Patent Application
20210057878
The present invention relates to a semiconductor laser device, and more particularly to a semiconductor laser device having a heat dissipation block formed with a flow path through which a coolant flows.
In recent years, there is an increasing demand for metal processing using laser light, and higher output of a laser device is required. Thus, a semiconductor laser device using a semiconductor laser element having high optical-electrical conversion efficiency attracts attention. However, increase in output of a semiconductor laser device increases the amount of current flowing into a semiconductor laser element, so that temperature of the semiconductor laser element rises due to Joule heat. This may cause a degradation in performance, a deterioration of an element, a failure, or the like.
Thus, there has been conventionally proposed a semiconductor laser device having a structure in which a semiconductor laser element and a sub-mount are held between electrode blocks from above and below to discharge heat generated in the semiconductor laser element through the electrode blocks. PTL 1 discloses a structure including a first electrode block provided with a semiconductor laser element and a sub-mount, and a second electrode block provided covering the semiconductor laser element and the sub-mount from above, the blocks being integrated by tightening a screw into a screw hole provided in each member.
Additionally, there has been proposed a structure in which a flow path for allowing cooling water to flow is provided in a heat sink provided with a semiconductor laser element and a sub-mount to cool the semiconductor laser element (e.g., refer to PTLs 2 and 3).
PTL 1: International Publication No. WO 2016/103536
PTL 2: Unexamined Japanese Patent Publication No. 2008-172141
PTL 3: Japanese Patent No. 3951919
Conventional structure as disclosed in PTLs 2 and 3 requires an insulating portion made of an insulating material such as resin or ceramic to be provided between a heat sink through which cooling water flows and a semiconductor laser element for electrically insulating both the heat sink and the semiconductor laser element.
Unfortunately, an insulating material generally has a low thermal conductivity, so that providing the insulating portion above reduces efficiency of discharging heat generated in the semiconductor laser element. This causes output of the semiconductor laser device to be hindered from increasing.
The present invention is made in view of the above points, and an object thereof is to provide a semiconductor laser device having high cooling efficiency, including a semiconductor laser element disposed in a heat dissipation block provided inside with a flow path through which a coolant flows.
To achieve the above object, a semiconductor laser device according to the present invention includes at least a heat dissipation block provided inside with a flow path through which a coolant flows, and first and second semiconductor laser modules disposed in the heat dissipation block. The heat dissipation block includes a lower heat dissipation block formed with a groove constituting the flow path, an insulating sealant disposed in contact with an upper surface of the lower heat dissipation block, having an opening above the groove, and an upper heat dissipation block made of a conductive material disposed in contact with an upper surface of the insulating sealant, covering the opening. The first semiconductor laser module is disposed in contact with an upper surface of the upper heat dissipation block, having a positive electrode side facing down, and the second semiconductor laser module is disposed in contact with the upper surface of the upper heat dissipation block, having a negative electrode side facing down.
This configuration enables the upper heat dissipation block located above the opening of the insulating sealant to be directly cooled by the coolant, so that cooling efficiency of the semiconductor laser module can be improved by promptly discharging heat generated in the first and second semiconductor laser modules disposed in contact with the upper surface of the upper heat dissipation block to outside the semiconductor laser device using the coolant. Additionally, the amount of current flowing into the semiconductor laser element can be increased, so that the semiconductor laser device can have a high output.
The semiconductor laser device of the present invention enables improving the cooling efficiency of the semiconductor laser module. The semiconductor laser device also can have a high output.
Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings. Descriptions of the preferred exemplary embodiments described below are each intrinsically an example, and are not intended to limit the present invention, and an application or a use of the present invention.
In the following description, a side of semiconductor laser device 100 in
As illustrated in
As illustrated in
Heat dissipation block 60 is provided inside with flow path 66 in a U-shape in top view. Inflow port 66a for a coolant is provided on a right side of heat dissipation block 60 close to a front side thereof, and discharge port 66b therefor is provided on the right side of heat dissipation block 60 and on a rear side of inflow port 66a at a predetermined interval. The coolant supplied from outside flows into inflow port 66a, and passes through the flow path to be discharged outside from discharge port 66b. Cooling water having resistivity adjusted to a predetermined value or more is used as the coolant in the present exemplary embodiment, and the resistivity of the cooling water is preferably managed to prevent leakage of electricity from first and second upper heat dissipation blocks 63a, 63b through the coolant.
Lower heat dissipation block 61 is a metal member made of, for example, copper, a copper-aluminum alloy, or a laminated body of copper and aluminum, and is provided in its upper surface with groove portion 65 constituting flow path 66. The upper surface other than groove portion 65 is flat.
Insulating sealant 62 is made of a material having a predetermined insulating property, and is made of, for example, an insulating resin or ceramic. Insulating sealant 62 is disposed in contact with the upper surface of lower heat dissipation block 61 except groove portion 65. Insulating sealant 62 is also provided with openings 62a and 62b at a predetermined interval, and openings 62a and 62b are located above groove portion 65 in top view. Openings 62a and 62b pass through insulating sealant 62 in its thickness direction. Insulating sealant 62 electrically insulates first and second upper heat dissipation blocks 63a, 63b from lower heat dissipation block 61, and also functions as a sealant that prevents the cooling water from leaking from flow path 66.
First and second upper heat dissipation blocks 63a, 63b are metal members made of the same material as the lower heat dissipation block 61, and are disposed in contact with an upper surface of insulating sealant 62, covering openings 62a, 62b of insulating sealant 62, respectively. First and second upper heat dissipation blocks 63a, 63b are disposed away from each other at a predetermined interval. This allows first and second semiconductor laser modules 10, 20 disposed on an upper surface of first upper heat dissipation block 63a to be electrically insulated and isolated from third and fourth semiconductor laser modules 40,40 disposed on an upper surface of second upper heat dissipation block 63b. However, as described later, second semiconductor laser module 20 and third semiconductor laser module 30 are electrically connected using bus bar 52. First and second upper heat dissipation blocks 63a, 63b each may be made of a material different from that of lower heat dissipation block 61. However, first and second upper heat dissipation blocks 63a, 63b each need to be made of a conductive material because a current at predetermined magnitude flows therethrough as described later.
First and second upper heat dissipation blocks 63a, 63b are each provided on its front side with a plurality of screw holes 64. Screw holes 64 do not pass through corresponding first and second upper heat dissipation blocks 63a, 63b, and have bottom surfaces located inside corresponding first and second upper heat dissipation blocks 63a, 63b. First semiconductor laser module 10 is attached and fixed to first upper heat dissipation block 63a using module fixing screws 90 inserted into respective screw holes 11a, 16a provided in first semiconductor laser module 10 (see
As illustrated in
Lower electrode block 11 is a thick plate member made of a conductive material. For example, lower electrode block 11 is obtained by plating a plate material made of copper (Cu) with nickel (Ni) and gold (Au) in this order. Lower electrode block 11 is disposed with its lower surface in contact with the upper surface of first upper heat dissipation block 63a. Lower electrode block 11 includes recessed portion 11b in a cut-out shape that is opened by cutting out a part of the upper surface and front side surface of lower electrode block 11. Recessed portion 11b accommodates sub-mount 13 and semiconductor laser element 14, and laser light is emitted from semiconductor laser element 14 through a front opening of recessed portion 11b. Lower electrode block 11 also includes screw holes 11a provided on right and left sides of recessed portion 11b one by one separately from recessed portion 11b, screw holes 11a passing through lower electrode block 11. A screw hole (not illustrated) is further provided behind screw holes 11a and on a line passing through between two screw holes 11a in top view. This screw hole opens on the upper surface of lower electrode block 11, having a bottom surface located inside lower electrode block 11, and accommodates terminal fixing screw 91 illustrated in
Insulating sheet 12 is provided on the upper surface of the lower electrode block 11, surrounding recessed portion 11b, and includes openings 12a at positions corresponding to respective screw holes 11a provided in lower electrode block 11. Insulating sheet 12 has a function of electrically insulating upper electrode block 16 and lower electrode block 16 when upper electrode block 11 is attached to lower electrode block 11. Insulating sheet 12 is made of an insulating material such as polyimide or ceramic, for example.
Sub-mount 13 is made of a conductive material such as copper tungsten (Cu:W), for example. As illustrated in
Semiconductor laser element 14 is an edge-emitting semiconductor laser element. Semiconductor laser element 14 is provided on its lower surface with an upper electrode and on its upper surface with a lower electrode (both not illustrated). When the upper electrode is disposed on an upper surface of sub-mount 13 with gold tin (Au—Sn) solder or the like (not illustrated) interposed therebetween, semiconductor laser element 14 is electrically connected to sub-mount 13. In the present exemplary embodiment, the upper electrode of semiconductor laser element 14 is a positive electrode (+pole), and the lower electrode thereof is a negative electrode (−pole). The upper electrode of semiconductor laser element 14 may be in direct contact with the upper surface of sub-mount 13. The lower electrode is provided on its upper surface with a plurality of bumps 15. Semiconductor laser element 14 includes a resonator (not illustrated) extending in a front-rear direction, and a front side surface of semiconductor laser element 14 corresponds to the laser light emitting end surface. Semiconductor laser element 14 is disposed on sub-mount 13 such that the laser light emitting end surface and the front side surface of sub-mount 13 are substantially aligned with each other. Semiconductor laser element 14 may include a plurality of resonators.
Each of bumps 15 is a gold bump formed by melting a wire made of gold (Au), for example. Gold is softer than other metals, so that the bumps are deformed when semiconductor laser element 14 and upper electrode block 16 are connected. This enables semiconductor laser element 14 and upper electrode block 16 to be electrically connected well to each other without mechanically damaging them greatly. The material of each of the bumps is not limited to gold, and may be any material that is conductive and can ensure electrical connection between the lower electrode of semiconductor laser element 14 and upper electrode block 16. Although not illustrated, a metal sheet such as gold foil is inserted between each of the bumps and upper electrode block 16. Inserting the metal sheet enables increasing a contact area between each of bumps 15 and the metal sheet, so that contact resistance between each of bumps 15 and upper electrode block 16 can be reduced. The metal sheet is not limited to gold foil, and a sheet made of another conductive material may be used. A plurality of metal sheets may be inserted between each of bumps 15 and upper electrode block 16. When electrical connection between each of bumps 15 and upper electrode block 15 is sufficiently good, no metal sheet is required to be inserted.
Upper electrode block 16 is provided on the upper surface of lower electrode block 11 with insulating sheet 12 interposed therebetween, covering above recessed portion 11b, and is a thick plate member made of a conductive material. For example, lower electrode block 11 is obtained by plating a plate material made of copper (Cu) with nickel (Ni) and gold (Au) in this order. Upper electrode block 16 includes screw holes 16a at positions communicating with corresponding screw holes 11a provided in lower electrode block 11, and screw hole 16b behind screw holes 16a and on a line passing through between two screw holes 16a in top view. Although screw holes 16a pass through upper electrode block 16, screw hole 16b has a bottom surface located inside upper electrode block 16.
Module fixing screws 90 are inserted into screw holes 16a provided in upper electrode block 16, openings 12a provided in insulating sheet 12, screw holes 11a provided in lower electrode block 11, and screw holes 64 provided in first upper heat dissipation block 63a, and then are fastened to position and fix these members. To insulate first upper heat dissipation block 63a from lower heat dissipation block 61, and lower electrode block 11 from upper electrode block 16, the screw holes each preferably have an inner surface coated with an insulating material, or module fixing screws 90 are each preferably made of an insulating material or coated with an insulating material. Upper electrode block 16 has an upper surface and a lower surface that are flat except portions provided with respective screw holes 16a and 16b. Upper electrode block 16 and lower electrode block 11 each have the same thickness except recessed portion 11b, and upper electrode block 11 and lower electrode block 16 are each formed having the same outer shape in top view. In the specification of the present application, “the same thickness” or “the same outer shape” means the same including manufacturing tolerances of upper electrode block 11 and lower electrode block 16, and thus upper electrode block 11 and lower electrode block 16 may not be strictly identical in thickness or outer shape.
[Electrical Connection between Semiconductor Laser Modules]
As illustrated in
When not only terminal fixing screw 91 is inserted into the opening provided at the left end portion of bus bar 52 and a screw hole provided in upper electrode block 26 of second semiconductor laser module 20 and is tightened, but also terminal fixing screw 91 is inserted into the opening provided at the right end portion of bus bar 52 and a screw hole provided in upper electrode block 36 of third semiconductor laser module 30 and is tightened, bus bar 52 is attached to second and third semiconductor laser modules 20, 30.
Here, as illustrated in
As is evident from
[Heat Discharge from Semiconductor Laser Device]
When a predetermined positive voltage is applied to bus bar 53 in a state where cooling water flows through flow path 66 in heat dissipation block 60 using a cooling water circulation mechanism (not illustrated), current begins to flow in each of semiconductor laser elements 14, 24, 34, 44 of first to fourth semiconductor laser modules 10, 20, 30, 40. When the current exceeds a predetermined threshold value, laser light is emitted forward from each of first to fourth semiconductor laser modules 10, 20, 30, 40.
At this time, heat generated in each of semiconductor laser elements 14, 24, 34, 44 of first to fourth semiconductor laser modules 10, 20, 30, 40 is mainly discharged outside from two paths. The first heat discharge path is for discharging heat into a surrounding atmosphere from upper electrode blocks 16, 26, 36, 46. The second heat discharge path is for discharging heat into flow path 66 of heat dissipation block 60 from semiconductor laser elements 14, 24, 34, 44 using sub-mounts 13, 23, 33, 43 and lower electrode blocks 11, 21, 31, 41.
Flow path 66 is formed by covering above groove portion 65 formed in lower heat dissipation block 61 with first and second upper heat dissipation blocks 63a, 63b. Insulating sealant 62 interposed between lower heat dissipation block 61, and first and second upper heat dissipation block 53a, 63b, is provided with openings 62a, 62b as described above. That is, first and second upper heat dissipation blocks 63a, 63b have lower surfaces in direct contact with the cooling water flowing through flow path 66, so that first and second upper heat dissipation blocks 53a, 63b are directly cooled by the cooling water. Thus, heat transferred from lower electrode blocks 11, 21, 31, 41 to first and second upper heat dissipation blocks 53a, 63b by heat conduction is promptly discharged outside semiconductor laser device 100 using the cooling water. The cooling water discharged from discharge port 66b is cooled to a predetermined temperature using a coolant circulation mechanism (not illustrated), and then is supplied again from inflow port 66a into flow path 66.
As described above, semiconductor laser device 100 according to the present exemplary embodiment includes heat dissipation block 60 provided inside with flow path 66 through which cooling water flows, and first to fourth semiconductor laser modules 10, 20, 30, 40 disposed on heat dissipation block 60.
Heat dissipation block 60 includes lower heat dissipation block 61 formed with groove 65 constituting flow path 66, insulating sealant 62 that is disposed in contact with the upper surface of lower heat dissipation block 61 and that has openings 62a and 62b above groove 65, and first and second upper heat dissipation blocks 63a, 63b that are each made of a conductive material and that are disposed in contact with the upper surface of insulating sealant 62, covering openings 62a, 62b, respectively. First upper heat dissipation block 63a and second upper heat dissipation block 63b are provided away from each other at a predetermined interval.
First semiconductor laser module 10 is disposed in contact with the upper surface of first upper heat dissipation block 63a, having a positive electrode side facing down, and second semiconductor laser module 20 is disposed in contact with the upper surface of first upper heat dissipation block 63a, having a negative electrode side facing down. Third semiconductor laser module 30 is disposed in contact with the upper surface of second upper heat dissipation block 63b, having a positive electrode side facing down, and fourth semiconductor laser module 40 is disposed in contact with the upper surface of second upper heat dissipation block 63b, having a negative electrode side facing down. Additionally, a positive electrode side of second semiconductor laser module 20 and a negative electrode side of third semiconductor laser module 30 are electrically connected using bus bar 52.
Forming semiconductor laser device 100 as described above enables first and second upper heat dissipation blocks 63a, 63b that are respectively located above openings 62a, 62b of insulating sealant 62 to be directly cooled by the cooling water, so that heat generated in first to fourth semiconductor laser modules 10, 20, 30, 40 disposed in contact with the corresponding upper surfaces of first and second upper heat dissipation blocks 63a, 63b can be promptly discharged outside semiconductor laser device 100. That is, cooling efficiency of first to fourth semiconductor laser modules 10, 20, 30, 40 can be improved. This also enables increasing the amount of current flowing into semiconductor laser elements 14, 24, 34, 44, so that semiconductor laser device 100 can have a high output. Interposing insulating sealant 62 between first and second upper heat dissipation blocks 63a, 63b, and lower heat dissipation block 61, not only allows first to fourth semiconductor laser modules 10, 20, 30, 40 to be insulated from lower heat dissipation block 61, but also enables cooling water flowing through flow path 66 to be prevented from leaking outside.
Additionally, first upper heat dissipation block 63a can be used as a current path, so that first and second semiconductor laser modules 10, 20 can be connected in series without using a conductive member. Similarly, second upper heat dissipation block 63b can be used as a current path, so that third and fourth semiconductor laser module 30, 40 can be connected in series without using a conductive member. Then, connecting the positive electrode side of second semiconductor laser module 20 and the negative electrode side of third semiconductor laser module 30 using bus bar 52 enables first to fourth semiconductor laser modules 10, 20, 30, 40 to be connected in series.
When a plurality of semiconductor laser modules is connected in parallel to fabricate a high-output semiconductor laser device 100 having a high output, a load on a power supply connected to the semiconductor laser device increases. This requires increase in power supply capacity to cause increase in size of power supply equipment and increase in equipment costs.
The present exemplary embodiment enables suppressing an increase in load on a power supply, so that the power supply can be reduced in size. Additionally, an increase in equipment costs can be suppressed.
When a plurality of semiconductor laser modules is disposed on heat dissipation block 60 while being electrically separated and is connected in series using a conductive member such as a bus bar, the semiconductor laser modules are required to be separated from each other at an interval more than a distance enabling mutual insulation to be secured. However, an attempt to increase output of semiconductor laser device 100 increases also an applied voltage itself, so that semiconductor laser device 100 is increased in size to secure an insulation distance between the semiconductor laser modules. Additionally, many conductive members are required, and increase in thickness of each conductive member is required to reduce electric resistance. This causes an increase in cost. Each conductive member also cannot be reduced in length to a predetermined length or less to secure an insulation distance, so that electric resistance in the entire current path cannot be sufficiently reduced.
In contrast, the present exemplary embodiment allows first semiconductor laser module 10 and second semiconductor laser module 20 to be electrically connected using first upper heat dissipation block 63a, so that an interval for insulation is not required between the semiconductor laser modules. Similarly, using second upper heat dissipation block 63b does not require an interval for insulation between third semiconductor laser module 30 and fourth semiconductor laser module 40. These structures enable suppressing increase in size of semiconductor laser device 100. Additionally, a number of conductive members connecting the semiconductor laser modules can be reduced, so that increase in cost can be suppressed.
First to fourth semiconductor laser modules 10, 20, 30, 40 respectively include: lower electrode blocks 11, 21, 31, 41; sub-mounts 13, 23, 33, 43 that are electrically connected to the corresponding lower electrode blocks; semiconductor laser elements 14, 24, 34, 44 that are disposed on and electrically connected to sub-mounts 13, 23, 33, 43, respectively; and upper electrode blocks 16, 26, 36, 46 that are provided to hold sets of sub-mounts 13, 23, 33, 43 and corresponding semiconductor laser elements 14, 24, 34, 44 with lower electrode blocks 11, 21, 31, 41, respectively, and that are electrically connected to semiconductor laser elements 14, 24, 34, 44, respectively, while being electrically insulated from lower electrode blocks 11, 21, 31, 41, respectively, using insulating sheet 12 interposed therebetween.
Lower electrode blocks 11, 21 of first and second semiconductor laser modules 10, 20 are disposed in contact with the upper surface of first upper heat dissipation block 63a, and lower electrode blocks 31, 41 of third and fourth semiconductor laser modules 30, 40 are disposed in contact with the upper surface of second upper heat dissipation block 63a.
When first to fourth semiconductor laser modules 10, 20, 30, 40 are formed as described above, heat can be promptly discharged outside from semiconductor laser elements 14, 24, 34, 44, which are heat sources, through lower electrode blocks 11, 21, 31, 41, respectively.
Upper electrode blocks 16, 26, 36, 46 of first to fourth semiconductor laser modules 10, 20, 30, 40 are preferably identical in outer shape in top view, and lower electrode blocks 11, 21, 31, 41 of first to fourth semiconductor laser modules 10, 20, 30, 40 are preferably identical in outer shape in top view.
This structure enables electrode blocks having a common shape to be used in first to fourth semiconductor laser modules 10, 20, 30, 40, so that cost can be reduced.
Additionally, upper electrode blocks 16, 26, 36, 46 and lower electrode blocks 11, 21, 31, 41 of first to fourth semiconductor laser modules 10, 20, 30, 40 are preferably identical in outer shape in top view. Each of upper electrode blocks 16, 26, 36, 46 of first to fourth semiconductor laser modules 10, 20, 30, 40 more preferably has a screw hole for fixing a module and a screw hole for fixing a terminal that are identical in position to those in the corresponding one of lower electrode blocks 11, 21, 31, 41 thereof in top view.
As illustrated in
In contrast, the present exemplary embodiment allows first to fourth semiconductor laser modules 10, 20, 30, 40 to have upper electrode block 16, 26, 36, 46, respectively, that are identical in outer shape to lower electrode blocks 11, 21, 31, 41, so that the separate production described above and the like are not required to be performed, and thus increase in cost can be suppressed.
Semiconductor laser device 100 according to the present exemplary embodiment is configured such that lower electrode blocks 11, 31 of first and third semiconductor laser modules 10, 30 are formed with recessed portions 11b,31b for accommodating sub-mount 13, 33 and semiconductor laser elements 14, 34, respectively, and that upper electrode blocks 26, 46 of second and fourth semiconductor laser modules 20, 40 are formed with recessed portions 26c, 46c for accommodating sub-mounts 23, 43 and semiconductor laser elements 24, 44, respectively.
These structures enable a position of an electrode block connected to a lower electrode of a semiconductor laser element can be alternately inverted vertically, so that first to fourth semiconductor laser modules 10, 20, 30, 40 can be connected in series with a simple structure.
First to fourth semiconductor laser modules 10, 20, 30, 40 respectively include semiconductor laser elements 14, 24, 34, 44 each having a laser light emitting end surface that is preferably located near flow path 66 of heat dissipation block 60 in top view, and more preferably near a portion of flow path 60 that directly extends from inflow port 66a for cooling water.
During operation of the semiconductor laser element, temperature rises most near the laser light emitting end surface. Thus, when the laser light emitting end surface is disposed near flow path 66 of heat dissipation block 60, particularly near a portion where cooling water directly flows from the inflow port 66a without being heated, first to fourth semiconductor laser modules 10, 20, 30, 40 including semiconductor laser elements 14, 24, 34, 44, respectively, can be improved in cooling efficiency.
The upper surface of first upper heat dissipation block 63a, and lower surfaces of lower electrode blocks 11, 21 of first and second semiconductor laser modules 10, 20, in contact with the upper surface, are preferably flat. The upper surface of second upper heat dissipation block 63b, and lower surfaces of lower electrode blocks 31, 41 of third and fourth semiconductor laser modules 30, 40, in contact with the upper surface, are also preferably flat.
These structures enable increasing a contact area between first upper heat dissipation block 63 and lower electrode blocks 11, 21 of first and second semiconductor laser modules 10, 20, so that first and second semiconductor laser modules 10, 20 can be improved in cooling efficiency. Similarly, a contact area between second upper heat dissipation block 63b and lower electrode blocks 31, 41 of third and fourth semiconductor laser modules 30, 40 can be increased, so that third and fourth semiconductor laser modules 30, 40 can be improved in cooling efficiency.
A structure shown in the present modification is different from the structure of the first exemplary embodiment illustrated in
Depending on required specifications of laser light output, semiconductor laser device 200 may be configured as illustrated in
Instead of the structure illustrated in
Then, as described above, when cooling water flowing from inflow port 76a is allowed to directly pass through near a laser light emitting end surface in top view, the semiconductor laser module can be improved in cooling efficiency. Thus, as illustrated in
When laser light is emitted from each of semiconductor laser elements mounted in a laser device including a single semiconductor laser device or a plurality of semiconductor laser devices disposed side by side, laser light having a higher output can be obtained by optically combining the laser light of each of the semiconductor laser elements into one piece of laser light. The laser light can be optically combined by disposing optical components, such as a light deflecting member that deflects laser light emitted from each semiconductor laser element in a predetermined direction and a condenser lens, at respective predetermined positions.
At this time, when a distance from a reference plane, such as an upper surface of first upper heat dissipation block 63a and/or second upper heat dissipation block 63b, to a luminous point of each semiconductor laser element is equal, a light deflecting member that vertically deflects laser light is not required. This causes structure of the laser device to be simplified, so that costs can be reduced.
With reference to
D1=t2−d1+d2 (1)
D2=t1+d1−d2 (2)
D2−D1=(t1−t2)+2(d1−d2) (3)
The thickness of each of sub-mounts 13, 23 includes a thickness of an adhesive layer (not illustrated) provided between sub-mounts 13, 23 and semiconductor laser elements 14, 24, respectively. Insulating sheet 12 has a thickness equal in each of first and second semiconductor laser modules 10, 20, so that the thickness of the insulating sheet 12 is not considered in Expressions (1) to (3) for convenience of description.
Here, assuming that t1=t2, that is, when first and second semiconductor laser modules 10, 20 respectively include upper electrode blocks 16, 26 and lower electrode blocks 11, 21 that are equal in thickness, Expression (4) below holds.
D2−D1=2(d1−d2) (4)
As described above, semiconductor laser elements 14, 24 are each formed with bumps 50, so that d1 is more than d2. Thus, first and second semiconductor laser modules 10, 20 each have a different distance from the reference plane to the luminous point. This requires laser light emitted from any one of first semiconductor laser module 10 and second semiconductor laser module 20 to be vertically deflected to optically combine the laser light as described above, so that the laser device has a complex structure to increase costs.
To solve such a problem, as illustrated in
At this time, the following relationship holds.
t1=t2−2(d1−d2) (5)
Unfortunately, lower electrode blocks 11, 21 are different from each other in thicknesses in this case, so that heat dissipation efficiency to flow path 66 and to the outside in first semiconductor laser module 10 may be different from heat dissipation efficiency to flow path 66 and to the outside in second semiconductor laser module 20. Thus, whether each semiconductor laser module is caused to be similar in heat dissipation efficiency or caused to have a luminous point identical in position is appropriately selected in accordance with required specifications of the laser device.
As in shown in the first exemplary embodiment, when upper electrode blocks 16, 26 and lower electrode blocks 11, 21 of first and second semiconductor laser modules 10, 20 are formed having an identical outer shape in top view, and upper electrode blocks 16, 26 and lower electrode blocks 11, 21 of first and second semiconductor laser modules 10, 20 are each provided with a screw hole for fixing a module and a screw for fixing a terminal that are each disposed at an identical position in top view, electrode blocks required to be formed separately can be sorted into only two types. It is needless to say that the logic above similarly can apply to third and fourth semiconductor laser modules 30 and 40.
Semiconductor laser device 400 shown in the present exemplary embodiment is different from the structure of first exemplary embodiment illustrated in
As described above, the structure illustrated in
In general, a semiconductor laser element has a luminous point closer to an upper electrode (positive electrode) than a lower electrode (negative electrode) (refer to
In contrast, for example, second semiconductor laser module 20 and fourth semiconductor laser module 40 include upper electrode blocks 26, 46 provided with sub-mounts 23, 43, respectively, are not in contact with heat dissipation block 60 as illustrated in
The present exemplary embodiment enables improving this point. This improvement will be described below.
As illustrated in
Although a placement direction is different from an actual placement direction in vertical relationships, additional heat dissipation block 80 includes members disposed on upper surfaces of upper electrode blocks 16, 26, 36, 46 of first to fourth semiconductor laser modules 10, 20, 30, 40, being referred to as third to fifth upper heat dissipation blocks 83a to 83c, and a block formed with groove 85 constituting flow path 86, being referred to as lower heat dissipation block 81. Thus, upper surfaces of third to fifth upper heat dissipation blocks 83a to 83c of additional heat dissipation block 80 are in direct contact with cooling water flowing through flow path 86.
The present exemplary embodiment enables heat transferred from semiconductor laser elements 14, 24, 34, 44 to upper electrode blocks 16, 26, 36, 46 of semiconductor laser modules 10, 20, 30, 40, respectively, to be efficiently discharged outside using third to fifth upper heat dissipation blocks 83a to 83c and cooling water flowing through flow path 86. This also enables increasing the amount of current flowing into semiconductor laser elements 14, 24, 34, 44, so that semiconductor laser device 400 can have a higher output.
The present exemplary embodiment also enables bus bars 51 to 53 illustrated in
When semiconductor laser device 400 is configured as described above, a number of components to be mounted can be reduced, and component costs and assembly costs can be reduced, as compared with the structure illustrated in
additional heat dissipation block 80 of the present exemplary embodiment includes inflow port 86a for cooling water, provided on a left side surface and a front side, and discharge port 86b provided on the left side surface and behind inflow port 86a at a predetermined distance from inflow port 86a. That is, additional heat dissipation block 80 has a structure in which placement of the inflow port and the discharge port in heat dissipation block 60 disposed on lower surfaces of respective first to fourth semiconductor laser modules 10, 20, 30, 40 is laterally inverted.
The cooling water flowing into flow path 66 from inflow port 66a of heat dissipation block 60 gradually increases in temperature as it sequentially passes through below first to fourth semiconductor laser modules 10, 20, 30, 40, due to inflowing heat. Similarly, the cooling water gradually increases in temperature also in additional heat dissipation block 80, as it sequentially passes through above first to fourth semiconductor laser modules 10, 20, 30, 40, due to inflowing heat. In this case, when the cooling water flowing from inflow port 66a of heat dissipation block 60 and the cooling water flowing from inflow port 86a of additional heat dissipation block 80 flow in the same direction, a semiconductor laser module near the inflow ports and a semiconductor far from the inflow ports are different in cooling efficiency. When such a state continues in semiconductor laser device 400 during usage for a long period of time, each semiconductor laser module differs in a degree of deterioration. As a result, the life of the semiconductor laser device 400 may be shortened.
In contrast, the present exemplary embodiment enables suppressing reduction in life of semiconductor laser device 400 by allowing a flowing direction of the cooling water flowing through below first to fourth semiconductor laser modules 10, 20, 30, 40 and a flowing direction of the cooling water flowing through above first to fourth semiconductor laser modules 10, 20, 30, 40 to be opposite to each other, for example, by reducing a difference in cooling efficiency between first semiconductor laser module 10 located at a left end of four semiconductor laser modules 10, 20, 30, 40 disposed side by side and fourth semiconductor laser module 40 located at a right end thereof in the structure illustrated in
Although the first and second exemplary embodiments each show an example in which four semiconductor laser modules 10, 20, 30, 40 are disposed on identical heat dissipation block 60, the present invention is not particularly limited to this, and an even number of semiconductor laser modules may be disposed on the identical heat dissipation block. However, that case requires two semiconductor laser modules to be disposed on each upper heat dissipation block and the semiconductor laser modules to be insulated by spacing adjacent upper heat dissipation blocks at a predetermined distance or more. When additional heat dissipation block 80 is disposed above the semiconductor laser modules, n (n is an even number of four or more) semiconductor laser modules are disposed on identical heat dissipation block 60.
The structure illustrated in
Although an example in which cooling water is used as a coolant is shown, a coolant other than water, such as an antifreeze liquid, may be used. When the semiconductor laser element is excessively cooled, for example, cooled to several degrees Celsius, dew condensation may occur on a laser light emitting end surface, for example. When such dew condensation occurs, laser oscillation may not occur or the semiconductor laser device may be damaged in some cases. When temperature of the semiconductor laser element greatly exceeds 60° C., light output characteristics may change, and thus desired output may not be obtained. Thus, it is preferable to select a kind of coolant or to control temperature of the coolant such that the semiconductor laser element in operation can be maintained at a temperature of about 10° C. to 40° C.
Lower surfaces of first and second upper heat dissipation blocks 63a, 63b may be covered with an insulating material. Similarly, lower surfaces of third to fifth upper heat dissipation blocks 83a to 83c (surfaces constituting one surface of a flow path) also may be covered with an insulating material.
When cooling water is used for a long period of time, resistivity of the cooling water may be reduced due to impurities eluted from pipes (not illustrated), etc., and thus electric leakage through the cooling water may not be successfully prevented. Depending on a kind of coolant, the resistivity may not be increased above a desired value.
In such a case, when surfaces of first to fifth upper heat dissipation blocks 63a, 63b, 83a to 83c, with which a coolant such as cooling water is directly brought into contact, are covered with an insulating material as described above, electric leakage though the coolant can be prevented from occurring. To prevent deterioration in thermal discharge efficiency from first to fifth upper heat dissipation blocks 63a, 63b, 83a to 83c to the coolant, thermal conductivity and thickness of the insulating material need to be set appropriately.
The exemplary embodiments described above including the modifications may be different in shape of the upper electrode block and the lower electrode block, for example, in outer shape in top view.
Besides this, each component described in each of the exemplary embodiments and modifications described above may be combined to form an additional exemplary embodiment.
The semiconductor laser device according to the present invention can improve cooling efficiency of a semiconductor laser module mounted thereon and is useful when applied to a laser light source of a laser processing device or the like.
10 first semiconductor laser module
11 lower electrode block
11
a screw hole
11
b screw hole
12 insulating sheet
12
a opening
13 sub-mount
14 semiconductor laser element
15 bumps
16 upper electrode block
16
a screw hole
16
b screw hole
20 second semiconductor laser module
21 lower electrode block
23 sub-mount
24 semiconductor laser element
26 upper electrode block
26
c recessed portion
30 third semiconductor laser module
31 lower electrode block
31
b recessed portion
33 sub-mount
34 semiconductor laser element
36 upper electrode block
40 fourth semiconductor laser module
41 lower electrode block
43 sub-mount
44 semiconductor laser element
46 upper electrode block
46
c recessed portion
51 to 53 bus bar
60, 70 heat dissipation block
61, 71 lower heat dissipation block
62, 72 insulating sealant
62
a,
62
b opening
63
a,
73
a first upper heat dissipation block
63
b second upper heat dissipation block
64 screw hole
65 groove
66, 76 flow path
66
a,
76
a inflow port
66
b,
76
b discharge port
80 additional heat dissipation block
81 lower heat dissipation block
82 insulating sealant
82
a to 82c opening
83
a third upper heat dissipation block
83
b fourth upper heat dissipation block
83
c fifth upper heat dissipation block
90, 90a module fixing screw
91 terminal fixing screw
100, 200, 300, 400 semiconductor laser device
| Number | Date | Country | Kind |
|---|---|---|---|
| 2018-097377 | May 2018 | JP | national |
This application is a continuation of the PCT International Application No. PCT/JP2019/010978 filed on Mar. 15, 2019, which claim the benefit of foreign priority of Japanese patent application No. 2018-097377 filed on May 21, 2018, the contents all of which are incorporated herein by reference.
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/JP2019/010978 | Mar 2019 | US |
| Child | 17092785 | US |
