiator is provided with a laser tube mounting hole and a heating structure mounting hole which are communicated together, the heat conduction substrate is mounted in the heating structure mounting hole and is connected with the laser tube in a heat conduction way, the heat conduction substrate is integrally formed with a heat conduction sleeve penetrating through the laser tube mounting hole, the laser tube is connected in the heat conduction sleeve, when the temperature is more than 25 ℃, the laser tube is abutted with the laser tube mounting hole through the heat conduction sleeve, and the linear expansion coefficient of the radiator is smaller than that of the heat conduction sleeve. The green light is not dazzled during observation, and the diode irradiates, thereby saving electricity.

However, the requirement of the green laser diode on the environment temperature is particularly high, the brightness of the green laser diode is reduced when the environment temperature is lower than 25 ℃, and the brightness of the green laser diode is also reduced when the environment temperature is higher than 30 ℃, so that heat dissipation and heating are considered when the green laser diode is used, particularly in winter, the environment temperature is relatively low, the temperature of some countries is near-25 ℃, products using the green laser diode are not bright at all, if a heating structure is not designed on the products to heat the products by the laser diode, the products cannot work, at present, two heating modes are provided for the laser diode, one heating mode is a mode of winding a heating belt on the laser diode and then installing the laser diode on a radiator to heat the laser diode, and the heating mode can cause poor heat dissipation of the laser diode when heat dissipation is needed, so that the green laser diode is seriously not suitable for heating. Another is to place a power resistor on the surface of the heat sink of the laser diode to heat the heat sink, and then transfer the heat to the laser diode through the heat sink, because the heat transfer of the heat sink surface to the laser tube green laser diode is very long when starting, the starting time in the low temperature environment (i.e. the time when the laser diode is heated to above 25 ℃ to normally emit light) is at least more than 30 minutes, i.e. the heating efficiency is low.

According to the technical scheme, the original power resistor is replaced by the patch resistor and is attached to the heat conducting plate, heat of the resistor is transmitted to the heat conducting plate, namely the heat conducting plate serves as a radiator of the resistor, the heat conducting plate is in heat conduction connection with the laser diode, so that the generated heat can be rapidly transmitted to the laser diode, and compared with the second mode, the time for heating the laser diode from-25 ℃ to 25 ℃ of a normal light-emitting machine is only 5-10 minutes (the existing time is 30 minutes). Meanwhile, when the laser diode is not heated, the influence of the existence of the heat conducting plate on the heat dissipation effect of the laser diode is small. When the temperature rises, the close fit between the small diode mounting hole with the thermal expansion effect and the laser diode is formed, so that good heat conduction can be carried out, and the heat dissipation effect can be high. The heat conduction effect between the laser diode and the radiator can be automatically reduced and the heat radiation can be automatically improved during heating.

Preferably, one side of the heat-conducting substrate, which is far away from the laser tube, is disconnected from the hole wall of the heating structure mounting hole. The heat during heating can mostly flow to the laser pipe and locate, plays the effect that improves the heating effect, and the hindrance when dispelling the heat is few.

Preferably, the chip resistor is arranged on one side of the heat conduction substrate far away from the laser tube. The heat transfer of the chip resistor to the heat-conducting plate can be ensured, and the existence of the chip resistor can not interfere with the heat transfer effect between the heat-conducting plate and the laser tube. Need heat the laser pipe when the temperature is less than 25 ℃, form clearance fit between laser pipe mounting hole and the laser pipe this moment under the effect of shrinkage, can prevent effectively that the heat of laser pipe from further running off and playing the effect that improves heating efficiency.

Preferably, one end of the heat conduction sleeve and one end of the radiator are in sealing butt joint with the sealing plate, the other end of the heat conduction sleeve and the other end of the radiator are in sealing connection through the annular liquid storage bag, a sealing cavity is formed among the heat conduction sleeve, the sealing plate, the radiator and the annular liquid storage bag, the sealing cavity is communicated with the annular liquid storage bag, and heat insulation liquid in the annular liquid storage bag can flow into the sealing cavity under the action of gravity or elastic contraction of the annular liquid storage bag. Because when being less than 25 ℃ the cold-shrinking effect can lead to producing the clearance and reducing the effect of heat conduction between heat conduction cover and the radiator and play the effect that improves the heating effect between heat conduction cover and the laser pipe mounting hole, adiabatic liquid fills and plays further improvement adiabatic effect and make the heating effect better in this clearance this moment. When the temperature is higher than 25 ℃ or 30 ℃ and heat dissipation is needed, the heat conduction sleeve and the laser tube mounting hole are tightly pressed together under the action of thermal expansion, and heat insulation liquid between the heat conduction sleeve and the laser tube mounting hole is extruded out in the pressing process and is stored in the annular liquid storage bag. The heating effect during heating can be further improved.

Preferably, the basin is equipped with once along conveyer belt moving direction and washs pond, sewage containing pool and secondary in proper order, sewage containing pool department is equipped with the crowded water roller of second, and the crowded water roller of second is absorbing water the layer and is moving the extrusion layer that absorbs water before the secondary washs the pond through sewage containing pool and make to remove the water that absorbs water in the layer and extruded and drop in the sewage containing pool. The improper cleaning effect of this cleaning method is good and for a washing pond washs, economize on water more.

Preferably, a dirt separation assisting mechanism is arranged in the primary cleaning pool and comprises a blade for extruding the water absorbing layer and a rotating motor for driving the blade to rotate. The cleaning effect can be improved.

Preferably, a spline connecting hole is formed in the end face of a power output shaft of the rotating motor, a rotating shaft of each blade is provided with a spline connector and a supporting disc located above the spline connector, the spline connector is inserted into the spline connecting hole in a vertically sliding mode, a driving sector gear is arranged on the power output shaft and meshed with a driven sector gear, and an eccentric wheel supported on the lower side of the supporting disc is connected to a rotating shaft of the driven sector gear. The blades do rotating motion and lifting motion, and the cleaning effect on the wiping objects is good.

The invention has the following advantages: the powder accumulated at the tube opening of the lamp tube can be removed, the feeding and the discharging of the lamp tube can be synchronously carried out, and the efficiency is high.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a second embodiment of the present invention.

Fig. 3 is a partially enlarged schematic view of a portion a of fig. 2.

FIG. 4 is a schematic view along the direction B of FIG. 2 according to the second embodiment.

FIG. 5 is a schematic diagram of a laser tube during scattering.

Fig. 6 is a schematic diagram of the laser tube in the third embodiment when scattering is performed.

In the figure: the device comprises a lamp tube fixing mechanism 1, a vertical shaft 11, a transposition motor 12, a pipe clamp 13, a pipe orifice wiping mechanism 2, a wiper 21, a water tank 22, a primary cleaning pool 221, a sewage storage pool 222, a secondary cleaning pool 223, a light-transmitting window 224, a driving mechanism 23, a conveying belt 231, a driving roller 232, a guide roller 233, a first water squeezing roller 234, a second water squeezing roller 235, a lamp tube 4, a water clarity feedback mechanism 7, a radiator 71, a laser tube mounting hole 711, a heating structure mounting hole 712, a laser tube 72, a power supply introducing pin 721, a heating structure 73, a heat-conducting substrate 731, a chip resistor 732, heat-conducting glue 733, a heat-conducting sleeve 734, a sealing plate 74, an annular liquid storage bag 75, a sealing cavity 76, a projection plate 77, a dirt separation assisting mechanism 9, a blade 91, a rotating shaft 911 of the blade, a spline 912, a rotating motor 92, a power output shaft 921 of the rotating motor, a spline connecting hole 922, Driven sector gear 95, driven sector gear shaft 951, eccentric 96.

Detailed Description

The invention is further described with reference to the following figures and examples.

Referring to fig. 1, the end face cleaning device for the fluorescent lamp tube comprises a lamp tube fixing mechanism 1 and a tube opening wiping mechanism 2.

The lamp tube fixing mechanism 1 comprises a vertical shaft 11, a transposition motor 12 for driving the vertical shaft to rotate and a plurality of tube clamps 13. There are two pipe clamps 13. The pipe clamps 13 are distributed axially along the vertical axis. The pipe clamp 13 is connected to the vertical shaft 12. Tube 4 is held in an upright position by tube clamps 13 holding tube 4.

The nozzle wiping mechanism 2 includes a wiper 21, a water tank 22, and a driving mechanism 23.

The drive mechanism 23 includes a conveyor belt 231, a drive roller 232, a first wringer roller 234, and a drive motor (located on the rear side of the frame 11, hidden from view by the frame in the figure) that drives the drive roller. The lower side of the conveyor belt 231 is inserted into the water tank 22 by the guide rollers 233. The surface of the conveyor belt 231 is provided with a water-absorbing layer to constitute the wiper 21. The water absorbing layer is made of sponge. The pipe clamp 13 can be rotated to be positioned above the conveyor belt 231.

In use, the tube 4 is held in an upright position by the tube clamp 13, and the cleaning liquid is injected into the tank 22 to submerge the conveyor belt in the tank, with the end of the tube to be cleaned facing downward and pressing against the wipe 3. The conveyer belt 231 rotates clockwise under the effect of driving motor, and the conveyer belt 231 is washd when passing through the basin 22, and first wringing roller 234 cooperates with drive roller 232 to extrude the layer that absorbs water promptly and remove the water in the layer that absorbs water when continuing to pass through first wringing roller 234, wipes off the mouth of pipe deposit powder of fluorescent tube lower extreme when continuing to pass through the below of fluorescent tube 4, at last when changeing back to the basin and wash. When one pipe clamp 13 is positioned above the conveyor belt 231 and the other pipe clamp 13 is positioned beside the conveyor belt 231, the operator mounts the lamp on the other pipe clamp 13 when the lamp 4 of the pipe clamp 13 positioned above the conveyor belt 231 is wiped. After the lamp is wiped, the transposition motor 12 drives the vertical shaft 11 to rotate until the non-wiped tube clamp is positioned above the conveyer belt 231 to wipe the lamp in the tube clamp, and the process is repeated.

The second embodiment is different from the first embodiment in that:

referring to fig. 2, the water tank 22 is provided with a primary cleaning tank 221, a waste water receiving tank 222, and a secondary cleaning tank 223 in this order along the moving direction of the conveyor belt 231.

The inside of the primary cleaning tank 221 is provided with a dirt separation assisting mechanism 9. A pair of second squeezing rollers 235 is disposed at the sewage storage tank 222. The secondary cleaning tank 223 is provided with a pair of light transmission windows 224 distributed on two opposite side walls of the secondary cleaning tank.

Referring to fig. 3, the dirt escape assisting mechanism 9 includes a blade 91 and a rotating motor 92. The rotating shaft 911 of the blade is provided with a spline connector 912 and a supporting disk 93 above the spline connector. The rotation shaft 911 of the vane extends in the up-down direction. A spline connection hole 922 is provided on the end surface of the power output shaft 921 of the rotating electrical machine. The spline connector 912 can be inserted into the spline connecting hole 922 in a vertically sliding manner. A driving sector gear 94 is provided on the power output shaft 921 of the rotating electrical machine. The driving sector gear 94 is meshed with a driven sector gear 95. An eccentric 96 supported on the underside of the support plate 93 is attached to the rotating shaft 951 of the moving sector gear.

Referring to fig. 2, in use, after the light tube is wiped by the wiper, the wiper moves into the primary cleaning tank 221 to be cleaned. The cleaning process comprises the following steps:

referring to fig. 3, the rotary motor 92 rotates the rotary shaft 911 of the blades of the rotary shaft 911 and the rotary shaft 91. The blade 91 is rotated to scrape the wipe 921 in a horizontal plane. The wiper is caused to perform a water sucking and spouting action to discharge the article into the water in the primary washing tank 221. The rotating motor 92 also drives the driving sector gear 94 to rotate when rotating, the driving sector gear 94 drives the driven sector gear 95 to rotate, the driven sector gear 95 drives the eccentric wheel 96 to rotate, the eccentric wheel 96 drives the supporting disc 93 to do lifting motion, the supporting disc 93 drives the blades 91 to do lifting motion, and the blades 91 repeatedly extrude the wipers 231 along the up-down direction, so that the effect of discharging the contained dirt into the primary cleaning pool 221 by the wipers is improved.

Referring to fig. 2, the wipe is then moved over the sewage housing tank 222, and the water contained in the wipe is squeezed out into the sewage housing tank 222 by the squeezing action of the second squeeze roller 235.

The wipe continues to travel through the secondary wash tank 223. The wipe is washed again while passing through the secondary washing tank 223.

The wipe then proceeds as in example one and is not repeated.

Referring to fig. 4, a water clarity feedback mechanism 7 is also included. Water clarity feedback mechanism 7 includes projection plate 77 and laser tube 72. The projection plate 77 and laser tube 72 are distributed on both sides of the water bath 22 and aligned with the light transmissive window 224. The laser tube 72 is sleeved with a heat sink 71, and the laser tube is fixed by the heat sink. The laser tube 72 is a green laser diode. The light emitted from the laser tube 72 is irradiated to the projection plate 77 through the light transmitting window 224.

When the water of the secondary cleaning tank is polluted to the extent that the light transmittance cannot enable light to be transmitted, a user cannot observe a light spot irradiated by the laser tube on the projection plate or the light spot dispersion area is large, and the water is too dirty and needs to be replaced.

Referring to fig. 5, a heating structure 73 is also connected to the heat sink 71.

The heat sink 71 is provided with a laser tube mounting hole 711 and a heating structure mounting hole 712 which are communicated together. The laser tube mounting hole 711 is a circular hole. The heating structure mounting hole 712 is a rectangular hole. The laser tube mounting hole 711 is through with the heating structure mounting hole 712, and specifically, the laser tube mounting hole 711 is through in a manner that the circle thereof extends into the heating structure mounting hole 712, i.e., in an intersecting manner. The laser tube mounting hole 711 and the heating structure mounting hole 712 extend in the same direction, i.e., in the same depth direction, and both extend in the vertical direction.

The laser tube 72 is cylindrical. The laser tube 72 is provided with a power supply lead-in pin 721.

Heating structure 73 includes a thermally conductive substrate 731 and a chip resistor 732 disposed on the thermally conductive substrate. The heat conductive substrate 731 is bonded in the heating structure mounting hole 712 in a flat manner by a heat conductive paste 733. The side of the thermally conductive substrate 731 remote from the laser tube 72 is disconnected from the walls of the heating structure mounting hole 712. The chip resistor 732 is disposed on a side of the thermally conductive substrate 731 away from the laser tube 72. The heat conductive substrate 731 is provided with a heat conductive jacket 734. The heat conductive substrate 731 and the heat conductive sleeve 734 are integrally formed. The heat conducting sleeve 734 is inserted into the laser tube mounting hole 711. The laser tube 72 is inserted through and thermally coupled to the heat conductive sleeve 734 and suspended within the laser tube mounting hole 711. The coefficient of linear expansion of the heat conducting sleeve 734 is greater than the coefficient of linear expansion of the heat sink 71, i.e. the amount of change in the radial dimension of the heat conducting sleeve caused by thermal expansion and contraction is greater than the amount of change in the radial dimension of the laser tube mounting hole. When the temperature is above 25 ℃, the heat conduction sleeve 734 and the laser tube mounting hole 711 are connected together in an abutting mode, and the laser tube 72 and the laser tube mounting hole 711 are indirectly connected together in an abutting mode.

When the laser tube 72 is used, when the temperature of the laser tube 72 is higher than 25 ℃, the heating structure 73, that is, the chip resistor 732, is not electrified, and the radial variation of the heat conduction sleeve 734 is larger than that of the laser tube mounting hole 711, so that the heat conduction sleeve 734 and the laser tube mounting hole 711 are more tightly abutted together to conduct better heat conduction. The heat generated by the laser tube 72 is transferred to the heat sink 71 through the heat conductive sleeve and the heat conductive substrate 731, thereby dissipating the heat. When the temperature of the laser tube 72 is lower than 25 ℃, the chip resistor 732 is powered on, heat generated by the chip resistor 732 is transferred to the heat-conducting substrate 731, enters and is transferred to the laser tube 72 to heat the laser tube 72 to a temperature not lower than 25 ℃, and when the temperature is lower than 25 ℃, the radial reduction amount of the heat-conducting sleeve 734 is larger than that of the laser tube mounting hole 711, so that a gap is generated between the heat-conducting sleeve 734 and the laser tube mounting hole 711, the effect of reducing the heat transferred by the heat-conducting sleeve 734 to the heat radiator 71 is achieved, the heat transferred by the heat-conducting sleeve 734 and the heat-conducting sleeve 734 can be more fully transferred to the laser tube 72, and the effect of improving the heating effect is achieved

The third embodiment is different from the second embodiment in that:

referring to fig. 6, one end of the heat conductive sleeve 734 and one end of the heat sink 71 are both sealingly abutted against the sealing plate 74, i.e. both the heat conductive sleeve and the heat sink may slide relative to the sealing plate 74. The other end of the heat conductive sleeve 734 and the other end of the heat sink 71 are hermetically connected together by an annular reservoir 75. The annular reservoir 75 is filled with a heat insulating liquid which keeps the annular reservoir 75 in an elastically expanded state. At temperatures below 25 ℃, a sealed cavity 76 is formed between the heat conducting sleeve 734, the sealing plate 74, the heat sink 71 and the annular reservoir 75. The sealed chamber 76 communicates with the annular reservoir 75.

In use the annular reservoir 75 is located above the sealed cavity 76 of the annular reservoir 75. When the temperature is lower than 25 ℃, the cold contraction action can cause a gap to be generated between the heat conduction sleeve and the laser tube mounting hole, so that the sealing cavity 76 is formed, at the moment, the heat insulation liquid in the annular liquid storage bag 75 flows into the sealing cavity 76 under the action of gravity and the elastic contraction of the annular liquid storage bag, the quantity of the heat conduction sleeve 734 transmitted to the heat radiator 71 is further reduced, and the heating effect is further improved. When the temperature is higher than 25 ℃ or 30 ℃ and heat dissipation is needed, the heat conduction sleeve and the laser tube mounting hole are tightly pressed together under the action of thermal expansion, so that the sealing cavity 76 disappears, and the heat insulation liquid in the sealing cavity 76 is squeezed back into the annular liquid storage bag 75 again to be stored.

Claims

1. A fluorescent lamp tube end face cleaning device is characterized by comprising a lamp tube fixing mechanism and a tube opening wiping mechanism, wherein the lamp tube fixing mechanism comprises a vertical shaft, a transposition motor for driving the vertical shaft to rotate and tube clamps which are axially distributed along the vertical shaft and connected with the vertical shaft together and can keep the lamp tube in a vertical state; the driving mechanism comprises a conveying belt, a driving roller for driving the conveying belt to rotate and a driving motor for driving the driving roller, the lower side of the conveying belt extends into the water tank, the wiper is a water absorption layer arranged on the surface of the conveying belt, and the lamp tube fixing mechanism enables the lamp tube to be positioned above the conveying belt to be in contact with the water absorption layer of the conveying belt; the driving mechanism also comprises a first wringing roller which is used for squeezing the water absorbing layer before the water absorbing layer is contacted with the lamp tube after the water absorbing layer is cleaned by the water tank so as to remove water in the water absorbing layer; the water tank is provided with a pair of light-transmitting windows, the water clarity feedback mechanism comprises a projection plate and a laser tube, and light emitted by the laser tube irradiates the projection plate through the light-transmitting windows; the laser tube is a green laser diode, the heating structure comprises a heat conduction substrate and a surface mounted resistor arranged on the heat conduction substrate, the radiator is provided with a laser tube mounting hole and a heating structure mounting hole which are communicated together, the heat conduction substrate is mounted in the heating structure mounting hole and is in heat conduction connection with the laser tube, the heat conduction substrate is integrally formed with a heat conduction sleeve penetrating through the laser tube mounting hole, the laser tube is connected in the heat conduction sleeve, when the temperature is above 25 ℃, the laser tube is abutted against the laser tube mounting hole through the heat conduction sleeve, and the linear expansion coefficient of the radiator is smaller than that of the heat conduction sleeve; one end of the heat conduction sleeve and one end of the radiator are in sealing butt joint on the sealing plate, the other end of the heat conduction sleeve and the other end of the radiator are in sealing connection through the annular liquid storage bag, a sealing cavity is formed among the heat conduction sleeve, the sealing plate, the radiator and the annular liquid storage bag, and the sealing cavity is communicated with the annular liquid storage bag and can flow into the sealing cavity through heat insulation liquid in the annular liquid storage bag under the elastic contraction effect of gravity or the annular liquid storage bag.