JP6351090B2 - Light source unit, illumination optical system using light source unit - Google Patents

Description

  The present invention relates to a light source unit on which a plurality of semiconductor laser elements are mounted, and more particularly to a light source unit used in an illumination optical system.

  In recent years, semiconductor lasers that emit laser light in the red band, the green band, and the blue band have been developed and are being put to practical use. If a semiconductor laser can be used as a light source, it can be expected to reduce power consumption, extend the life, and reduce the size as compared with a conventional discharge lamp light source.

  Patent Document 1 discloses a light source device that includes a reflection unit that reflects light from first and second solid-state light source units that are opposed to each other, and a fluorescent light-emitting plate that is excited by the light of the reflection unit. Patent Document 2 discloses an illumination device in which light emitting element units each having a laser diode arranged in an array are arranged to face each other, and light from each light emitting element unit is reflected by a reflection mirror.

JP 2012-133337 A JP2012-118129A

  In the light source unit in which laser elements are arrayed, the amount of heat generation increases as the number of elements increases and the output increases, so how to efficiently dissipate this is a problem. In particular, when the light source unit is applied to an illumination optical system, optical components such as a mirror and a lens must be disposed in the vicinity of the semiconductor laser element, and it becomes difficult to secure a sufficient space for heat dissipation. On the other hand, if such a space is to be secured, it becomes difficult to make the light source unit thinner and smaller.

  An object of this invention is to provide the light source unit which improved heat dissipation efficiency, aiming at size reduction and thickness reduction, and an illumination optical system using the same.

  The light source unit according to the present invention includes an aligning unit that aligns the plurality of semiconductor laser elements in the first linear direction, and each of the laser beams emitted from the plurality of semiconductor laser elements is incident and reflected in the second direction. It has a plurality of reflecting members and a heat radiating member thermally coupled to the alignment means, and the heat radiating members are present on at least a region where the plurality of reflecting members are arranged.

  In a preferred aspect, the heat radiating member includes a pair of two-dimensionally extending metal members, and the alignment means and the reflecting member are disposed between the pair of metal members. Preferably, the metal member includes a plurality of heat radiation fins including a flat surface and projecting vertically from the flat surface. Preferably, the metal member includes a flat surface and has a plurality of heat radiation fins parallel to the flat surface. Preferably, the end of the flat surface is inclined at a first angle, the ends of the plurality of heat radiation fins are inclined at a second angle, and the ends of the flat surface and the ends of the plurality of fins Intersect. Preferably, the sum of the first angle and the second angle is 90 degrees. Preferably, the combination of the alignment means, the reflecting member and the heat radiating member has a substantially rectangular outer shape. Preferably, the alignment means includes a metal fixing member formed with a recess for accommodating a plurality of semiconductor laser elements. Preferably, the fixing member includes a plurality of collimating lenses for collimating light from the plurality of semiconductor laser elements. Preferably, the fixing member includes positioning means for positioning at least one of the semiconductor laser element and the collimating lens. Preferably, the alignment means aligns the plurality of semiconductor laser elements on opposite sides. Preferably, the light source unit array is configured by stacking a plurality of light source units. Preferably, the end of the flat surface of one light source unit is in contact with the end of the heat sink fin of the other light source unit, and the end of the heat sink fin of one light source unit is the flat surface of the other light source unit. The two light source units are joined in the horizontal direction by abutting against the end portions. Preferably, the light source unit array further includes a cooling device for cooling the heat radiating member.

  According to the present invention, since the heat dissipating member is formed on the region where the reflecting member is disposed, the heat generated by the aligning means can be effectively dissipated using the space on the reflecting member, At the same time, the light source unit can be reduced in thickness and size.

It is an external appearance perspective view of the light source unit array which concerns on the Example of this invention. It is a schematic sectional drawing of the light source unit which concerns on the 1st Example of this invention. It is a perspective view of the metal member used for the light source unit which concerns on the 1st Example of this invention. It is a perspective view of the fixing member concerning the 1st example of the present invention. It is a perspective view which shows an example of the semiconductor laser element used for the 1st Example of this invention. In the 1st Example of this invention, it is a typical schematic top view explaining a state when a fixing member is attached to the metal member. It is a figure which shows an example of the positioning member which fixes a collimator lens. It is a schematic sectional drawing of the light source unit which concerns on the 2nd Example of this invention. It is a schematic sectional drawing of the light source unit which concerns on the 3rd Example of this invention. In the 3rd Example of this invention, it is a typical schematic top view explaining a state when a fixing member is attached to the metal member. It is a schematic sectional drawing of the light source unit which concerns on the 4th Example of this invention. In the 5th Example of this invention, it is a typical schematic top view explaining a state when a fixing member is attached to the metal member. It is a figure which shows the other structural example of the fixing member which concerns on the Example of this invention. It is the top view and side view of a light source unit which concern on the 6th Example of this invention. It is a figure which shows the structural example of the other reflective mirror which can be used for the light source unit of the Example of this invention. It is a figure explaining the example of attachment of the reflective mirror by the Example of this invention. It is a perspective view which shows the light source unit which concerns on the 7th Example of this invention. It is a perspective view which shows the light source unit array comprised combining the light source unit which concerns on the 7th Example of this invention.

  Next, embodiments of the present invention will be described in detail with reference to the drawings. In a preferred aspect of the present invention, the light source unit is configured by mounting a plurality of semiconductor laser elements. The semiconductor laser element may be in any of a red band, a green band, and a blue band. In a preferred embodiment, the semiconductor laser element emits a blue band laser beam. The semiconductor laser element may be any type of a surface emitting semiconductor laser element and an edge emitting laser element. In a further preferred aspect, the light source unit is used as a light source of an illumination optical system such as a projector, an endoscope, or an illumination device. It should be noted that the scale of the drawings is emphasized for easy understanding of the features of the invention and is not necessarily the same as the scale of an actual device.

  FIG. 1 is an external perspective view of a light source unit array according to an embodiment of the present invention. The light source unit array 10 of this embodiment is composed of a single light source unit or a plurality of light source units. The light source unit array 10 shown in the figure is composed of four light source units 10-1 to 10-4. One light source unit has a substantially rectangular shape including a plurality of semiconductor laser elements arranged in a line and a reflection mirror that reflects light emitted from the plurality of semiconductor laser elements, and one side surface thereof. The laser beam is configured to be emitted from the opening 12. In a preferred example, in one light source unit, a plurality of semiconductor laser elements are arranged in the Y direction, and the number of reflection mirrors 14 corresponding to the number of semiconductor laser elements is reflected in the Y direction. Laser light is output to the outside from the opening 12 on the side surface of the light source unit.

  One light source unit is assembled in a rectangular shape for thinning and miniaturization, and is made of a material having high thermal conductivity, for example, metal. The light source unit array 10 is configured by stacking an arbitrary number of light source units in the Z direction. For example, when m semiconductor laser elements are mounted in one light source unit and n light source units are stacked, one light source unit array 10 constitutes an array light source having m × n semiconductor laser elements. To do.

  Next, a detailed configuration of the light source unit will be described. FIG. 2 is a schematic sectional view in the X direction of the light source unit according to the first embodiment. The light source unit 100 according to the first embodiment includes a pair of plate-like metal members 110, a fixing member 120 that fixes a plurality of semiconductor laser elements, and a plurality of reflection mirrors 130 that are sandwiched between the pair of metal members 110. And have.

  FIG. 3A is a perspective view of the front side of the metal member, and FIG. 3B is a perspective view of the back side of the metal member. The metal member 110 is made of a metal having high thermal conductivity such as aluminum or copper. The metal member 110 has a substantially rectangular shape, and has a first flat surface 112 and a second flat surface 114 connected from the first flat surface 112 via a step 113. On the back surface 114A of the second flat surface 114, a plurality of heat radiating fins 116 projecting vertically therefrom are formed. The height of the back surface 112 </ b> A of the first flat surface 112 is substantially equal to the height of the plurality of radiating fins 116.

  The pair of metal members 110 are preferably the same, and such a pair of metal members 110 is configured such that one first and second flat surfaces 112 and 114 are the other first and second flat surfaces. 112 and 114 are arranged to face each other in parallel, the plurality of reflecting mirrors 130 are arranged between the second flat surfaces 114, and the fixing member 120 is arranged between the first flat surfaces 112. . The fixing member 120 fixes a plurality of semiconductor laser elements 200 linearly aligned inside and a plurality of collimator lenses 240 aligned so as to coincide with the optical axis of each semiconductor laser element 200 as will be described later. . Laser light emitted from the semiconductor laser element 200 is collected by the collimator lens 240, and the collected light is reflected by the reflection mirror 130 and emitted from the gap between the pair of metal members 110 to the outside.

  4A is an external perspective view of the fixing member, and FIG. 4B is a rear view of the fixing member. As shown in FIG. 4A, the fixing member 120 is a substantially rectangular hollow metal material having a length L in the X direction, a width W in the Y direction, and a height H in the Z direction (for example, aluminum or copper). Consists of A number of openings 124 corresponding to the number of semiconductor laser elements 200 to be fixed therein are formed in the upper surface 122 of the fixing member 120. The opening 124 has a rectangular shape, for example. The semiconductor laser element 200 and the collimating lens 240 are inserted into the fixing member 120 through the opening 124, where fixing and final position adjustment are performed. A plurality of circular emission windows 128 are formed on the front side surface 126 of the fixing member 120. Each emission window 128 allows light emitted from the semiconductor laser element 200 to pass toward the reflection mirror 130.

  The length and width of the first flat surface 112 of the metal member 110 are substantially equal to the length L and width W of the fixing member 120, and the height of the step 113 is ½ of the height H of the fixing member 120. Somewhat smaller than. The fixing member 120 is positioned by bringing the front side surface 126 of the fixing member 120 into contact with the step 113. When the fixing member 120 is sandwiched between the first flat surfaces 112 of the pair of metal members 110, a space S is formed between the pair of second flat surfaces 114. The height of the space S in the Z direction is substantially equal to the height of the reflecting mirror 130 and is somewhat larger than the diameter of the exit window 128 of the front side surface 126 of the fixing member 120.

  FIG. 5A shows a configuration example of the semiconductor laser element. In the semiconductor laser element 200, a semiconductor chip (not shown) is mounted on a disk-shaped metal stem 210, and a cup-shaped housing 220 is attached on the stem 210. A transmission window capable of transmitting laser light is formed on the top of the housing 220. In addition, two lead terminals 230 are extended from the stem 210, and the lead terminals 230 are electrically connected to the semiconductor chip within the housing. When a drive current is supplied to the lead terminal 230, a blue band laser beam is emitted along the optical axis C from the top of the housing. The configuration of such a semiconductor laser element is an example, and it is needless to say that other configurations may be used. For example, the semiconductor laser element can include a light receiving element for monitoring the output, in which case three lead terminals extend to the outside.

  In a preferred embodiment, when the far-field image P (FFP) from the semiconductor laser element is elliptical as shown in FIG. 5B, the orientation of the semiconductor laser element is such that the minor axis coincides with the Z direction. Aligned. Thereby, the Z direction of the reflective mirror 130 can be made small, and as a result, the thinning of the light source unit is further improved.

  As shown in FIGS. 2 and 4B, a cylindrical recess 129 that accommodates the disc-shaped stem 210 of the semiconductor laser element 200 is formed behind the fixing member 120. The outer diameter of the recess 129 is somewhat larger than the outer diameter of the stem 210. Further, a through-hole penetrating the rear side surface 126A is formed on the bottom surface of the recess 129. Thus, the stem 210 of the semiconductor laser element 200 inserted from the opening 124 is accommodated in the recess 129, the lead terminal 230 is inserted into the through hole, and the REIT terminal 230 protrudes from the rear side surface 126A. Since the bottom and side surfaces of the metal stem 210 are in contact with the recess 129, the heat generated in the semiconductor laser element 200 is suitably conducted to the fixing member 120.

  In a preferred embodiment, an annular or C-shaped ring member 129A is inserted into the recess 129 in order to fix or position the semiconductor laser element 200. The ring member 129A is made of, for example, a member having good thermal conductivity or an elastic member such as rubber. When the stem 210 is accommodated in the recess 120, the ring member 129A is inserted into the circumferential gap between the housing 220 and the recess 129. The semiconductor laser element is fixed. The ring member 129A may be inserted into the gap together with the adhesive. Such a positioning and fixing method is an example, and other positioning or fixing methods may be used.

  As shown in FIG. 4C, the fixing member 120 is composed of a plurality of fixing members 120-1 to 120-n, and one fixing member accommodates one semiconductor laser element and one collimating lens. It may be a thing. In this case, each fixing member 120-1 to 120-n is connected using a fastening member (not shown) such as a connecting screw.

  FIG. 6 is a plan view when the fixing member is mounted on the first flat surface of one metal member and the reflection mirror is mounted on the second flat surface. In the drawing, as an example, an example in which three semiconductor laser elements 200 are mounted is shown. The semiconductor laser element 200 is inserted into the fixing member 120 through the opening 124, the stem 210 is accommodated in the recess 129, and the lead terminal 230 protrudes from the rear side surface 126A. As described above, the stem 210 is fitted or inserted into the recess 129, and when the diameter of the recess 129 is somewhat larger than the diameter of the stem 210, the semiconductor laser device 200 is finely adjusted in the X, Y, and Z directions. Can be done. The position of the semiconductor laser element is held by a jig or the like (not shown), and in this state, the recess 129 is filled with an ultraviolet curable resin or the like, and the semiconductor laser element is positioned by irradiating ultraviolet rays. Alternatively, the ring member 129 may be inserted so as to press the stem 210 and filled with an ultraviolet curable resin or the like. Thus, the plurality of semiconductor laser elements 200 are aligned along the Y direction of the fixing member 120.

  Further, the collimator lens 240 is inserted through the opening 124 of the fixing member 120 and fixed or positioned so as to be aligned with the optical axis C of the semiconductor laser element 200. In a preferred embodiment, the collimating lens 240 is fixed by a positioning member 250 as shown in FIG. The positioning member 250 has a support portion 254 whose bottom portion 252 is fixed to the fixing member 120 and extends from the bottom portion 252 in a semicircular shape. The support portion 254 supports the outer periphery of the collimator lens 240, but the curvature of the support portion 254 is smaller than the curvature of the collimator lens 240 (so that the support portion 254 becomes a hole for the collimator lens). Is formed. Further, the axial width of the support portion 254 is formed to be sufficiently smaller than the axial thickness of the collimating lens 240. When the collimator lens 240 is placed on the support portion 254, minute angles in the X, Y, and Z directions of the collimator lens 240 can be changed.

  For example, the position of the collimator lens 240 is determined using a jig (not shown) in a state where the laser light from the semiconductor laser element is projected onto a screen or the like via the reflection mirror 130, and in this state, for example, an ultraviolet curable resin Is filled in the gap between the support portion 254 and the collimating lens 240, and then the position of the collimating lens 240 is fixed by irradiating ultraviolet rays. Such a positioning method is an example, and for example, the fine adjustment and fixing of the collimating lens may be performed using a member such as a screw. Thus, the laser light emitted from the semiconductor laser element 200 is collimated by the collimating lens 240 and guided to the reflection mirror 130.

  The reflection mirror 130 is mounted on the second flat surface 114 of the metal member 110. For example, a groove for positioning the reflection mirror 130 is formed on the second flat surface 114, and the end surface of the reflection mirror 130 is fitted into the groove or fixed by an adhesive or the like. The laser light emitted from the semiconductor laser element 200 is reflected in the X direction by the reflection mirror 130 and is output to the outside from the space S between the pair of metal members 110.

  Referring to FIG. 2 again, the fixing member 120 in which the semiconductor laser element 200 and the collimating lens 240 are aligned is sandwiched between the pair of metal members 110, and the laser light emitted from the fixing member 120. Is reflected in the Y direction. The pair of metal members 110 are fixed to the upper and lower surfaces of the fixing member 120 by screws or the like (not shown).

  The heat generated in the semiconductor laser element 200 is efficiently conducted to the fixing member 120 through the metal stem 210. Furthermore, since the upper surface 122 of the fixing member 120 and the lower surface opposite thereto are brought into surface contact with the first flat surface 112, the heat of the fixing member 120 is effectively conducted to the metal member 110. Further, the heat conducted to the metal member 110 is further released to the outside by a plurality of heat radiating fins 116 formed on the second flat surface 114.

  Since the second flat surface 114 is connected to the first flat surface 112 via the step 113, the second flat surface 114 on the side opposite to the reflection mirror 130 is utilized using the height of the step 113 in the Z direction. A plurality of radiating fins 116 are formed on the flat surface 114, and the height of the radiating fins 116 and the height of the first flat surface 112 can be made uniform.

  One light source unit is provided with a plurality of reflection mirrors 130 in which a plurality of semiconductor laser elements 200 are arranged in the Y direction and the laser light is reflected in the X direction. As shown in FIG. 2, the fins 116 are formed, and as a result, the back surface 112A of the first flat surface 112 and the tips of the radiation fins 116 form substantially the same height or the same surface. It should be noted that a plurality of semiconductor laser elements 200 and a plurality of optical components (reflecting mirrors 130) are integrated, and the light source unit can be thinned and miniaturized while having a cooling structure using heat radiation fins. . Furthermore, when the light source unit 100 as shown in FIG. 2 is laminated in the Z direction as shown in FIG. 1, the array light source unit is excellent in heat dissipation characteristics because the light source units are thermally coupled in close contact with each other. Can be provided.

  Next, a second embodiment of the present invention will be described. FIG. 8 is a schematic cross-sectional view of the light source unit 100A according to the second embodiment. The same reference numerals are given to the same components as those in the first embodiment, and the description thereof is omitted. The second embodiment differs from the first embodiment in that the plurality of heat radiation fins 116A extend from the step 113 so as to be parallel to the second flat surface 114. Preferably, the size of the XY plane of the radiation fin 116A is the same as that of the second flat surface 114.

  In the example shown in FIG. 8A, the radiating fin 116A is integrally formed with the metal member 110 and extends from the step 113 in the X direction. When the interval between the plurality of heat dissipating fins 116A is reduced or the distance in the X direction is increased, it is difficult to integrally form the mold. Therefore, as shown in FIG. 8B, the plurality of heat radiation fins 116 </ b> A may be configured separately from the metal member 110. In this case, the plurality of radiating fins 116A are held by a connecting member 117 such as aluminum so that the distance between them is parallel, and the connecting member 117 is fixed on the second flat surface by a fastening member such as a screw. May be. Further, as shown in FIG. 8C, the fixing member 120 may be integrated with one of the metal members 110A. As a result, the heat conduction efficiency is increased and the heat dissipation efficiency is further improved. In this case, the upper portion P extending from the opening of the fixing member 120 to the exit window does not necessarily have to be integrated with the metal member 110A. If necessary, the upper portion P may be integrated with the upper metal member 110.

  Next, a third embodiment of the present invention will be described. FIG. 9 is a schematic cross-sectional view of a light source unit 100B according to the third embodiment. In the first embodiment, the fixing member 120 is attached to one side of the metal member 110 in the Y direction, whereas in the third embodiment, the fixing member 120 is attached to both sides of the metal member 110 in the Y direction. It is done. In this case, the metal member 110 is symmetrical with respect to the center line, that is, the two first flat surfaces 112 are formed on both sides of the second flat surface 114 via the step 113, The fixing members 120 are sandwiched between the first flat surfaces 112, respectively. The reflection mirror 130 is configured as a double-sided mirror that reflects the laser light emitted from the fixing members 120 on both sides.

  FIG. 10A is a schematic plan view for explaining a state when the fixing member 120 is attached to both sides of the metal member 110. Laser light emitted from the semiconductor laser element 200 of the fixing member 120 attached on the left side as viewed in the drawing is reflected in the Y direction by one surface of each reflecting mirror 130A, and is emitted from one side of the light source unit 100B. A bundle L1 is output. Laser light emitted from the semiconductor laser element 200 of the fixing member 120 attached on the right side in the drawing is reflected in the −Y direction by the other surface of each reflecting mirror 130A, and is emitted from the other side of the light source unit. A bundle L2 is output. The light bundles L1 and L2 can be combined using a desired optical system. As described above, according to the third embodiment, it is possible to increase the output of the light source unit 100B by attaching the fixing members on both sides.

  Further, as shown in FIG. 10B, the laser beam from the semiconductor laser element of the fixing member 120 attached on the right side may be reflected in the same direction by using the reflection mirror 130A.

  Next, a fourth embodiment of the present invention will be described. FIG. 11 is a schematic cross-sectional view of a light source unit 100C according to the fourth embodiment. In the fourth embodiment, the radiation fins 260 are attached to the outside of the light source unit. In the illustrated example, when the fixing members 120 are attached to both sides as in the third embodiment, the metal radiating fins 260 are coupled so as to be thermally coupled to the fixing members 120 on both sides. The height of the radiating fins 260 in the Z direction is substantially equal to the height of the pair of metal members 110 in the Z direction so that the plurality of light source units 100C are not obstructed when stacked in the Z direction. According to the light source unit 100C of the fourth embodiment, the heat radiation fin 260 is thermally coupled to the fixing member 120, so that the heat of the semiconductor laser element can be effectively released to the outside. Such an external heat radiation fin can also be applied to other embodiments.

  Next, a fifth embodiment of the present invention will be described. FIG. 12 is a schematic schematic plan view of a light source unit 100D according to the fifth embodiment. In the fifth embodiment, two light source units 100D as shown in FIG. 12 are combined to form a light source unit 100B as in the third embodiment. In a preferred embodiment, the metal member 110 has an end portion 270 that is inclined at, for example, 45 degrees along the arrangement direction of the reflection mirrors 130. By combining the end portions 270 of the light source unit 100D having such a configuration, it is possible to obtain a light source unit that outputs a light beam from two directions as in the third embodiment. It is of course possible to use the light source unit 100D of the fifth embodiment alone, and in this case, the size in the XY direction can be reduced as compared with the light source unit 100 of the first embodiment.

  FIGS. 12B, 12C, and 12D are enlarged views of part B, and show other examples of positioning of the collimating lens. As shown in FIG. 12B, a step 124 </ b> A that engages with the end 242 of the collimating lens 240 is formed inside the fixing member 120. The diameter of the step 124A is somewhat larger than the outer diameter of the collimating lens 240, and is fixed to the fixing member 120 using an adhesive or an ultraviolet curable resin when the collimating lens 240 is finely adjusted. Further, as shown in FIG. 12C, a step 124B corresponding to the axial length of the collimating lens 240 may be formed.

  12B and 12C, the semiconductor laser element 200 and the collimating lens 240 are attached from the opening 124 on the upper surface of the fixing member 120. In FIG. 12D, the collimating lens 240 is attached to the fixing member 120. It is attached from the front side. As shown in the figure, the opening 124 is formed so as to communicate with the exit window 128 formed on the front side surface of the fixing member 120. Preferably, the diameter in the fixing member 120 formed by the opening 124 is substantially equal to the outer diameter of the collimating lens 240, and the collimating lens 240 is inserted into the fixing member 120 from the exit window 128. The diameter in the fixing member 120 formed by the opening 124 may be formed larger than the outer diameter of the collimating lens 240. In this case, the optical axis of the collimating lens 240 can be finely adjusted in the X, Y, and Z directions. The collimating lens 240 is fixed with an adhesive or an ultraviolet curable resin.

  12A is a diagram showing the embodiment of FIG. 12D in more detail, FIG. 12A is a front view of the fixing member, and FIG. 12B is a perspective view thereof. The fixing member 120 </ b> A has an emission window 128 formed on the front side surface 126, and an opening 124 is formed on the upper surface 122 so that the emission window 128 is continuous. The diameter of the circular groove formed inside by the opening 124 is equal to the diameter of the exit window 128. The groove formed through the opening 124 is connected to a circular recess 129 for housing the semiconductor laser element. In this example, the diameter of the groove formed through the opening 124 is somewhat larger than the diameter of the recess 129. Preferably, the diameter of the collimating lens 240 is equal to the diameter of the groove formed through the exit window 128 or the opening 124, and the collimate lens 240 is inserted into the interior from the exit window 128. The semiconductor laser element is inserted into the recess 129 through the emission window 128 or the opening 124. Thereafter, fine adjustment of the optical axes of the semiconductor laser element and the collimating lens 240 in the X, Y, and Z directions is performed using a jig or the like through the opening 124, and finally an adhesive, an ultraviolet curable resin, a screw, or the like. The fixing means is used for positioning and fixing. As described above, since the semiconductor laser element, the collimating lens, and the reflection mirror are unitized on the plane, the optical axis of the lens can be adjusted in each of the X, Y, and Z axes through the opening 124 of the upper surface 122. Moreover, since the reflecting member can be adjusted, the assembly can be performed accurately and easily.

  Next, a sixth embodiment of the present invention will be described. FIG. 13A is a schematic plan view of a light source unit 100D according to the sixth embodiment, and FIG. 13B is a front view thereof. In the sixth embodiment, the light source unit 100E includes the blower 300. As shown in FIG. 13, when the light source unit 100E is configured by stacking four light source units 10-1 to 10-4, the blower device 300 is attached to one side portion. The air blower 300 further improves the cooling efficiency by forcibly sucking air or exhausting air to the heat radiation fins 116 / 116A formed on the upper and lower surfaces of the light source units 10-1 to 10-4. . The blower 300 is configured using, for example, an axial fan or a sirocco fan. In the example of FIG. 13, since the light beam L1 is output from one side portion of the light source unit 100E, the air blower 300 is attached at a position where it does not become an obstacle. If one light source unit 10-1 includes the radiation fins 116 (FIGS. 2 and 3) as in the first embodiment, the air is blown in the direction (Y direction) in which the radiation fins 116 extend. It is desirable to install the device 300 and allow air to pass through the gaps of the heat dissipating fins 116.

  In the above-described embodiment, an example in which a plurality of reflection mirrors are attached has been described. However, the reflection mirror may have an integrated configuration. For example, as shown in FIG. 14, the reflection mirror 130 has an integral configuration having a plurality of reflection surfaces 130-1, 130-2, 130-3, and 130-4 according to the number of the semiconductor laser elements 200. There may be.

  FIGS. 15A and 15B are diagrams showing another example of attachment of the reflection mirror. As shown in the figure, a positioning groove 132 having a slight depth for positioning the reflecting mirror is formed on the second flat surface 114 of one metal member 110. The end of the reflecting mirror is positioned in the groove 132 and fixed there by an adhesive. Furthermore, as shown in the figure, by forming the grooves 132 in a two-dimensional array, it is possible to select any groove and attach the reflecting mirror. In another preferred example, as shown in FIG. 15B, the reflection mirror 130 may be integrally formed on the second flat surface 114 of the metal member 110.

  Next, a seventh embodiment of the present invention will be described with reference to FIG. Whereas the metal member 110 of the above embodiment has a first flat surface and a second flat surface through the step 113, in the light source unit 100F according to the seventh embodiment, the metal member is flat. A flat surface 400, a plurality of heat radiation fins 410 formed on the flat surface 400, and a connection portion 420 that connects the plurality of heat radiation fins 410 in the Z direction at the ends of the flat surface 400. . The open end 402 of the flat surface 400 extends in an oblique direction so as to have an angle θ1 with respect to the X direction, and the open end 412 of the radiating fin 410 extends in an oblique direction so as to have an angle θ2 with respect to the X direction. Exists. The open end 402 and the open end 412 are just in a crossing relationship, and preferably θ1 = θ2. Or you may make it become the relationship of (theta) 1+ (theta) 2 = 90.

  By stacking such a pair of metal members, one light source unit 100F shown in FIG. 16 is configured. The two light source units 100F are combined in a nested manner so as to face each other, that is, the open end 402 of the flat surface 400 of one light source unit 100F abuts on the open end 412 of the radiation fin 410 of the other light source unit 100F. Is done. The height in the Z direction of the flat surface 400 when the pair of metal members are laminated is approximately equal to or slightly larger than the height in the Z direction of the heat radiation fin 410.

  A light source unit array 10A thus configured is shown in FIG. The open end 402 of the flat surface 400 is tightly joined to the open end 412 of the heat radiating fin 410 to form a rectangular light source unit array 10A as a whole. In this case, one of the light source units constituting the uppermost stage and the lowermost stage does not necessarily require the heat radiating fins 310, and a flat surface 430 may be provided on the upper surface and the bottom surface. L in the figure indicates the direction in which the laser light is emitted. Such a light source unit array 10A is coupled to the cooling device 300 as shown in FIG. 13, and intake air or exhaust air from the cooling device 300 passes between the heat radiation fins, so that the array 10A can be efficiently cooled. .

  The light source unit of the present invention can be used as a light source for various electronic devices such as projectors. In a preferred example, the laser beam bundle emitted from the light source unit can be used for the illumination optical system of the projector. For example, the laser beam bundle emitted from the light source unit is applied to the optical modulation device via a lens, a mirror, a prism, or the like. If necessary, the laser beam bundle may be converted to a desired wavelength using a phosphor or the like. For example, a rotating wheel coated with a phosphor layer may be irradiated with a laser beam of a blue band to generate a wavelength-converted yellow, green, or red band light.

  The preferred embodiments of the present invention have been described in detail above. However, the present invention is not limited to specific examples, and a plurality of examples are appropriately combined from the first to seventh examples. It may be. The present invention can be variously modified and changed within the scope of the gist of the present invention described in the claims.

10: Light source unit arrays 100, 100A, 100B, 100C, 100D, 100E, 100F: Light source units 10-1 to 10-4: Light source units (light source units)
110: metal member 112: first flat surface 113: step 114: second flat surface 116, 116A: radiating fin 120: fixing member 122: upper surface 124: opening 126: front side 128: exit window 128A : Fixing hole 129: Recess 130: Reflection mirror 132: Groove 200: Semiconductor laser element 210: Stem 220: Housing 230 Lead terminal 240: Collimating lens 250: Positioning member 260: External radiation fin 270: End 300: Blower 400 : Flat surface 402, 412: Open end 410: Radiating fin 420: Connection part

Claims (5)

Alignment means for aligning a plurality of semiconductor laser elements in a first linear direction;
A plurality of reflecting members that enter each of the laser beams emitted from the plurality of semiconductor laser elements and reflect in the second direction;
A heat dissipation member thermally coupled to the alignment means;
The heat dissipating member includes a pair of two-dimensionally extending metal members, the alignment means and the reflecting member are disposed between the pair of metal members, and the heat dissipating member is on an area where at least a plurality of reflecting members are disposed. Exists in
The metal member includes a flat surface, and a plurality of radiating fins are formed on a back surface of the flat surface, and an end of the flat surface is inclined at a first angle, and ends of the radiating fins The light source unit is inclined at a second angle, and an end of the flat surface and an end of the plurality of fins intersect. Alignment means for aligning a plurality of semiconductor laser elements in a first linear direction;
A plurality of reflecting members that enter each of the laser beams emitted from the plurality of semiconductor laser elements and reflect in the second direction;
A heat dissipation member thermally coupled to the alignment means;
The heat dissipating member includes a pair of two-dimensionally extending metal members, the alignment means and the reflecting member are disposed between the pair of metal members, and the heat dissipating member is on an area where at least a plurality of reflecting members are disposed. Exists in
The alignment means includes a metal fixing member having recesses for accommodating a plurality of semiconductor laser elements, and the fixing member includes a plurality of lenses for collimating light from the plurality of semiconductor laser elements. And the fixing member includes a positioning unit that positions at least one of the semiconductor laser element and the lens. The metal member includes a flat surface, and a plurality of radiating fins are formed on a back surface of the flat surface, and an end of the flat surface is inclined at a first angle, and ends of the radiating fins The light source unit according to claim 2 , wherein the portion is inclined at a second angle, and an end of the flat surface and an end of the plurality of fins intersect . A plurality of light source units according to claim 1 are included, the end of the flat surface of one light source unit is brought into contact with the end of the radiation fin of the other light source unit, and the end of the radiation fin of one light source unit is A light source unit array in contact with an end of a flat surface of the other light source unit and two light source units coupled in the horizontal direction. Alignment means for aligning a plurality of semiconductor laser elements in a first linear direction;
A plurality of reflecting members that enter each of the laser beams emitted from the plurality of semiconductor laser elements and reflect in the second direction;
Including at least a pair of identically shaped metal members that expand two-dimensionally,
The metal member includes a first flat surface and a second flat surface formed from the first flat surface through a step, and a heat radiating fin is provided on a back surface of the second flat surface. Is substantially equal to the height of the back surface of the first flat surface and the end of the heat radiation fin protruding from the back surface of the second flat surface,
When the pair of metal members are disposed to face each other, the alignment member is disposed between the first flat surfaces, and the plurality of reflecting members are disposed between the second flat surfaces,
A light source unit array in which a plurality of the pair of metal members can be stacked.

Images