CN105186267B - Laser radiator - Google Patents
Laser radiator Download PDFInfo
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- CN105186267B CN105186267B CN201510702603.0A CN201510702603A CN105186267B CN 105186267 B CN105186267 B CN 105186267B CN 201510702603 A CN201510702603 A CN 201510702603A CN 105186267 B CN105186267 B CN 105186267B
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Abstract
The present invention relates to a kind of laser radiators, including:Laser module;Thermal insulation board, the thermal insulation board are provided with separator, and multiple separators are arranged at intervals on the thermal insulation board, and multiple laser modules are respectively arranged between separator;Cooling body, the cooling body are connect with the thermal insulation board;The cooling body includes multiple coldplates, and cooling capillary is provided in the coldplate.It will be separated by between multiple laser modules by thermal insulation board so that the heat between multiple laser modules can not be concentrated, simultaneously, thermal insulation board will be after heat absorption, heat is distributed by cooling body so that the heat of laser module can be distributed effectively, substantially increase the service life of laser module.
Description
Technical field
The present invention relates to laser technology fields, more particularly to laser radiator.
Background technology
With the continuous development of laser technology, more and more ripe laser technology is applied in each technical field, for example, swashing
Light mark, laser printing, laser cutting and laser ranging etc., laser have the characteristics that high directivity, brightness are high and energy is concentrated,
Therefore, laser light source often will produce a large amount of heat at work, such as not in time distribute heat, it will influence laser light source
And the working efficiency of related work component, or even will likely result in burning for laser light source and related work component.
Invention content
Based on this, it is necessary to lack good radiator structure for existing laser module, cause to generate at work a large amount of
Heat, and then influence laser module service life defect, a kind of laser radiator is provided, mode of laser is effectively absorbed
The amount of heat that block generates at work, and heat is distributed, substantially increase the service life of laser module.
A kind of laser radiator, including:
Laser module;
Thermal insulation board, the thermal insulation board are provided with separator, and multiple separators are arranged at intervals on the thermal insulation board, more
A laser module is respectively arranged between separator;
Cooling body, the cooling body are connect with the thermal insulation board;
The cooling body includes multiple coldplates, and cooling capillary is provided in the coldplate;
The coldplate is connect with the thermal insulation board, and multiple coldplate connections are internal to form cooling chamber, the cooling
Mechanism further includes cooler, and the cooler is connected to the cooling chamber;
Cooling medium is provided in the cooling chamber;
The cooling medium be refrigerant, the refrigerant be R417A, the cooler include compressor, throttle valve and
One end of condenser, the compressor is connect with condenser one end, and the other end of the condenser and one end of throttle valve connect,
The other end of the throttle valve and one end of cooling chamber connect, and the other end of the cooling chamber and the other end of compressor connect;
The coldplate includes sequentially connected first cooling layer, the second cooling layer and third cooling layer, and described first is cold
But layer is connect with the thermal insulation board, second cooling layer and the third cooling layer to the side far from the thermal insulation board successively
Connection, first cooling layer are set as heat conduction carbon fiber, and second cooling layer is set as copper, the third cooling layer setting
Thickness for aluminium, first cooling layer, the second cooling layer and third cooling layer is sequentially reduced.
In one embodiment, it is provided with coolant liquid in the cooling capillary.
In one embodiment, the coolant liquid is water.
In one embodiment, the cooling capillary diameter is set as 2mm~6mm.
In one embodiment, the cooling capillary diameter is set as 3mm~5mm.
In one embodiment, the cooling capillary diameter is set as 4mm.
Above-mentioned laser radiator will be separated by by thermal insulation board between multiple laser modules so that between multiple laser modules
Heat can not concentrate, meanwhile, thermal insulation board is distributed after heat absorption heat by cooling body so that laser module
Heat can be distributed effectively, substantially increase the service life of laser module.
Description of the drawings
Fig. 1 is the cross-sectional view of the laser radiator of one embodiment of the invention;
Fig. 2 is the cross-sectional view of the laser radiator of another embodiment of the present invention;
Fig. 3 is the cross-sectional view of the laser radiator of another embodiment of the present invention;
Fig. 4 is the cross-sectional view of the laser radiator of one embodiment of the invention;
Fig. 5 is the cross-sectional view of the laser radiator of another embodiment of the present invention;
Fig. 6 is the cross-sectional view of the laser radiator of another embodiment of the present invention;
Fig. 7 is the cross-sectional view in a direction of the laser radiator of another embodiment of the present invention;
Fig. 8 is the cross-sectional view of the laser radiator of another embodiment of the present invention;
Fig. 9 is the cross-sectional view of the laser radiator of another embodiment of the present invention;
Figure 10 is the structural schematic diagram of the thermal insulation board of the laser radiator of another embodiment of the present invention.
Specific implementation mode
To facilitate the understanding of the present invention, below with reference to relevant drawings to invention is more fully described.In attached drawing
Give the better embodiment of the present invention.But the present invention can realize in many different forms, however it is not limited to herein
Described embodiment.On the contrary, the purpose of providing these embodiments is that making to understand more the disclosure
Add thorough and comprehensive.
It should be noted that when element is referred to as " being set to " another element, it can be directly on another element
Or there may also be elements placed in the middle.When an element is considered as " connection " another element, it can be directly connected to
To another element or it may be simultaneously present centering elements.Term as used herein " vertical ", " horizontal ", " left side ",
" right side " and similar statement for illustrative purposes only, are not offered as being unique embodiment.
Unless otherwise defined, all of technologies and scientific terms used here by the article and belong to the technical field of the present invention
The normally understood meaning of technical staff is identical.Used term is intended merely to description tool in the description of the invention herein
The purpose of the embodiment of body, it is not intended that in the limitation present invention.Term " and or " used herein includes one or more
Any and all combinations of relevant Listed Items.
For example, a kind of laser radiator comprising:Laser module;Thermal insulation board, the thermal insulation board is provided with separator, more
A separator is arranged at intervals on the thermal insulation board, and multiple laser modules are respectively arranged between separator;It is cooling
Mechanism, the cooling body are connect with the thermal insulation board;The cooling body includes multiple coldplates, is arranged in the coldplate
There is cooling capillary.
The laser module is for emitting laser, for example, laser module transmitting laser carries out mark, for example, described
Laser module emits laser and carries out ranging, for example, laser module transmitting laser is for cutting, it should be understood that laser
Module can be applicable to different scenes, should not be limited to any of the above-described implement scene, and the laser radiator of the present invention can basis
The different shape and size of laser module and be arranged, following example only as the present invention one or more preferred embodiments into
Row, which is expanded, to be illustrated, is not applied only on the laser module of this type with limiting the present invention.
For example, as shown in Figure 1, it is a preferred embodiment of the present invention laser radiator 10, including:Laser module 100,
Thermal insulation board 200, cooling body 300 and heat-conducting mechanism 400, the thermal insulation board 200 are provided with separator, between multiple separators
Every being arranged on the thermal insulation board 200, multiple laser modules 100 are respectively arranged between separator;The cooling body
300 connect with the thermal insulation board 200;The heat-conducting mechanism 400 is connect with the thermal insulation board 200;For another example, the cooling body
300 include cooling cylinder 310, and there is the cooling cylinder 310 barrel 311, the thermal insulation board 200 to be connected to the barrel 311.
For example, referring again to Fig. 1, the cooling cylinder 310 is rectangular, and the barrel 311 is in four orthogonal
Wall, the thermal insulation board 200 are four, and four thermal insulation boards 200 are connected to four logical inner walls of the cooling, i.e., described in four
Thermal insulation board 200 is arranged in a mutually vertical manner, and multiple laser modules 100 are respectively arranged between separator, will be more by the separator
A laser module 100 is spaced one from so that the heat between multiple laser modules 100 can not be concentrated, and heat is conducive to
It distributes, and multigroup laser module 100 is separately positioned on different thermal insulation boards 200, can further spread the mode of laser
The heat of block 100 so that the heat of multiple laser modules 100 is further disperseed.
For example, the cooling cylinder 310 is polygon, the cooling cylinder 310 of the polygon has multiple inner walls, multiple heat-insulated
Plate 200 is correspondingly arranged on multiple inner walls, in this way, can be with further such that the mode of laser on multiple thermal insulation boards 200
Block 100 is disperseed, for example, the cooling cylinder 310 is hexagon, for example, the cooling cylinder 310 is octagon.
In order to enable the uniform heat distribution of multiple laser modules 100, being conducive to the cooling cylinder 310 can be uniform
Ground absorbs the heat of the laser module 100, for example, as shown in Fig. 2, the cooling cylinder 310 is circle, for example, described heat-insulated
Plate 200 is arc, and the thermal insulation board 200 of arc is matched with 310 shape of the cooling cylinder, and the thermal insulation board 200 is connected to institute
It states on the round tube wall 311 of cooling cylinder 310.
In order to enable heat is more uniformly spread, for example, the thermal insulation board 200 is provided with multiple thermal vias, it is described to dissipate
Heat through-hole is evenly distributed on the thermal insulation board 200, can accelerate the air circulation on thermal insulation board 200 in this way so that it is described every
Heat on hot plate 200 can distribute rapidly, and heat is more uniformly spread.
For example, the different setting of spacing between multiple separators, i.e., spacing between multiple separators not phase
Deng in this way, different spacing can place the laser module 100 of different specifications, size, to meet the needs of different.Alternatively,
In order to enable the heat of the laser module 100 on the thermal insulation board 200 is distributed and is more uniformly distributed, and as depicted in figs. 1 and 2, Duo Gesuo
The spacing stated between separator is equal, is set to the spacing phase of multiple laser modules 100 between multiple separators in this way
Deng so that the heat of multiple laser modules 100 distributed can uniformly be absorbed by the thermal insulation board 200, be avoided described
The heat of laser module 100 is excessively concentrated.
In one embodiment, the separator is isolation bar, for example, the isolation bar and 200 one of the thermal insulation board
Effectively multiple laser modules 100 can be isolated for molding setting, the isolation bar, avoid heat from excessively concentrating, for example, the isolation
Muscle is provided with arc-shaped surface.
In a further embodiment, as shown in Figures 1 to 6, the separator is isolation board 210, for example, the isolation board
210 are vertically arranged on the thermal insulation board 200, are arranged for example, the isolation board 210 is integrally formed with the thermal insulation board 200, example
Such as, as shown in Figures 4 to 6, the both sides of the laser module 100 are connected to two adjacent thermal insulation boards 200, in this way, institute
It states laser module 100 not only to connect with thermal insulation board 200 by bottom so that heat can pass through the bottom of the laser module 100
Portion is transmitted to thermal insulation board 200, can also transfer heat to isolation board 210 by both sides, and the isolation board 210 can will be warm
Amount is transferred to thermal insulation board 200 rapidly, and the radiating efficiency of the laser module 100 is further increased with this.
For example, the isolation board 210 and the integrated forging molding of the thermal insulation board 200, for example, the isolation board 210 and institute
It is metal material to state thermal insulation board 200, for example, the isolation board 210 is alloy material with the thermal insulation board 200, for example, the conjunction
Golden material is copper alloy, for example, the isolation board 210 includes each component of following mass parts with the thermal insulation board 200:
60 parts~75 parts of copper, 4 parts~4.5 parts of aluminium, silver 2.5 parts~4.5 parts, 0.6 part~0.8 part of titanium, 4 parts~4.5 parts of magnesium,
1 part~1.5 parts of iron, 1 part~1.2 parts of nickel, 0.2 part~0.4 part of manganese, 0.5 part~2 parts of graphene, 0.7 part~0.8 part of chromium, vanadium
0.6 part~0.8 part and 1.2 parts~15 parts of silicon.
Preferably, the isolation board 210 includes each component of following mass parts with the thermal insulation board 200:
72 parts of copper, 4.3 parts of aluminium, 3.5 parts of silver, 0.7 part of titanium, 4 parts of magnesium, 1.2 parts of iron, 1.1 parts of nickel, 0.3 part of manganese, graphene
1.3 parts of 1.6 parts, 0.75 part of chromium, 0.75 part of vanadium and silicon.
The alloy synthesized by above-mentioned component, have good heat absorption and heat conductivility, wherein the thermal conductivity of copper be 500~
600W/ (m* DEG C), the thermal conductivity of aluminium are 200~300W/ (m* DEG C), using both metals as the alloy of primary raw material with compared with
Strong heat conductivility, and 600~750W/ of thermal conductivity (m* DEG C) of silver, silver in the alloy more preferably effectively heat conductivility of alloy.
It is too thick it should be understood that the thickness of the isolation board 210 should not be too thick, can not reduce heat conduct to every
The speed of hot plate 200, and if thickness is too thin, easy 100 spacing of laser module for making 210 both sides of the isolation board is too
Closely, it is unfavorable for heat to distribute, and is easy that the heat of the laser module 100 of 210 both sides of isolation board is influenced each other, in order to enable
210 one side of isolation board can absorb rapidly heat, on the other hand reduce the heat of the laser module 100 of 210 both sides of isolation board
Interaction, for example, 210 thickness of the isolation board is set as 8mm~12mm, it is preferable that 210 thickness of the isolation board be arranged
For 9mm~10mm, it is preferable that 210 thickness of the isolation board is set as 9.5mm, in this way so that the heat transfer efficiency of isolation board 210
It is improved, thermal insulation board 200 will can be rapidly transferred to after the heat absorption of laser module 100, on the other hand, avoid two
The spacing of adjacent laser module 100 is too close so that and heat between the two influences each other, and causes local temperature excessively high, to
Influence the service life of laser module 100.
In order to improve heat dissipation effect, as shown in Figures 3 to 6, the cooling body 300 further includes multiple coldplates 320, institute
It states coldplate 320 to connect with the thermal insulation board 200, multiple coldplates 320 connect internal formation cooling chamber 330, for example, institute
It states multiple coldplates 320 and is in turn connected to form cooling cylinder 310, for example, multiple coldplates 320 connect internal formation cooling chamber
330, for example, multiple coldplates 320 are integrally formed connection, the internal cooling cylinder 310 with cooling chamber 330 is formed, for example,
330 shape of the cooling chamber is matched with 310 shape of the cooling cylinder, for example, the cooling cylinder 310 is rectangular, the then cooling
Chamber 330 is Q-RING, and the cooling chamber 330 is arranged around the cooling cylinder 310, for example, Fig. 3 is referred to, the cooling cylinder 310
For circle, then the cooling chamber 330 is circular rings, and the cooling chamber 330 is arranged around the cooling cylinder 310.The coldplate
320 by after the heat absorption of the thermal insulation board 200, and the cooling chamber 330 by heat absorption and distributes rapidly so that the laser
The heat of module 100 can distribute rapidly.
In order to further increase the heat absorption capacity of the cooling chamber 330, as shown in figure 4, the cooling body 300 further includes
Cooler 340, the cooler 340 are connected to the cooling chamber 330, by 200 heat of thermal insulation board in the cooling chamber 330
Air can be cooled down by cooler 340 so that the interior air of the cooling chamber 330 can absorb more heats,
Heat absorption efficiency higher.
For example, referring again to Fig. 4, the cooling body 300 further includes cooling tube 350, and the cooler 340 is by cold
But pipe 350 is connected to the cooling chamber 330, for example, the cooling tube 350 includes first circulation pipe 351 and second circulation pipe
352, there is the cooling chamber 330 first communication port 331 and the first communication port 332, the cooler 340 to be followed by described first
Endless tube 351 is connected to first communication port 331 of the cooling chamber 330, and passes through the second circulation pipe 352 and described the
One communication port 332 is connected to, in this way, absorbing the air of heat can be entered by the first communication port 331 and first circulation pipe 351
Cooler 340, under the effect of the cooler 340, heat is absorbed and is discharged by the cooler 340, logical through cooling air
It crosses second circulation pipe 352 and the first communication port 332 is again introduced into cooling chamber 330 so that the temperature of cooling chamber 330 is dropped
It is low, improve the heat absorption capacity of cooling chamber 330.
For example, being provided with cooling medium in the cooling chamber 330, for example, the cooling medium is air, air is good
Heat transfer medium, the characteristics of being easy to obtain, have velocity of liquid assets fast, be easy to transmission, air can rapidly in cooling chamber 330 and
It circulates in cooler 340 so that heat exchanger effectiveness improves, in order to further increase the endothermic effect of the cooling body 300, example
Such as, the cooling medium is coolant liquid, for example, the coolant liquid is cooling water, water has the characteristics that specific heat capacity is big, and has valence
Lattice are cheap, the advantages of being easily obtained, when cooling water circulation in cooling chamber 330, can effectively take away the heat of coldplate 320
Amount, and heat is distributed by cooler 340, since specific heat capacity is big, cooling water can fully absorb the heat of coldplate 320
Amount, and temperature is unlikely to increase excessively, has good endothermic effect.For example, the cooler 340 includes water cooling box 360, institute
State water cooling box 360 goes pipe to be connected to the cooling chamber 330 by cold, such as multiple copper pipes are provided in the water cooling box 360, institute
It states copper pipe to connect with the radiating fin 361 being set to outside the water cooling box 360, cooling water is by the heat of the cooling chamber 330
It takes in water cooling box 360, after the copper pipe in the water cooling box 360 absorbs the heat of cooling water, transfers heat to radiating fin
Piece 361, radiating fin 361 distribute heat.
For example, in order to improve the heat absorption efficiency of cooling water in cooling chamber 330, referring again to Fig. 4, the cooling chamber 330
It is inside provided with metallic particles 333, for example, the metallic particles 333 is copper particle, for example, the metallic particles 333 is aluminium copper
Grain, metallic particles 333 have good heat-conducting effect, can fully absorb the heat of coldplate 320, and metallic particles 333 increases
The contact area with cooling water is added, during flow of cooling water, metallic particles 333 can be filled in multiple angles with cooling water
Tap is touched so that heat fully can be transferred to cooling water by metallic particles 333, improve thermal conversion efficiency.
In order to avoid metallic particles 333 flows out the cooling chamber 330 with the flowing of cooling water, as shown in figure 4, described
First communication port 331 and first communication port 332 of cooling chamber 330 are respectively arranged with strainer 334, the strainer 334
With filter opening, the diameter of the filter opening is less than the diameter of the metallic particles 333, it should be understood that the metallic particles 333
Diameter cannot be excessive, if the diameter of metallic particles 333 is excessive, the quality of metallic particles 333 increases therewith, then influence described in
The mobility of metallic particles 333 so that metallic particles 333 is unable to fully move with the flowing of cooling water, reduces metal
The contact frequency of particle 333 and cooling water, and the diameter of metallic particles 333 is also unsuitable too small, too small then metallic particles 333 is easy
It is lost in from cooling chamber 330, and in order to avoid the too small metallic particles 333 of diameter is lost in, then the diameter of filter opening then will accordingly subtract
Small, the reduction of the diameter of filter opening then reduces the mobility of cooling water, in order to improve the flexibility ratio of metallic particles 333, and makes
The more flowability of cooling water, for example, the metallic particles 333 a diameter of 3mm~6mm, a diameter of 1.8mm of filter opening~
3.5mm;Preferably, 333 a diameter of 5mm of the metallic particles, a diameter of 3mm of filter opening, in this way, metallic particles 333 has
Smaller volume and quality, flexibility ratio is higher, can be moved with flow of cooling water and quickly, increases the contact frequency with cooling water,
On the other hand, the control of filter opening can abundant filtering metal particle 333, avoid metallic particles 333 from being lost in, and with good logical
The property crossed so that cooling water has preferable mobility, so that cooling water can rapidly take away heat.
In order to further increase endothermic effect, for example, the coolant liquid is ethyl alcohol, ethyl alcohol has volatile characteristic, when
Ethyl alcohol is heated readily volatilized in the cooling chamber 330, can absorb the heat of the coldplate 320 rapidly, when ethyl alcohol circulates
When to cooler 340, heat is released under the action of cooler 340, ethyl alcohol cohesion is liquid, is circulated again into cooling chamber 330
It is interior, to realize the cycle of heat absorption and heat dissipation, substantially increase the radiating efficiency of coldplate 320.
For example, the cooling medium is liquid nitrogen, liquid nitrogen has extremely low temperature, has extraordinary endothermic effect, when
Liquid nitrogen when circulation, can absorb the heat of cooling version as quick as thought in cooling chamber 330 so that cooling version has extraordinary heat absorption
Effect, can be rapidly by the heat absorption of thermal insulation board 200 so that laser module 100 works at a normal temperature, substantially increases
The service life of laser module 100.
In order to further increase the cooling effect of cooling body 300, for example, the cooling medium is refrigerant, for example, institute
It is R417A to state refrigerant, for example, as shown in figure 5, the cooler 340 includes compressor 341, throttle valve 342 and condenser
343, one end of the compressor 341 is connect with 343 one end of condenser, the other end and the throttle valve 342 of the condenser 343
One end connects, and the other end of the throttle valve 342 is connect with one end of cooling chamber 330, the other end and pressure of the cooling chamber 330
The other end of contracting machine 341 connects, and in concrete application, compressor 341 works, and refrigerant compression is freezed for high pressure gaseous
Agent, refrigerant enter condenser 343 after compression, and under the cooling effect of condenser 343, the gaseous refrigerant of high temperature and pressure is cold
But it is the liquid refrigerant of cryogenic high pressure, cryogenic high pressure liquid refrigerant becomes low-temp low-pressure under 342 antihypertensive effect of throttle valve
Liquid refrigerant after low-temp low-pressure liquid refrigerant enters cooling chamber 330, absorbs the heat in cooling chamber 330, rapid to volatilize,
So that the temperature of cooling chamber 330 and coldplate 320 reduces rapidly, so that the heat of thermal insulation board 200 is largely absorbed, volatilization
It after gaseous refrigerant afterwards enters compressor 341, is compressed, is constantly recycled with this process again, worked in laser module 100
When for 100 low temperature of laser module working environment, extend laser module 100 service life.
In order to further increase heat absorption and the capacity of heat transmission of the coldplate 320, please referring also to Fig. 6 and Fig. 7, described cold
But it is provided with cooling capillary 325 in plate 320, for example, the cooling capillary 325 is connected to the cooling chamber 330, in this way,
The contact area that cooling chamber 330 and coldplate 320 can be increased by the cooling capillary 325, further increases cooling chamber
330 heat absorption efficiency so that the heat of the thermal insulation board 200 can efficiently be transmitted to cooling chamber by the coldplate 320
330, and distributed by cooling chamber 330.
For example, coolant liquid is provided in the cooling capillary 325, such as the coolant liquid is cooling water, for example, described
Cooling water in cooling chamber 330 by being circulated to cooling capillary 325 so that cooling water can be contacted fully with coldplate 320, cooling
Water can fully absorb the heat of coldplate 320, and take away heat in the cyclic process of cooling water, and distribute.
It should be understood that the diameter of the cooling capillary 325 should not be too large, the diameter of excessive cooling capillary 325
The heat absorption capacity of coldplate 320 will be made to decline, also the coolant liquid can not be made fully to be contacted with the coldplate 320, and
The diameter of the cooling capillary 325 is also unsuitable too small, and the diameter of too small cooling capillary 325 will influence the stream of coolant liquid
It is logical, in order to increase the contact area of coolant liquid and coldplate 320, and improve stream of the coolant liquid in cooling capillary 325
Logical speed, for example, 325 diameter of cooling capillary is set as 2mm~6mm, it is preferable that 325 diameter of cooling capillary
It is set as 3mm~5mm, it is preferable that 325 diameter of cooling capillary is set as 4mm, for example, setting in the coldplate 320
There are multiple cooling capillaries 325, smaller 325 to one, the cooling capillary of such diameters multiple to be in this way relatively large in diameter
The surface area bigger of cooling capillary 325 improves to considerably increase the contact area of coolant liquid and the coldplate 320
The heat absorption capacity of coolant liquid, on the other hand so that coolant liquid can swimmingly circulate in the cooling capillary 325, carry
High heat exchanger effectiveness.It is more uniformly distributed in order to enable coolant liquid can be contacted with the coldplate 320, for example, multiple described cold
But capillary 325 is uniformly arranged in the coldplate 320, for example, multiple cooling capillaries 325 are parallel to each other and uniform
It is arranged in the coldplate 320, for example, as shown in fig. 7, multiple cooling capillaries 325 are in head and the tail sequentially connected " U "
Shape is arranged, and on the one hand increases the contact area of coolant liquid and coldplate 320 so that each position of coolant liquid and coldplate 320
Contact is more uniformly distributed, and on the other hand allows coolant liquid in the cooling chamber 330 and 325 inner recirculation flow of cooling capillary
It is logical, further increase heat exchanger effectiveness.
In order to further increase heat absorption and the heat-sinking capability of the coldplate 320, as shown in Figure 8 and Figure 9, the cooler
Structure 300 includes multiple coldplates 320, and the coldplate 320 includes sequentially connected first cooling layer 321, the second cooling layer 322
With third cooling layer 323, first cooling layer 321 is connect with the thermal insulation board 200, for example, first cooling layer 321,
Second cooling layer 322 and the integrated forging molding of third cooling layer 323, for example, first cooling layer 321, the second cooling layer 322
The metal of unlike material is respectively set to third cooling layer 323, for example, first cooling layer 321, the second cooling layer 322
It is respectively the materials synthesis of unlike material with third cooling layer 323, for example, first cooling layer 321 is set as heat conduction carbon fiber
Dimension, second cooling layer 322 are set as copper, and the third cooling layer 323 is set as aluminium.
In order to which the heat improved between first cooling layer 321, the second cooling layer 322 and third cooling layer 323 transmits effect
Rate, for example, being provided with silica gel between first cooling layer 321, the second cooling layer 322 and third cooling layer 323.
It should be understood that since first cooling layer 321, the second cooling layer 322 and third cooling layer 323 be not using
Same material is made, therefore first cooling layer 321, the second cooling layer 322 and third cooling layer 323 have different heat conduction
Rate is more uniformly distributed in order to enable the heat of first cooling layer 321, the second cooling layer 322 and third cooling layer 323 is transmitted, is high
Effect, for example, the thickness of first cooling layer 321, the second cooling layer 322 and third cooling layer 323 is sequentially reduced, above-mentioned
In one embodiment, first cooling layer 321 is heat conduction carbon fiber, and the thermal conductivity of heat conduction carbon fiber is 600~900W/ (m*
DEG C), second cooling layer 322 is copper, and the thermal conductivity of copper is 500~600W/ (m* DEG C), and third cooling layer 323 is aluminium, aluminium
Thermal conductivity be 200~300W/ (m* DEG C), for example, first cooling layer 321 is connect with the thermal insulation board 200, described second
Cooling layer 322 and the third cooling layer 323 are sequentially connected to the side far from the thermal insulation board 200, the third cooling layer
323 are located at the outermost of coldplate 320, and first cooling layer 321 can quickly absorb the heat of thermal insulation board 200, and will be hot
To second cooling layer 322, the second cooling layer 322 conducts heat to third cooling layer 323, third cooling layer for amount conduction
323 distribute heat, due to the heat of first cooling layer 321, second cooling layer 322 and the third cooling layer 323
Conductance is gradually reduced, and therefore, in order to enable heat transference efficiency improves, needs to reduce second cooling layer 322 and the third
The thickness of cooling layer 323 can be passed by second cooling layer 322 and the third cooling layer 323 rapidly so that heat is transmitted
It is delivered to the external world, it is preferable that the thickness ratio of first cooling layer 321, the second cooling layer 322 and third cooling layer 323 is 7:6:
3, in this way, not only having improved the endothermic effect of coldplate 320, but also the heat of coldplate 320 is distributed rapidly to the external world.
In order to further increase the heat absorption capacity of the coldplate 320, for example, Fig. 9 is referred to, second cooling layer
322 are provided with multiple cooling hollow bubbles 324, for example, cooling hollow bubble 324 is evenly distributed on second cooling layer 322,
For example, being provided with ethyl alcohol in cooling hollow bubble 324, in this way so that 322 endothermic effect of the second cooling layer evenly,
And there is stronger heat absorption capacity, for example, cooling hollow bubble 324 has circular configuration or circular cross-section, for example, described cold
But 324 a diameter of 0.8mm~1.2mm of Rubus Tosaefulins, it is preferable that the cooling hollow steeps 324 a diameter of 1mm.In other implementation
In example, the cooling hollow bubble 324 is polyhedron, in this way, Rubus Tosaefulins 324 can be from the second cooling described in each face uniform pickup
The heat of layer 322.
In one embodiment, as shown in Fig. 1 and Figure 10, the heat-conducting mechanism 400 includes cooling fin 410, the heat dissipation
Piece 410 is connect with the thermal insulation board 200, for example, the cooling fin 410 is semiconductor heat-dissipating piece 410, when the semiconductor heat-dissipating
When piece 410 is powered, the heat of the cooling fin 410 is transferred to hot junction by cold end, for example, the semiconductor heat-dissipating piece 410 includes
First end and second end, the first end are connect with the thermal insulation board 200, and the second end is connect with the first end, work as institute
When stating the energization of semiconductor heat-dissipating piece 410, the heat absorption of thermal insulation board 200 is transferred to the second end by the first end, is made
Obtaining the temperature of the thermal insulation board 200 can reduce rapidly, it is worth mentioning at this point that, by the semiconductor heat-dissipating piece 410 to described
It is active heat removal that thermal insulation board 200, which carries out heat dissipation, when 200 temperature of thermal insulation board is not high, can also be forced the by being powered
The heat transfer of one end is to second end so that the temperature of thermal insulation board 200 is lower, without when 200 temperature of thermal insulation board is higher
Time just radiates, and can substantially increase radiating efficiency in this way.
In order to further increase radiating efficiency, for example, as shown in Figure 10, four semiconductor heat-dissipating pieces 410 are set, from
And the radiating efficiency of heat-conducting mechanism 400 is improved, for example, the thermal insulation board 200 is rectangular, four semiconductor heat-dissipating pieces
410 are set to four angles of rectangular thermal insulation board 200 or four semiconductor heat-dissipating pieces 410 are set to rectangular thermal insulation board 200
Four sides, in this way, four semiconductor heat-dissipating pieces 410 can equably absorb the heat of thermal insulation board 200 so that thermal insulation board
200 heat, which distributes, to be more uniformly distributed, so that multiple laser modules 100 can obtain effective temperature-reducing, is extended and is used
Service life.
Each technical characteristic of embodiment described above can be combined arbitrarily, to keep description succinct, not to above-mentioned reality
It applies all possible combination of each technical characteristic in example to be all described, as long as however, the combination of these technical characteristics is not deposited
In contradiction, it is all considered to be the range of this specification record.
Several embodiments of the invention above described embodiment only expresses, the description thereof is more specific and detailed, but simultaneously
It cannot therefore be construed as limiting the scope of the patent.It should be pointed out that coming for those of ordinary skill in the art
It says, without departing from the inventive concept of the premise, various modifications and improvements can be made, these belong to the protection of the present invention
Range.Therefore, the protection domain of patent of the present invention should be determined by the appended claims.
Claims (6)
1. a kind of laser radiator, which is characterized in that including:
Laser module;
Thermal insulation board, the thermal insulation board are provided with separator, and multiple separators are arranged at intervals on the thermal insulation board, Duo Gesuo
Laser module is stated to be respectively arranged between separator;
Cooling body, the cooling body are connect with the thermal insulation board;
The cooling body includes multiple coldplates, and cooling capillary is provided in the coldplate;
The coldplate is connect with the thermal insulation board, and multiple coldplate connections are internal to form cooling chamber, the cooling body
Further include cooler, the cooler is connected to the cooling chamber;
Cooling medium is provided in the cooling chamber;
The cooling medium is refrigerant, and the refrigerant is R417A, and the cooler includes compressor, throttle valve and condensation
One end of device, the compressor is connect with condenser one end, and the other end of the condenser and one end of throttle valve connect, described
The other end of throttle valve and one end of cooling chamber connect, and the other end of the cooling chamber and the other end of compressor connect;
The coldplate includes sequentially connected first cooling layer, the second cooling layer and third cooling layer, first cooling layer
It is connect with the thermal insulation board, second cooling layer and the third cooling layer connect successively to the side far from the thermal insulation board
It connects, first cooling layer is set as heat conduction carbon fiber, and second cooling layer is set as copper, and the third cooling layer is set as
The thickness of aluminium, first cooling layer, the second cooling layer and third cooling layer is sequentially reduced.
2. laser radiator according to claim 1, which is characterized in that be provided with coolant liquid in the cooling capillary.
3. laser radiator according to claim 2, which is characterized in that the coolant liquid is water.
4. laser radiator according to claim 1, which is characterized in that the cooling capillary diameter be set as 2mm~
6mm。
5. laser radiator according to claim 4, which is characterized in that the cooling capillary diameter be set as 3mm~
5mm。
6. laser radiator according to claim 5, which is characterized in that the cooling capillary diameter is set as 4mm.
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CN106003499A (en) * | 2016-06-20 | 2016-10-12 | 安庆市鑫顺塑业有限公司 | Plastic film blowing cooling device |
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CN203205702U (en) * | 2013-03-26 | 2013-09-18 | 南京诺威尔光电系统有限公司 | Air-cooled heat dissipation apparatus for semiconductor laser device |
US8660157B2 (en) * | 2007-09-21 | 2014-02-25 | Corporation For National Research Initiatives | Means for improved implementation of laser diodes and laser diode arrays |
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CN104836112B (en) * | 2015-04-17 | 2018-07-10 | 中国科学院苏州生物医学工程技术研究所 | A kind of insulation heat radiator of single-tube semiconductor laser cascaded structure |
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CN203205702U (en) * | 2013-03-26 | 2013-09-18 | 南京诺威尔光电系统有限公司 | Air-cooled heat dissipation apparatus for semiconductor laser device |
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