JP6915652B2 - Light emitting element light source module - Google Patents

Description

The present invention relates to a light emitting element light source module including a plurality of light emitting elements such as an LED (light emitting diode) element.

In recent years, the technology for curing an ultraviolet curable resin (UV curing technology) has been used in various fields, specifically, for example, a liquid crystal panel manufacturing process (ODF method), a printed substrate manufacturing process (exposure processing), and printing ink. It is used in the fixing process (drying process) of UV rays. In the ultraviolet irradiation device used in such a UV curing process (ultraviolet curing process), a light emitting element light source module having a light emitting element such as an LED element as a light emitting source is used as a light source. A light emitting element light source module using the LED element as a light emitting source is usually configured by arranging a large number of LED elements at a high density in order to obtain an desired light emitting intensity.

In a light emitting element light source module provided with such a large number of LED elements, each of the large number of LED elements tends to rise in temperature due to its own heat generation or heat reception from the surroundings, resulting in a high temperature of the LED element itself. There is a problem that the luminous efficiency is lowered. Further, since the LED elements have individual differences in temperature characteristics and life characteristics, and in particular, the life characteristics greatly differ depending on the emission wavelength, a particularly large number of LED elements are composed of a plurality of types of LED elements having different emission wavelengths. In this case, there is also a problem that the uniformity of the illuminance distribution may deteriorate over time.
Thus, as a light emitting element light source module provided with a large number of LED elements, a plurality of substrates on which a plurality of LED elements are arranged are joined and arranged on a heat sink, and each of the plurality of heat sinks is joined and arranged. However, there has been proposed a configuration in which the LEDs are interchangeably arranged on a support base made of metal via a spacer made of an insulating material (see Patent Document 1). In this light emitting element light source module, a cooling flow path for circulating a cooling medium is formed inside each heat sink. Further, inside the support base, a cooling medium supply flow path through which the cooling medium supplied to the cooling flow path of the plurality of heat sinks flows, and a discharge flow path through which the cooling medium discharged from the cooling flow path flows are formed. Has been done. Further, the spacer is formed with a cooling medium supply through hole and a cooling medium discharge through hole communicating with each of the cooling flow paths in the plurality of heat sinks and the cooling medium supply flow path and the cooling medium discharge flow path in the support base. Has been done.
According to the light emitting element light source module described in Patent Document 1, a large number of LED elements can be cooled by a heat sink and a cooling medium. Further, by removing the heat sink in which the substrate on which the LED element that needs to be replaced is arranged is joined from the support base and attaching a new heat sink (specifically, the heat sink in which the substrate is joined and arranged). , The LED element can also be replaced.

However, in the light emitting element light source module having such a configuration, the flow path structure of the cooling flow path has not been sufficiently studied, and therefore a large number of LED elements cannot be cooled efficiently and uniformly. There is a problem.

Japanese Unexamined Patent Publication No. 2009-65128

The present invention has been made based on the above circumstances, and an object of the present invention is to provide a light emitting element light source module capable of cooling a plurality of light emitting elements efficiently and with high uniformity. be.

The light emitting element light source module of the present invention includes a light source unit in which a plurality of light emitting elements are arranged on the surface of a heat sink made of a heat conductive material, and a cooling block arranged on the back surface of the heat sink.
A cooling flow path for circulating a cooling medium is formed inside the heat sink.
The cooling medium supply port and the cooling medium discharge port in the cooling flow path are connected to the cooling medium supply flow path and the cooling medium discharge flow path formed in the cooling block, respectively.
The cooling flow paths are continuous with each other and have a plurality of flow path portions adjacent to each other via the heat conductive partition wall portion, and the thickness of the heat conductive partition wall portion is increased via the heat conductive partition wall portion. It is smaller than the flow path width of the cooling flow path so that heat exchange is performed between the cooling media flowing through the adjacent flow path portions, and is configured within the range of 0.5 to 2.5 mm.
The plurality of light emitting elements are arranged at positions directly above the plurality of flow path portions and the heat conductive partition wall portion on the surface of the heat sink.
The cooling block is made of a metal having a smaller thermal conductivity than the thermally conductive material constituting the heat sink.

In the light emitting element light source module of the present invention, the cooling flow path includes a first flow path portion extending along one edge of the light emitting element arrangement region in which the plurality of light emitting elements are arranged, and the first flow path. It is preferable to have a second flow path portion that is continuous with the cooling medium outlet of the portion and extends in the same direction as the first flow path portion via the heat conductive partition wall portion.
In the light emitting element light source module of the present invention having such a configuration, it is preferable that the cooling medium supply port and the cooling medium discharge port are each provided outside the region directly below the light emitting element arrangement region.

In the light emitting element light source module of the present invention, the cooling flow path has a flow path width larger than the flow path height, has a flat cross-sectional shape extending along the surface of the heat sink, and has a flow path width with respect to the flow path height. The ratio of is preferably 1.5 to 3.5.

In the light emitting element light source module of the present invention, when the light source unit is viewed through in a direction perpendicular to the surface of the heat sink, the area occupied by the cooling flow path in the light emitting element arrangement region in which the plurality of light emitting elements are arranged. The area of the portion is preferably 80% or more with respect to the area of the light emitting element arrangement region.

The light emitting element light source module of the present invention includes a plurality of the light source units, and the cooling block is common to these plurality of light source units.
It is preferable that each of the cooling medium supply port and the cooling medium discharge port of the cooling flow path in the plurality of light source units is connected to the common cooling medium supply flow path and the common cooling medium discharge flow path in the cooling block. ..

In the light emitting element light source module of the present invention, the cooling flow path formed inside the heat sink is provided as a plurality of flow path portions in a region directly below the light emitting element arrangement region on the surface of the heat sink in which the plurality of light emitting elements are arranged. Can be of a flow path structure in which the elements are densely arranged. Therefore, since the contact area between the heat sink and the cooling medium can be increased without excessively increasing the flow path width of the cooling flow path, it is possible to cool a plurality of light emitting elements with high efficiency. Moreover, since heat exchange is performed between the cooling media flowing through the flow path portions adjacent to each other, the temperature is made uniform in the plurality of flow path portions, so that a large temperature gradient does not occur in the cooling flow path. ..
Further, in the light emitting element light source module of the present invention, the cooling medium supply flow path through which the cooling medium supplied to the cooling flow path flows, and the cooling medium discharge flow path through which the cooling medium discharged from the cooling flow path flows. , It is formed in a cooling block arranged on the back surface of the heat sink. Therefore, since the temperature of the cooling medium flowing through the cooling medium supply flow path is suppressed from rising due to heat reception from the light emitting element, a large temperature gradient does not occur in the cooling medium supply flow path. Further, it is possible to prevent the temperature of the cooling medium flowing through the cooling flow path from rising due to the heat received from the cooling medium heated by the heat receiving from the light emitting element flowing through the cooling medium discharge flow path. Further, since the cooling block is made of a metal having a lower thermal conductivity than the heat sink, it is possible to suppress heat transfer between the cooling medium supply flow path and the cooling medium discharge flow path. Therefore, it is possible to prevent the temperature of the cooling medium from rising in the cooling medium supply flow path due to heat reception from the cooling medium flowing through the cooling medium discharge flow path and causing a temperature gradient, which is more efficient. A large number of light emitting elements can be cooled.
Therefore, according to the light emitting element light source module of the present invention, a plurality of light emitting elements can be cooled efficiently and with high uniformity.

It is explanatory cross-sectional view which shows an example of the structure of the light emitting element light source module of this invention. It is explanatory drawing which shows the surface (light emitting surface) side of the assembly of the cooling block which constitutes the light emitting element light source module of FIG. 1 and a light source unit. It is explanatory drawing which shows the cross section of the assembly of the cooling block which comprises the light emitting element light source module of FIG. 1 and a light source unit. It is explanatory drawing which shows the heat sink which comprises the light emitting element light source module of FIG.

Hereinafter, embodiments of the present invention will be described.
FIG. 1 is an explanatory cross-sectional view showing an example of the configuration of the light source light source module of the present invention, and FIG. 2 is a surface of an assembly of a cooling block and a light source unit constituting the light source light source module of FIG. FIG. 3 is an explanatory view showing the light emitting surface) side, FIG. 3 is an explanatory view showing a cross section of an assembly of a cooling block and a light source unit constituting the light source light source module of FIG. 1, and FIG. 4 is an explanatory view showing a cross section of the light source unit. It is explanatory drawing which shows the heat sink which comprises the light source light source module.
In the light emitting element light source module 10, the rectangular flat plate-shaped substrate 22 in which a plurality of light emitting elements 21 are arranged on the surface (the lower surface in FIG. 1 and the upper surface in FIG. 3) is the surface of the heat sink 31 having a substantially rectangular flat plate shape. A plurality of (three in the example of the figure) light source units 20 having a configuration located on (the lower surface in FIG. 1 and the upper surface in FIG. 3) are provided. In each of these plurality of light source units 20, a cooling flow path 35 for circulating a cooling medium such as water is formed inside the heat sink 31. Further, the plurality of light source units 20 are formed on the surface of the substantially rectangular flat plate-shaped cooling block 40 (the lower surface in FIG. 1 and the upper surface in FIG. 3) in the longitudinal direction of the cooling block 40 (horizontal direction in FIGS. 2 and 3). ) Are arranged in parallel. Inside the cooling block 40, a cooling medium supply flow path 42 and a cooling medium discharge flow path 44 that communicate with each of the cooling flow paths 35 in the plurality of light source units 20 are formed. Then, the plurality of heat sinks 31 and the cooling block 40 constitute a water cooling structure for cooling a large number of light emitting elements 21 (a plurality of light emitting elements 21 constituting each of the plurality of light source units 20) by a cooling medium. ing.
Further, the plurality of light source units 20 and the cooling block 40 are covered with an aluminum cover member 12 having a substantially rectangular parallelepiped appearance shape. The cover member 12 has a rectangular opening formed in a region of the bottom surface of the cover member 12 (lower surface in FIG. 1) facing a large number of light emitting elements 21, and the opening is a window made of borosilicate glass. It is closed by the member 13. Further, on one side surface of the cover member 12, a power supply unit (not shown) connected to an external power source is provided, and a cooling medium supply opening (not shown) and a cooling medium discharge opening (not shown) are provided. It is formed.
Here, in the cover member 12, the light from the plurality of light emitting elements 21 provided in each of the plurality of substrates 22 to the window member 13, that is, the plurality of substrates 22 on the inner peripheral surface of the cover member 12. The area 12A surrounding the space where the optical path leading to the window member 13 is formed may be mirror-finished from the viewpoint of radiating the light from the light emitting elements 21 from the window member 13 with high efficiency. be. Further, the light emitting element light source module 10 may have a configuration in which light from a plurality of light emitting elements 21 is reflected or refracted by an optical member such as a mirror and a lens in order to obtain a desired illuminance and illuminance distribution. good.
In the example of this figure, the plurality of light emitting elements 21 and the window member 13 are such that most of the light radiated from the plurality of light emitting elements 21 at a radiation angle (half angle) of about 60 ° passes through the window member 13. They are placed as close as possible to each other.

In each of the plurality of light source units 20, a substrate 22 in which a plurality of light emitting elements 21 are arranged on the surface of the heat sink 31 is joined in a state where the back surface of the substrate 22 and the front surface of the heat sink 31 face each other. It is a thing. A bonding layer (not shown) made of a heat conductive bonding material is formed between the heat sink 31 and the substrate 22. As the heat conductive bonding material, for example, a heat conductive adhesive and a heat conductive double-sided adhesive sheet are used.
In the example of this figure, the heat sink 31 is composed of a rectangular flat plate-shaped large diameter portion 31A and a rectangular flat plate-shaped small diameter portion 31B stacked on the large diameter portion 31A. The large diameter portion 31A has a dimension larger than the dimension in the longitudinal direction of the substrate 22 in the longitudinal direction, while the dimension in the lateral direction is slightly smaller than the dimension in the lateral direction of the substrate 22. Have. Further, the small diameter portion 31B has a dimension equivalent to the dimension in the longitudinal direction of the substrate 22 in the longitudinal direction, while the dimension equivalent to the dimension in the lateral direction of the large diameter portion 31A in the lateral direction. have. The small diameter portion 31B is located at the central portion in the longitudinal direction on the surface of the large diameter portion 31A (the lower surface in FIG. 1 and the upper surface in FIG. 3), and both ends in the longitudinal direction on the surface of the large diameter portion 31A. Is in a state where the surface is exposed. In the heat sink 31, the substrate 22 is arranged on the surface of the small diameter portion 31B in a state of covering the surface and having both edges of the substrate 22 in the lateral direction slightly protruding from the heat sink 31. The light source units 20 adjacent to each other are in a state in which the substrates 22 are close to each other and the heat sink 31 is in a slightly separated state.

Further, in the water-cooled structure composed of the plurality of heat sinks 31 and the cooling block 40, a flow path for the cooling medium is formed inside the cooling structure. This flow path has a cooling flow path 35 in the plurality of heat sinks 31, a cooling medium supply flow path 42 in the cooling block 40, and a cooling medium discharge flow path 44.
Further, in the water-cooled structure, a supply unit 17 for supplying a cooling medium to the distribution flow path and a discharge unit 18 for discharging the cooling medium from the distribution flow path are provided on the outer surface of the cooling block 40. The light source unit 20 is provided in an area other than the area where the light source unit 20 is located.
In the example of this figure, the supply unit 17 and the discharge unit 18 are composed of a joint member, and a cooling medium supply opening (not shown) and a cooling medium discharge opening formed in the cover member 12 in the cooling block 40. It is provided on one side surface facing (not shown). Further, the tip portion of the supply unit 17 projects outward from the cooling medium supply opening to the outside of the cover member 12, and the tip portion of the discharge unit 18 projects outward from the cooling medium discharge opening to the outside of the cover member 12. There is.

The water-cooled structure is formed by arranging each of the plurality of light source units 20 in a replaceable manner with the back surface of the heat sink 31 in close contact with the surface of the cooling block 40.
Specifically, each of the plurality of light source units 20 is provided with a plurality of (four in the example of this figure) fixing screws 28 so that the back surface of the heat sink 31 is in close contact with the surface of the cooling block 40. It is fixed to the cooling block 40.
In the water-cooled structure, a supply communication passage 26 extending in the stacking direction of the heat sink 31 and the cooling block 40 is formed between each of the plurality of cooling passages 35 and the cooling medium supply passage 42. , Each of the plurality of cooling flow paths 35 and the cooling medium supply flow path 42 are communicated with each other by these supply communication passages 26. The supply passage 26 is composed of a supply passage hole 26A in the heat sink 31 and a supply passage hole 26B in the cooling block. Further, between each of the plurality of cooling passages 35 and the cooling medium discharge passage 44, discharge passages 27 extending in the stacking direction of the heat sink 31 and the cooling block 40 are formed, and these discharge passages 27 are formed. Each of the plurality of cooling flow paths 35 and the cooling medium discharge flow path 44 are communicated with each other by the passage 27. The discharge passage 27 is composed of a discharge passage hole 27A in the heat sink 31 and a discharge passage hole 27B in the cooling block 40.
Further, between each of the plurality of light source units 20 and the cooling block 40, an annular seal member 29 is arranged so as to surround each of the supply passage 26 and the discharge passage 27.
In this way, the plurality of light source units 20 are interchangeably fixed to the cooling block 40, and the liquidtightness of the supply passage 26 and the discharge passage 27 is realized, so that the water-cooled structure is formed. There is.
In the example of this figure, each of the plurality of light source units 20 is fixed to the cooling block 40 by fixing screws 28 at each of the four corners of the surface of the heat sink 31 (the surface of the large diameter portion 31A). Further, on the surface of the cooling block 40, an annular seal member arranging groove 41 is formed so as to go around the opening communicating with the supply communication passage hole 26B and the opening communicating with the discharge communication passage hole 27B. A seal member 29 made of an O-ring is arranged in the seal member arranging groove 41, and the seal member 29 is sandwiched.

In each of the plurality of light source units 20, a plurality of (160 in the example of the figure) light emitting elements 21 are two-dimensionally arranged at regular intervals on the surface of the substrate 22.
In the example of this figure, the plurality of light emitting elements 21 are arranged in a substantially rectangular light emitting element arrangement region located at the center of the substrate 22 in the longitudinal direction on the surface of the substrate 22 in the lateral direction of the light emitting element arrangement region. Ten pieces are arranged in a staggered pattern in the longitudinal direction (horizontal direction in FIG. 2) and ten pieces in the longitudinal direction (horizontal direction in FIG. 2) of the light emitting element arrangement region. Further, on the surface of the substrate 22, a plurality of (two in the example of the figure) electrical connection portions 23 are arranged at both ends of the substrate 22 in the longitudinal direction. All the light emitting elements 21 on the substrate 22 are electrically connected to the electrical connection portion 23.

As the light emitting element 21, an LED element, an LD (laser diode) element, or the like is used, and specifically, as the LED element, for example, those having peak emission wavelengths of 365 nm, 385 nm, 395 nm, 405 nm, and 450 nm are used.
In the example of this figure, an LED element having a peak emission wavelength of 365 nm is used as the light emitting element 21.

As the base material constituting the substrate 22, an appropriate base material according to the type of the light emitting element 21 and the like is used. Specific examples of the material of the substrate 22 include thermally conductive ceramics such as _{aluminum nitride (AlN) and aluminum oxide (Al 2} O _3).
In the example of this figure, the base material of the substrate 22 is made of aluminum nitride.

In each of the plurality of light source units 20, one cooling flow path 35 is formed inside the heat sink 31.
The cooling flow path 35 is provided parallel to the surface of the heat sink 31 so that the cooling medium can flow along the surface of the heat sink 31, and a cooling medium supply port 35A is formed at one end and the other end. The cooling medium discharge port 35B is formed.
In the cooling flow path 35, the heat of the plurality of light emitting elements 21 is received by the cooling medium via the substrate 22 and the heat sink 31, thereby cooling the light emitting elements 21.

Further, the cooling flow path 35 has a flat cross-sectional shape in which the flow path width is larger than the flow path height and extends along the surface of the heat sink 31. In the cooling flow path 35, the ratio of the flow path width to the flow path height is preferably 1.5 to 3.5 from the viewpoint of cooling efficiency.
In the example of this figure, the cooling flow path 35 has a cross-sectional shape of 5 mm in width (flow path width) and 2.5 mm in height (flow path height), and the ratio of the flow path width to the flow path height. Is a flat rectangular shape of 2.

The cooling flow path 35 is one of the light emitting element arrangement regions in the region directly below the light emitting element arrangement region (hereinafter, also referred to as “light source direct region”) in which the plurality of light emitting elements 21 are located on the surface of the heat sink 31. It is continuous with the first flow path portion extending along the edge and the cooling medium outlet of the first flow path portion, and extends in the same direction as the first flow path portion via the heat conductive partition wall portion 39A. It has a serpentine shape with a second flow path portion.
Specifically, the cooling flow path 35 extends in parallel with the region edges of the region directly under the light source (specifically, the region edges extending in the lateral direction of the heat sink 31) 33A and 33C in the region directly under the light source. It has a plurality of (three in FIG. 4) linear flow path portions (hereinafter, also referred to as "inner linear portions") 36. Here, the "inner linear portion" refers to a linear flow path portion whose entire portion is located in the region directly below the light source. Then, in these plurality of inward linear portions 36, the inward linear portions 36 adjacent to each other via the heat conductive partition wall portion 39A are connected to the cooling medium outlet of one of the inward linear portions 36. The cooling medium inflow port of the other inward linear portion 36 is communicated via a bent flow path portion (hereinafter, also simply referred to as a “bent portion”) 38A so as to be continuous.
In the example of this figure, the inward linear portions 36 located on both ends in the longitudinal direction of the heat sink 31 in the region directly under the light source extend in the lateral direction of the region immediately below the light source (specifically, the heat sink 31). Region edge) It is located slightly inward from 33A and 33C. Further, the bent portion 38A communicating with the inward linear portion 36 adjacent to each other is slightly inside the region edge of the region directly under the light source (specifically, the region edge extending in the longitudinal direction of the heat sink 31) 33B and 33D. It is located on the side.
Further, each of the inward linear portions 36 located on both ends in the longitudinal direction of the heat sink 31 in the region directly under the light source is a straight line partially located outside the region directly under the light source via the bending flow path portion (bending portion) 38B. It communicates with a circular flow path portion (hereinafter, also referred to as an "outer linear portion") 37. These two outer linear portions 37 are arranged in parallel along the inner linear portion 36. The heat conductive partition wall portion 39B located between the outer straight portion 37 and the inner straight portion 36 is located in the region directly below the light source. The cooling medium supply port 35A is formed by the cooling medium inflow port of one outer linear portion 37, and the cooling medium discharge port 35B is formed by the cooling medium outlet of the other outer linear portion 37. Has been done. The flow path lengths of these two outer linear portions 37 are the inner linear portions 36 so that the cooling medium supply port 35A and the cooling medium discharge port 35B are located at the center of the heat sink 31 in the lateral direction, respectively. It is said to be about half the length of the flow path. In this way, the cooling flow path 35 has a meandering shape as a whole.
In FIG. 4, the flow direction of the cooling medium in the cooling flow path 35 is indicated by an arrow. Further, in the figure, the region directly under the light source is a region surrounded by the alternate long and short dash line.

In the cooling flow path 35, the thickness of the heat conductive partition wall portion 39A located between the inward linear portions 36 adjacent to each other is smaller than the flow path width of the cooling flow path 35.
Since the thickness of the heat conductive partition wall portion 39A is smaller than the flow path width of the cooling flow path 35, the inward linear portions 36 adjacent to each other are in a state of being positioned close to each other, and these inward linear portions adjacent to each other are arranged in close proximity to each other. Heat exchange will take place between the cooling media flowing through the portion 36.
The thickness of the heat conductive partition wall portion 39A is preferably less than half the width of the cooling flow path 35 from the viewpoint of heat conductivity (heat diffusion).
In the example of this figure, the thickness of the heat conductive partition wall portion 39B located between the outer linear portion 37 and the inner linear portion 36 adjacent to each other is smaller than the flow path width of the cooling flow path 35. It is set to be less than half the width of the flow path.

Specifically, the thickness of the heat conductive partition wall portion 39A is required to be at least a thickness that can withstand the pressure from the cooling medium flowing through the cooling flow path 35, and further, the material of the heat sink 31 and the thickness of the heat sink 31 It is appropriately determined according to the flow path width of the cooling flow path 35 and in consideration of the type of the light emitting element 21, and is, for example, 0.5 to 2.5 mm.
In the example of this figure, the thickness of the heat conductive partition wall portion 39A is 1 mm. Further, the thickness of the heat conductive partition wall portion 39B located between the outer linear portion 37 and the inner linear portion 36 adjacent to each other is also set to 1 mm.

Further, in the cooling flow path 35, when the light source unit 20 is seen through in the direction perpendicular to the surface of the heat sink 31 (the direction perpendicular to the paper surface in FIG. 2), the cooling in the light emitting element arrangement region (the region directly under the light source). The area of the region portion occupied by the flow path 35 (hereinafter, also referred to as “cooling flow path forming area”) is 80% of the area of the light emitting element arrangement region (hereinafter, also referred to as “light emitting element arrangement area”). The above is preferable.
Since the cooling flow path forming area is 80% or more of the light emitting element arrangement area, specifically, all the light emitting elements on the substrate 22 regardless of the positional relationship between the plurality of light emitting elements 21 and the cooling flow path 35. Even when the 21 is not arranged directly above the cooling flow path 35, all of the light emitting elements 21 can be cooled more efficiently and with higher uniformity.
In the example of this figure, the cooling flow path forming area is 83.3% of the light emitting element arrangement area.

Further, in the cooling flow path having a meandering shape in the region directly under the light source, as shown in FIG. 4, the cooling medium supply port 35A and the cooling medium discharge port 35B are provided outside the region directly under the light source, respectively. Is preferable.
Since the cooling medium supply port 35A and the cooling medium exhaust / discharge port 35B are provided outside the region directly below the light source, it is possible to further achieve temperature uniformity in the plurality of inward linear portions 36. Therefore, the plurality of light emitting elements 21 can be cooled with even higher uniformity.

Further, the cooling flow path 35 is preferably provided at a position level close to the surface of the heat sink 31 from the viewpoint of improving the cooling efficiency by reducing the thermal resistance with the light emitting element 21. ..
In the example of this figure, the cooling flow path 35 has a depth of 2.5 mm from the surface of the heat sink 31 (the surface of the small diameter portion 31B), that is, a distance of 2.5 mm from the surface of the heat sink 31. It is formed to be.

The heat sink 31 is made of a heat conductive material.
Examples of the heat conductive material used for the heat sink 31 include high heat conductive metals such as copper and aluminum.
The thickness of the heat sink 31 is appropriately determined according to the arrangement interval of the plurality of light emitting elements 21, the cross-sectional shape of the cooling flow path 35 (specifically, the flow path height and the flow path width), and the like.

In the heat sink 31 having such a configuration, two substantially rectangular plate-shaped base materials (specifically, a base material for a large diameter portion and a base material for a small diameter portion) made of a heat conductive material are joined by brazing. The cooling flow path 35 is formed by sealing the groove formed on the joint surface of one of the base materials by joining the two base materials.
Specifically, a groove for a cooling flow path is formed on the joint surface of the base material for a small diameter portion. Further, in the large-diameter portion base material, the supply communication passage hole 26A and the discharge communication passage hole 27A are provided in a state where the large-diameter portion base material is joined to the small-diameter portion base material. The hole 26A is formed so as to be located on one end of the cooling flow path groove, and the discharge communication passage hole 27A is located on the other end of the cooling flow path groove. Then, the base material for the small diameter portion and the base material for the large diameter portion are joined by brazing, so that the groove for the cooling flow path in the base material for the small diameter portion is sealed by the base material for the large diameter portion. Therefore, the heat sink 31 in which the cooling flow path 35 is formed is obtained.
Here, the two base materials constituting the heat sink 31 may be made of the same kind of heat conductive material, or may be made of different kinds of heat conductive materials.
In the example of this figure, the base material for the small diameter portion and the base material for the large diameter portion constituting the heat sink 31 are both made of copper.

In the cooling block 40, the cooling medium supply flow path 42 and the cooling medium discharge flow path 44 are provided parallel to the surface of the cooling block 40, and the cooling medium supply flow path 42 is the cooling supplied from the supply unit 17. The medium is circulated toward each of the cooling medium supply ports 35A of the plurality of cooling flow paths 45, while the discharge flow path 44 discharges from each of the cooling medium discharge ports 35B of the plurality of cooling flow paths 45. The cooling medium is circulated toward the discharge unit 18. A supply opening is formed at one end of the cooling medium supply flow path 42, and the supply unit 17 is formed by inserting a joint member into the supply opening. Further, a discharge opening is formed at one end of the cooling medium discharge flow path 44, and a discharge portion 18 is formed by inserting a joint member into the discharge opening.
Further, as in the example of this figure, when the water cooling structure is composed of the cooling block 40 and the plurality of heat sinks 31, that is, when the plurality of cooling flow paths 35 are provided, the plurality of these By connecting the cooling flow path 35 to the common cooling medium supply flow path 42 and the common cooling medium discharge flow path 44, the plurality of cooling flow paths 35 can be connected in parallel.
It is preferable that the cooling medium supply flow path 42 and the cooling medium discharge flow path 44 have the same shape (specifically, the overall shape and the cross-sectional shape) and are provided in parallel.
In the example of this figure, the cooling medium supply flow path 42 and the cooling medium discharge flow path 44 each have a linear shape extending in the longitudinal direction of the cooling block 40, that is, in the direction in which a plurality of light source units 20 are parallel to each other. , The cross-sectional shape is a circular shape with a diameter of 6 mm. Further, the cooling medium supply flow path 42 and the cooling medium discharge flow path 44 are each configured by inserting a sealing member 48 on the other end side of the linear through hole formed in the cooling block 40. There is.

It is preferable that the cooling medium supply flow path 42 and the cooling medium discharge flow path 44 are each provided with a buffer portion 46 from the viewpoint of pressure control of the cooling medium in the flow path.
In the example of this figure, the cooling medium supply flow path 42 and the cooling medium discharge flow path 44 are each provided with a buffer portion 46.

For the cooling block 40, an appropriate metal is used depending on the material of the heat sink 31 from the viewpoint of mechanical strength, electrolytic corrosion resistance, and the like.
Further, it is preferable that the metal constituting the cooling block 40 has a smaller thermal conductivity than the thermally conductive material constituting the heat sink 31.
Since the cooling block 40 is made of a metal having low thermal conductivity, it is possible to suppress heat transfer between the cooling medium supply flow path 42 and the cooling medium discharge flow path 44. Therefore, it is possible to prevent the temperature of the cooling medium from rising in the cooling medium supply flow path 42 due to the heat reception from the cooling medium flowing through the cooling medium discharge flow path 44 and causing a temperature gradient, which is more efficient. A large number of light emitting elements 21 can be cooled.
In the example of this figure, the cooling block 40 is made of stainless steel.

Further, in the light emitting element light source module 10, when the water cooling structure is composed of the cooling block 40 and the plurality of heat sinks 31 as shown in the example of this figure, the cooling medium supplied from the supply unit 17 is discharged. The number of paths leading to the portion 18 is formed by the number of cooling flow paths 35 connected in parallel by the cooling medium supply flow path 42 and the cooling medium discharge flow path 44. Thus, with respect to these a plurality of paths, from the supply opening (supply section 17), which is the most upstream position of the cooling medium supply flow path 42, through the cooling flow path 35, the maximum of the cooling medium discharge flow path 44. It is preferable that the length of the path to the discharge opening (discharge portion 18), which is a downstream position, is the same for each of the plurality of cooling flow paths 35.

By design, the flow path resistances in each path are the same because all the lengths of the paths from the supply opening to the discharge opening through each of the plurality of cooling flow paths 35 are the same. Therefore, the same amount of cooling medium flows into each of the plurality of cooling flow paths 35, that is, the cooling medium supplied to the cooling medium supply flow path 42 via the supply unit 17 is introduced into the plurality of cooling flow paths 45. It can be evenly distributed and flowed into each.

In the light emitting element light source module 10 as described above, in the state where a large number of light emitting elements 21 are emitting light, a cooling medium is supplied to the water-cooled structure from the supply unit 17, and the cooling medium is supplied from the supply unit 17. The cooling medium is distributed and flows into each of the plurality of cooling flow paths 35 via the cooling medium supply path 42 and the supply communication passage 26. Then, after passing through each of the plurality of cooling flow paths 35, the cooling medium is discharged from the discharge unit 17 to the outside of the water-cooled structure via the discharge communication passage 27 and the cooling medium discharge flow path 44. As the cooling medium circulates in the water-cooled structure in this way, the plurality of light emitting elements 21 are cooled by the cooling media flowing through the heat sink 31 and the cooling flow path 35 in each of the plurality of light source units 20. Become.

Thus, in the light emitting element light source module 10, the cooling flow path 35 formed inside the heat sink 31 has a plurality of inward linear portions 36 and a plurality of outward linear portions in the region directly below the light source and the peripheral region thereof. The portions 37 are supposed to have a densely arranged flow path structure. Therefore, since the contact area between the heat sink 31 and the cooling medium can be increased without excessively increasing the flow path width of the cooling flow path 35, the plurality of light emitting elements 21 can be cooled with high efficiency. Further, since heat exchange is performed between the cooling media flowing through the inner linear portion 36 and the outer linear portion 37 adjacent to each other via the heat conductive partition walls 39A and 39B, a plurality of inner sides are exchanged. Since the temperature is made uniform in the linear portion 36 and the plurality of outer linear portions 37, a large temperature gradient does not occur in the cooling flow path 35.
Further, in the light emitting element light source module 10 of the present invention, the cooling medium supply flow path 42 and the cooling medium discharge flow path 44 are formed in the cooling block 40. Therefore, since the temperature of the cooling medium flowing through the cooling medium supply flow path 42 is suppressed from rising due to heat reception from the light emitting element 21, a large temperature gradient does not occur in the cooling medium supply flow path 42. Further, it is possible to prevent the temperature of the cooling medium flowing through the cooling flow path from rising due to the heat received from the cooling medium heated by the heat receiving from the light emitting element 21 flowing through the cooling medium discharge flow path 44.
Therefore, according to the light emitting element light source module 10, even when all of the large number of light emitting elements 21 are not arranged at positions directly above the cooling flow path 35, the large number of light emitting elements 21 can be efficiently and highly uniform. It can be cooled with sex.
Here, according to the light emitting element light source module 10 of the example of this figure, as is clear from the experimental example described later, the surface temperature of the substrate 21 is set within the temperature range of ± 3 ° C. with an average temperature of 60 ° C. or less. can do.

Further, in the light emitting element light source module 10, since the cooling medium supply port 35A and the cooling medium discharge port 35B are provided outside the region directly under the light source, the temperature is further increased in the plurality of inward linear portions 36. Uniformity can be achieved.

Further, in the light emitting element light source module 10, since the water-cooled structure is composed of the heat sink 31 made of copper and the cooling block 40 made of stainless steel, galvanic corrosion is prevented or sufficiently suppressed. .. Moreover, since stainless steel has a smaller thermal conductivity than copper, between the cooling medium supply flow path 42 and the cooling medium discharge flow path 44, the cooling medium supply flow path 42 and the cooling flow path 35 Heat transfer is suppressed between the space and between the cooling medium discharge flow path 44 and the cooling flow path 35, respectively. Therefore, it is possible to suppress the occurrence of a temperature gradient in the cooling medium supply flow path 42 and the cooling flow path 35, so that the light emitting element can be cooled more effectively.

Further, in the light emitting element light source module 10, a plurality of cooling flow paths 35 are connected in an array by a cooling medium supply flow path 42 and a cooling medium discharge flow path 44, and for each of the plurality of cooling flow paths 35. , A cooling medium having a temperature equivalent to that of the cooling medium flowing through the supply opening in the cooling medium supply flow path 42 can be introduced. Therefore, even if the light source module 10 includes a plurality of light source units 20, a large number of light source 21 constituting the plurality of light source units 20 can be cooled efficiently and with high uniformity. can do.

Further, in the light emitting element light source module 10, since each of the plurality of light source units 20 is interchangeably fixed to the cooling block 40, the light source unit including the light emitting element 21 that needs to be replaced. The light emitting element 21 can be replaced by removing the 20 from the cooling block 40 and attaching a new light source unit 20.

The light emitting element light source module 10 is suitable as a light source of an ultraviolet irradiation device used in, for example, a liquid crystal panel manufacturing process (ODF method), a printed circuit board manufacturing process (exposure processing), and a printing ink fixing process (drying process). Can be used for.

The light emitting element light source module of the present invention is not limited to the above-described embodiment, and various modifications can be made.
For example, the cooling flow path has a plurality of flow path portions that are continuous with each other and adjacent to each other via the partition wall portion in the region directly under the light source, and the heat conductive partition wall portion located between the flow path portions adjacent to each other. As long as the thickness of the cooling flow path is smaller than the flow path width of the cooling flow path, the shape may be other than the shape shown in FIG. That is, the cooling flow path has a bent portion or a curved portion, and in the region directly under the light source, a plurality of flow path portions running in parallel via a heat conductive partition wall portion having a thickness smaller than the flow path width of the cooling flow path. Anything that has Specifically, the shape of the region directly below the light source of the cooling flow path is continuous with the first flow path portion extending along one edge of the light emitting element arrangement region and the cooling medium outlet of the first flow path portion. , It may be U-shaped having a second flow path portion extending in the same direction as the first flow path portion via the heat conductive partition wall portion. Further, the shape of the region directly below the light source of the cooling flow path may be a meandering shape that meanders and extends along the lateral direction of the heat sink in FIG. 4, and is also a spiral shape (specifically, a circular spiral shape and a rectangular shape). It may be spiral, etc.).
Here, when the shape of the region directly under the light source of the cooling flow path is U-shaped, the cooling medium supply port and the cooling medium discharge port are provided outside the region directly under the light source from the viewpoint of cooling efficiency. Is preferable. When the shape of the region directly under the light source of the cooling flow path is spiral, the cooling medium supply port is provided in the region directly under the light source and the cooling medium discharge port is the light source from the viewpoint of cooling efficiency. It is preferable that it is provided outside the region directly below.

Further, the light emitting element light source module may have a configuration in which one light source unit is arranged on the upper surface of the cooling block.

Further, in the light emitting element light source module, the light emitting element is directly arranged on the surface of the heat sink, and the wiring pattern is applied to the surface of the heat sink, that is, the heat sink also has a function as a substrate. There may be.
In such a case, since the light emitting element is directly cooled by the heat sink, the light emitting element can be cooled more effectively.

Hereinafter, an experimental example of the present invention will be shown.

[Experimental Example 1]
A light emitting element light source module having the configuration shown in FIG. 1 (hereinafter, also referred to as “light emitting element light source module (1)”) was manufactured.
In this light emitting element light source module (1), the substrate is made of aluminum nitride in which 160 LED elements having a peak emission wavelength of 365 nm are arranged in a houndstooth pattern of 10 × 16.
Further, the heat sink is formed by joining two substantially rectangular plate-shaped base materials made of copper by brazing, and the inside of the heat sink has a cross-sectional shape of 5 mm in width (flow path width) and a height. A cooling flow path having a (flow path height) of 2.5 mm, a flow path width ratio to the flow path height of 2, is formed in a flat rectangular shape, and the overall shape is meandering. In this cooling flow path, the thickness of the heat conductive partition between the inward linear portions adjacent to each other, and the heat conductive partition between the inward linear portion and the outward linear portion adjacent to each other. The thickness is 1 mm in each case. The area where the cooling flow path is formed is 83.3% of the area where the light emitting element is arranged. The cooling medium supply port and the cooling medium discharge port have a circular shape with a diameter of 6 mm.
The cooling block is made of stainless steel, and inside the cooling block, a cooling medium supply flow path and a cooling medium discharge having a circular cross-sectional shape with a diameter of 6 mm and a linear overall shape are provided. A flow path is formed.

In the manufactured light emitting element light source module (1), 160 light emitting elements constituting the three light source units are made to emit light under the condition of a calorific value of 1.82 W under an environmental condition of a temperature of 25 ° C., and a water-cooled structure is provided. A cooling medium composed of cooling water having a temperature of 25 ± 5 ° C. was supplied to the flow path under the condition of a flow rate of 3 L / min. Here, the calorific value of each light source unit was 291.2 W. Then, when the surface temperature of the substrate was measured and the temperature of the cooling medium at the cooling medium supply port and the temperature of the cooling medium at the cooling medium discharge port were measured, the surface temperature of the substrate was 59 ± 3 ° C., and the cooling medium. The temperature of the cooling medium at the supply port was 37 ° C., and the temperature of the cooling medium at the cooling medium discharge port was 38 ° C.

[Comparative Experiment Example 1]
In the light emitting element light source module (1) of Experimental Example 1, a light emitting element having the same configuration as the light emitting element light source module (1) except that the cooling flow path of the heat sink has a linear shape extending in the longitudinal direction of the heat sink. A light source module (hereinafter, also referred to as “comparative light emitting element light source module (1)”) was produced.

Regarding the light emitting element light source module (1) for comparison, the surface temperature of the substrate, the temperature of the cooling medium at the cooling medium supply port, and the temperature of the cooling medium at the cooling medium discharge port were measured in the same manner as in Experimental Example 1. The surface temperature was 80 ± 16 ° C., the temperature of the cooling medium at the cooling medium supply port was 45 ° C., and the temperature of the cooling medium at the cooling medium discharge port was 48 ° C.

[Comparative Experiment Example 2]
In the light emitting element light source module (1) of Experimental Example 1, the same as the light emitting element light source module (1) except that the cooling flow path of the heat sink has a shape having three linear branch paths extending in the longitudinal direction of the heat sink. A light emitting element light source module having the same configuration (hereinafter, also referred to as “comparative light emitting element light source module (2)”) was produced.

Regarding the light emitting element light source module (2) for comparison, the surface temperature of the substrate, the temperature of the cooling medium at the cooling medium supply port, and the temperature of the cooling medium at the cooling medium discharge port were measured in the same manner as in Experimental Example 1. The surface temperature was 72 ± 8 ° C., the temperature of the cooling medium at the cooling medium supply port was 47 ° C., and the temperature of the cooling medium at the cooling medium discharge port was 50 ° C.

From the results of Experimental Example 1, Comparative Experimental Example 1 and Comparative Experimental Example 2 described above, according to the light emitting element light source module (1) according to the present invention, a plurality of light emitting elements constituting the light emitting source can be efficiently and efficiently used. It was confirmed that it can be cooled with high uniformity.

10 Light source light source module 12 Cover member 12A Region 13 Window member 17 Supply part 18 Discharge part 20 Light source unit 21 Light source 22 Board 23 Electrical connection part 26 Supply passage 26A, 26B Supply passage 26A, 26B Supply passage 26A, 27B Discharge passage 27A, 27B Hole for discharge passage 28 Fixing screw 29 Sealing member 31 Heat sink 31A Large diameter part 31B Small diameter part 33A, 33B, 33C, 33D Region edge 35 Cooling flow path 35A Cooling medium supply port 35B Cooling medium discharge port 36 Linear flow path part ( Inner straight part)
37 Linear flow path part (outer straight part)
38A, 38B Bending flow path part (bending part)
39A, 39B Thermally conductive partition wall 40 Cooling block 41 Sealing member placement groove 42 Cooling medium supply flow path 44 Cooling medium discharge flow path 46 Buffering part 48 Sealing member

Claims (6)

It includes a light source unit in which a plurality of light emitting elements are arranged on the surface of a heat sink made of a heat conductive material, and a cooling block arranged on the back surface of the heat sink.
A cooling flow path for circulating a cooling medium is formed inside the heat sink.
The cooling medium supply port and the cooling medium discharge port in the cooling flow path are connected to the cooling medium supply flow path and the cooling medium discharge flow path formed in the cooling block, respectively.
The cooling flow paths are continuous with each other and have a plurality of flow path portions adjacent to each other via the heat conductive partition wall portion, and the thickness of the heat conductive partition wall portion is increased via the heat conductive partition wall portion. It is smaller than the flow path width of the cooling flow path so that heat exchange is performed between the cooling media flowing through the adjacent flow path portions, and is configured within the range of 0.5 to 2.5 mm.
The plurality of light emitting elements are arranged at positions directly above the plurality of flow path portions and the heat conductive partition wall portion on the surface of the heat sink.
The cooling block is a light emitting element light source module characterized in that the cooling block is made of a metal having a smaller thermal conductivity than a thermally conductive material constituting the heat sink. The cooling flow path is continuous with a first flow path portion extending along one edge of a light emitting element arrangement region in which the plurality of light emitting elements are arranged and a cooling medium outlet of the first flow path portion. The light emitting element light source module according to claim 1, further comprising a second flow path portion extending in the same direction as the first flow path portion via the heat conductive partition wall portion. The light emitting element light source module according to claim 2, wherein the cooling medium supply port and the cooling medium discharge port are each provided outside the region directly below the light emitting element arrangement region. The cooling flow path has a flow path width larger than the flow path height, has a flat cross-sectional shape extending along the surface of the heat sink, and the ratio of the flow path width to the flow path height is 1.5 to 3.5. The light emitting element light source module according to any one of claims 1 to 3. When the light source unit is viewed through in a direction perpendicular to the surface of the heat sink, the area of the region portion occupied by the cooling flow path in the light emitting element arrangement region in which the plurality of light emitting elements are arranged is the light emitting element arrangement area. The light emitting element light source module according to any one of claims 1 to 4, wherein the light emitting element light source module is 80% or more of the area of the above. A plurality of the light source units are provided, and the cooling block is common to these plurality of light source units.
Each of the cooling medium supply port and the cooling medium discharge port of the cooling flow path in the plurality of light source units is connected to the common cooling medium supply flow path and the common cooling medium discharge flow path in the cooling block. The light emitting element light source module according to any one of claims 1 to 5.

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