JP2004281352A - Shadowless lamp - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a shadowless lamp, reducing cost and facilitating the condensing of light from a light source to an area to be illuminated. <P>SOLUTION: A plurality of LEDs 40 are arranged spreading along the surface 21 of a substrate 20. A condenser lens 32 is provided so that the light from each LED 40 is independently condensed to the whole area of the area S1 to be illuminated. The loss of the light from the LED is minimized to allow a limited number of LEDs 40 to emit a sufficient amount of light. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a surgical light that focuses light from a light source on an illumination area.
[0002]
[Prior art]
As a conventional surgical light, one large light source is formed by collecting a plurality of LEDs, a reflecting mirror is arranged behind the light source, and the light from the LED is reflected by the reflecting mirror. (For example, see Patent Document 1).
By using an LED as a light source, there is an advantage that it is not necessary to take high-temperature measures because the light source does not become hot, and that the life of the light source is prolonged, and that the operating light can be made lightweight and thin. .
[0003]
In addition, one lens unit for individually controlling the light distribution from the LED is provided for each LED, and the light from each LED is condensed to an area of a predetermined irradiation distance by the lens unit. (For example, see Patent Document 2).
[0004]
Furthermore, Patent Literature 3 discloses a technique in which a desired illumination color is obtained by changing the ratio of the number of lighted red, green, and blue LEDs and mixing light from each LED. ing.
[0005]
[Patent Document 1]
Japanese Utility Model Registration No. 3084178
[Patent Document 2]
JP 2001-106356 A
[Patent Document 3]
JP-A-2002-352968
[0006]
[Problems to be solved by the invention]
However, in the technique according to Patent Literature 1, since the light from the LED is reflected by the reflecting mirror and then condensed on the illumination area, a considerable amount of light loss occurs, and a sufficient amount of light is generated. Since a large number of LEDs are required to obtain the light source, there is a problem that the cost is increased, and since the light source is large, it is difficult to condense the light in an illumination area.
[0007]
Further, in the technology according to Patent Document 2, when LEDs are arranged in a wide range, in order to collect light from each LED arranged in a wide range to a predetermined area by each lens unit, It is necessary to prepare lens parts of various shapes and fix the lens parts at predetermined positions, and there is a problem that the manufacturing cost and the assembly cost of the lens parts increase.
Furthermore, in the technique according to Patent Literature 3, if the number of lit LEDs is changed in order to change a predetermined illumination color, the illuminance may change, which is not convenient. Was.
[0008]
The present invention has been made to solve the above-mentioned conventional problems. A plurality of LEDs are arranged so as to spread along the surface of a substrate, and light from each LED is individually collected over the entire illumination area by an optical system. In this case, a sufficient amount of light can be obtained even with a small number of LEDs so that the cost can be reduced. In addition, the light source can be made small so that the light from the light source can be easily condensed in the illumination area. It is intended to provide an operating light that can be operated. It is another object of the present invention to provide an easy-to-use surgical light that can reduce the manufacturing cost and the assembly cost of the condenser lens.
[0009]
[Means for Solving the Problems]
The gist of the present invention to achieve this object lies in the inventions in the following items.
[1] Light from a light source is condensed on an illumination area (S1), and in an operation lamp including a substrate (20) and an optical system (30),
The light source includes a plurality of LEDs (40);
The substrate (20) is arranged so that a surface (21) of the substrate (20) faces the illumination area (S1),
The plurality of LEDs (40) are arranged to extend along a surface (21) of the substrate (20);
The operating light is characterized in that the optical system (30) is arranged to individually condense light from each LED (40) to the entire illumination area (S1).
[0010]
[2] a front cover (31) for covering the plurality of LEDs (40) from the front,
The optical system (30) includes a plurality of condenser lenses (32),
The plurality of condenser lenses (32) are respectively arranged corresponding to the respective LEDs (40),
Furthermore, the operating light is characterized in that a plurality of condenser lenses (32) are formed integrally with the front cover (31).
[0011]
[3] The condensing lens (32) is arranged so that the light from the LED (40) is collected at one point before the illumination area (S1). Surgical light.
[0012]
[4] The optical system (30) includes a plurality of reflecting mirrors (35),
The plurality of reflecting mirrors (35) are respectively arranged corresponding to the respective LEDs (40), and the plurality of reflecting mirrors (35) are individually provided to the entire illumination area (S1). The operating light according to [1] or [2], wherein the operating light is formed so as to reflect and condense the light from (1).
[0013]
[5] The reflecting mirror (35) is formed so as to reflect light from the LED (40) and collect the light at one point before the illumination area (S1) [4]. Operating light as described in.
[0014]
[6] The surface (21) of the substrate (20) includes a curved surface (22) recessed in a direction opposite to the illumination area (S1),
The curved surface (22) is formed so that the direction of the optical axis of the LED (40) disposed on the curved surface (22) is directed to the center of the illumination area (S1) [1]. ] Or the surgical light according to [2].
[0015]
[7] The front cover (31) includes a recessed surface (31a) recessed in a direction opposite to the illumination area (S1),
The concave surface (31a) is formed so that the direction of the optical axis of the condenser lens (32) formed integrally with the illumination cover is directed toward the center of the illumination area (S1). The surgical light according to [2], which is characterized by the following.
[0016]
[8] A surgical lamp including a substrate (20) and an optical system (30), wherein light from a light source is focused on an illumination area (S1).
The light source includes a plurality of LEDs (40);
The plurality of LEDs (40) are arranged to extend along a surface (21) of the substrate (20);
A surface (21) of the substrate (20) includes a curved surface (22) recessed in a direction opposite to the illumination area (S1);
The curved surface (22) is formed so as to direct the direction of the optical axis (L2) of the LED (40) disposed on the curved surface (22) toward the illumination area (S1),
The optical system (30) includes a plurality of condenser lenses (32) arranged along a surface (21) of the substrate (20), and the plurality of condenser lenses (32). (40) a lens support member (33) for supporting the lens in a corresponding manner.
The lens support member (33) is formed such that each optical axis (L2) of the plurality of condenser lenses (32) matches each optical axis (L2) of the plurality of LEDs (40). An operating light characterized by the following.
[0017]
[9] The plurality of LEDs (40) are divided into two or more groups (G11, G12),
The illumination area (S1) includes a coverage area (S11, S12) that is an area covered by the group (G11, G12),
The condensing lens (32) is arranged so as to condense light from the LEDs (40) related to the groups (G11, G12) to the coverage areas (S11, S12) [ 8] The operating light according to [1].
[0018]
[10] The plurality of LEDs (40) are arranged in a matrix,
The condenser lens (32) includes a front convex lens part (32b) protruding forward from the front of the condenser lens (32) and a rear convex lens part (32c) protruding rear from the back of the condenser lens (32). ) And
The plurality of front convex lens portions (32b) extend in a cylindrical shape along one of each row or each column of the LEDs (40), and are formed to be continuous with each other;
A plurality of the rear convex lens portions (32c) each extend in a cylindrical shape along the other of each of the rows or columns and are formed so as to be continuous with each other [1] to [9]. The surgical light according to any one of the above.
[0019]
[11] Each of the front convex lens portion (32b) and the rear convex lens portion (32c) protrudes forward and backward with different curvatures, respectively, and emits light from the LED (40) to the illumination area (S1) or The surgical light according to any one of [1] to [10], wherein the operating light is formed so as to converge light on the responsible area (S11, S12).
[0020]
[12] The plurality of LEDs (40) include RGB LEDs (40) that emit red, green, and blue colors, respectively.
Controlling the lighting of each of the RGB LEDs (40) to keep the total amount of luminous flux from each of the RGB LEDs (40) constant and changing the ratio of the luminous flux from each of the RGB LEDs (40); The operating light according to any one of [1] to [11], further comprising an LED (40) control means for adjusting a color temperature.
[0021]
[13] The plurality of LEDs (40) include a plurality of LED modules (40M) formed by collecting two or more white LEDs (40w) and one or more red LEDs (40r). The surgical light according to any one of [1] to [11].
[0022]
[14] The plurality of LEDs (40) include a white LED (40w) of each system having a color tone of red, green, and blue,
The operating light according to any one of [1] to [11], wherein the white LEDs (40w) of the respective systems are arranged so as not to be gathered at one place in the same system.
[0023]
[15] A heat radiating member (50) for radiating heat from the light source to the outside of the surgical light is disposed on a back surface (15) side of the surgical light [1]. -The surgical light according to any one of [14] to [14].
[0024]
[16] The surgical light according to any one of [1] to [14], wherein the back surface (15) of the surgical light is formed of a flat surface made of a metal material.
[0025]
[17] The back surface (15) of the operating light is formed in a mirror surface by a metal material,
The surgical light according to any one of [1] to [14], further comprising: an auxiliary light (60) for illuminating the rear of the surgical light.
[0026]
[18] The LED (40) is formed such that the light emission distribution of the LED (40) is in a shape corresponding to any one of the illumination area (S1) and the responsible area (S11, S12). The operating lamp according to any one of [1] to [17], wherein:
[0027]
[19] The condenser lens (32) is formed so as to irradiate light from the LED (40) to a substantially square area,
Two or more of the condenser lenses (32) form a lens module (32M) by converging with each other,
The lens module (32M) is formed in a shape corresponding to any one of the illumination area (S1) and the responsible area (S11, S12) [1] to [18]. The surgical light according to any one of the above.
[0028]
[20] The condensing lens (32) condenses the light having high radiation energy from the LED (40) on the periphery (S14) of the illumination area (S1) or the responsible area (S11, S12). On the other hand, it is characterized in that it is formed so that light with low radiant energy is focused on the central part (S13) of the illumination area (S1) or the responsible area (S11, S12) [1] to [19]. ] The surgical light according to any one of [1] to [10].
[0029]
[21] The lens support member (33) and the condenser lens (32) are integrally formed,
The surgical light according to any one of [1] to [20], wherein a light-blocking material (36) is applied to at least one of a front side and a rear side of the lens support member (33). .
[0030]
[22] A heat dissipation gap (SL1) for emitting heat from the LED is formed between the lens support member (33) and the LED (40).
The condensing lens (32) projects from the lens support member (33) toward the LED (40) and approaches the LED (40), so that almost all of the light from the LED (40) is transmitted. The surgical light according to any one of [1] to [21], wherein the operating light is arranged to be incident on the condenser lens (32).
[0031]
Next, the operation of the present invention will be described.
In the case where the plurality of LEDs (40) are arranged so as to spread along the surface (21) of the substrate (20), the plurality of LEDs (40) are substantially uniformly dispersed on the surface (21) of the substrate (20). The plurality of LEDs (40) may be arranged on the surface (21) of the substrate (20) in a predetermined number of rows and columns. By arranging or arranging the plurality of LEDs (40), the plurality of LEDs (40) does not become bulky, the substrate (20) of the LEDs (40) can be reduced, and the size of the surgical light can be reduced. Generally, the plurality of LEDs (40) are arranged corresponding to the shape of the illumination area (S1). For example, if the illumination area (S1) is rectangular or circular, the plurality of LEDs (40) are arranged so as to be rectangular or circular.
[0032]
The optical system (30) collects light from each LED (40) individually over the entire illumination area (S1). By condensing the light from each LED (40) in the illumination area (S1), a sufficient amount of light can be obtained. Further, since each of the LEDs (40) is a small light source, the light from the LED (40) can be easily focused on the illumination area (S1) by the optical system (30). The optical system (30) includes a condenser lens (32) and a reflecting mirror (35).
[0033]
A front cover (31) for covering the plurality of LEDs (40) from the front is provided, the optical system (30) includes a plurality of condensing lenses (32), and the plurality of condensing lenses (32) is provided for each LED (40). ), And formed integrally with the front cover (31), the plurality of condenser lenses (32) and the front cover (31) are, specifically, translucent. Are integrally formed by a molding die using a resin material having
For example, no matter where the condenser lens (32) is formed on the front cover (31), in order for the optical axis of the condenser lens (32) to pass through the center of the illumination area (S1). It is necessary to change the direction of the condenser lens (32) depending on the position where the condenser lens (32) is formed. Therefore, when the front cover (31) is a flat surface, a plurality of Each shape of the condenser lens (32) is different.
[0034]
When the condenser lens (32) is arranged to collect the light from the LED (40) at one point before the illumination area (S1), the condenser lens (32) having a short focal length and a small outer diameter. ), The light from the LED (40) gathers at one point before the illumination area (S1) and then spreads toward the entire illumination area (S1). Since the condenser lens (32) having a small outer diameter can be used, the distance between the adjacent condenser lenses (32) is shortened, and the distance between the adjacent LEDs (40) is shortened. Can be reduced in size.
[0035]
When the optical system (30) includes a plurality of reflecting mirrors (35), and the plurality of reflecting mirrors (35) are arranged corresponding to the respective LEDs (40), the light is reflected instead of the condenser lens (32). A mirror (35) may be used, or a reflecting mirror (35) may be used together with the condenser lens (32).
[0036]
When a reflecting mirror (35) is used instead of the condenser lens (32), the light from the LED (40) emitted to the outside of the illumination area (S1) is reflected, and the light is reflected within the illumination area (S1). A reflecting mirror (35) is formed so as to be directed. When the reflecting mirror (35) is used together with the condenser lens (32), the light from the LED (40) emitted to the outside of the condenser lens (32) is reflected to the condenser lens (32). A reflecting mirror (35) is formed so as to be directed. Thereby, almost all the light from the LED (40) is converged on the illumination area (S1), and a sufficient amount of light can be obtained. For example, when the reflecting mirror (35) is similar to a concave mirror, each reflecting mirror (35) is arranged so that the mirror axis of the reflecting mirror (35) passes through the center of the illumination area (S1).
[0037]
In the case where the reflecting mirror (35) is formed so as to reflect the light from the LED (40) and collect it at one point before the illumination area (S1), for example, the reflecting mirror (35) is similar to a concave mirror. In the case of a light source, by using a reflecting mirror (35) having a short focal length and a small outer diameter, light from the LED (40) converges to one point before the illumination area (S1) and then reaches the illumination area (S1). ) Spread towards the whole. By using the reflecting mirror (35) having a small outer diameter, the distance between the adjacent reflecting mirrors (35) is shortened, and the distance between the adjacent LEDs (40) is shortened. be able to.
[0038]
The surface (21) of the substrate (20) has a curved surface (22) recessed in a direction opposite to the illumination area (S1), and the curved surface (22) is disposed on the curved surface (22) by the LED (40). When the LED (40) is arranged along the surface (21) of the substrate (20), the direction of the optical axis of the LED (40) is directed toward the center of the illumination area (S1). Only by mounting the component (40) on the surface (21) of the substrate (20), the direction of the optical axis of the LED (40) is directed toward the center of the illumination area (S1). At this time, the optical axis of the LED (40) may be aligned with the optical axis of the condenser lens (32) or the optical axis of the reflecting mirror (35).
[0039]
Further, the front cover (31) has a concave surface (31a) recessed in the direction opposite to the illumination area (S1), and the concave surface (31a) is formed integrally with the illumination cover. In the case where the direction of the optical axis of the lens (32) is directed to the center of the illumination area (S1), as described above, the condenser lens depends on the position where the condenser lens (32) is formed. Although it is necessary to change the direction of (32), since the front cover (31) has a concave surface (31a), it is possible to collect light without actively changing the direction of each condenser lens (32). If the lens (32) is arranged along the concave surface (31a) of the front cover (31), the direction of the optical axis of the condensing lens (32) is directed to the center of the illumination area (S1). It is not necessary to make each shape of the plurality of condenser lenses (32) different from each other. Body-formed by condensing lens (32) can be of the same shape.
[0040]
The optical system (30) includes a plurality of condenser lenses (32) arranged along the surface (21) of the substrate (20) and a plurality of condenser lenses (32) to a plurality of LEDs (40). A lens support member (33) for supporting each correspondingly, wherein the lens support member (33) is configured to connect each optical axis (L2) of the plurality of condenser lenses (32) to the plurality of LEDs (40). When the condenser lens (32) is mounted on the lens support member (33), the optical axis (L2) of the condenser lens (32) is formed. For example, the entire lens support member (33) may be formed into a curved surface (22) in the same manner as the surface (21) of the substrate (20) so that the optical axis (L2) of the LED (40) coincides with the optical axis (L2) of the LED (40). Also, for example, a mounting hole for mounting the condenser lens (32) It is not necessary to prepare converging lenses (32) of various shapes corresponding to the positions where the LEDs (40) are arranged, and the same condensing lens (32) can be used. Can be used, and the manufacturing cost and the assembly cost of the condenser lens (32) can be reduced.
[0041]
The plurality of LEDs (40) are divided into two or more groups (G11, G12), and the illuminated area (S1) includes areas (S11, S12), which are areas allocated to the groups (G11, G12). The light from the LEDs (40) related to the groups (G11, G12) is condensed on the respective areas (S11, S12) by the condenser lens (32). Adjacent areas (S11, S12) may overlap each other, or may not overlap each other.
[0042]
For example, when the illuminance of the peripheral portion (S14) around the central portion (S13) is lower than the illuminance of the central portion (S13) of the responsible region (S11, S12), the neighboring responsible regions (S11, In S12), if the illuminance is increased by overlapping the peripheral edges (S14) of the coverage areas (S11, S12), the uniformity of the entire illumination area (S1) can be increased.
[0043]
The condenser lens (32) includes a front convex lens part (32b) protruding forward from the front of the condenser lens (32) and a rear convex lens part (32c) protruding rear from the back of the condenser lens (32). And a plurality of front convex lens portions (32b) are each formed in a cylindrical shape along one of the rows or columns in which the LEDs (40) are arranged, and are formed so as to be continuous with each other. Since a plurality of convex lens portions (32c) extend in a cylindrical shape along the other of each row or each column and are formed so as to be continuous with each other, a plurality of condenser lenses (32) are individually formed, Instead of being individually assembled, they can be formed integrally and assembled together at once.
[0044]
Each of the front convex lens portion (32b) and the rear convex lens portion (32c) protrudes forward and backward with different curvatures, respectively, and receives light from the LED (40) in the illumination area (S1) or the area (S11, S12). For example, when the illumination area (S1) or the area (S11, S12) is rectangular, the light from the LED (40) is formed into a rear convex lens portion (32c). ) In one direction (for example, the short direction of the illumination area (S1) or the area (S11, S12)), and the other lens (for example, the illumination area (S1) or the area ( If the light is condensed in the longitudinal direction (S11, S12), the light from each LED (40) is illuminated (S1) or the area (S11, S12). It can be condensed to.
[0045]
When the plurality of LEDs (40) include the RGB LEDs (40) that emit red, green, and blue colors, the LED (40) control means controls the lighting of each of the RGB LEDs (40). , The total amount of luminous flux from each of the RGB LEDs (40) is kept constant, and the color temperature is adjusted by changing the ratio of the luminous flux from each of the RGB LEDs (40). The color temperature can be changed to the color temperature desired by the user without changing the illuminance of S1) or the assigned area (S11, S12).
[0046]
The plurality of LEDs (40) include a plurality of LED modules (40M) formed by collecting two or more white LEDs (40w) and one or more red LEDs (40r). ) Simply turns on the red component (40r) when the red object looks yellowish because the red component is insufficient, so that the red object can be seen in its original color, Color rendering is enhanced.
[0047]
The plurality of LEDs (40) include a white LED (40w) of each system having a color tone of red, green, and blue, and the white LEDs (40w) of each system do not converge at one place in the same system. , By controlling the lighting of the white LED (40w) of each system, the color temperature desired by the user can be changed without changing the illuminance of the illumination area (S1) or the area of responsibility (S11, S12). Can be changed to The color temperature may be changed by controlling the current to the white LED (40w) of each system.
[0048]
In the case where a heat radiating member (50) for radiating heat from the light source to the outside of the surgical light is disposed on the back surface (15) side of the surgical light, infrared light from the LED (40) as a light source is provided. Although the amount of heat generated from the LED (40) is small, the durability of the LED (40) can be increased by radiating heat from the back surface (15) side of the operating light by the heat radiation member (50). . In the case where the back surface (15) of the operating lamp is formed of a flat surface by a metal material, for example, if the flat back surface (15) is formed of an aluminum material, the back surface (15) of the operating lamp from the side (15) side The heat radiation effect can be enhanced, and the heat radiation member (50) need not be provided.
[0049]
In the case where the back surface (15) of the surgical light is formed in a mirror surface by a metal material and the auxiliary light (60) for illuminating the back of the surgical light is provided, the surgical light is turned upside down. , Can be used as a mirror. At this time, by turning on the auxiliary illumination lamp (60), it is possible to illuminate an object to be reflected in a mirror.
[0050]
The LED (40) is formed such that the light emission distribution of the LED (40) is formed in a shape corresponding to any one of the illumination area (S1) and the area (S11, S12). By simply condensing the light from 40), it is possible to irradiate the illumination area (S1) or the area of responsibility (S11, S12) without using a special lens.
[0051]
The condenser lens (32) is formed so as to irradiate the light from the LED (40) to the substantially square area (S15), and two or more of the condenser lenses (32) are gathered together to form a lens module (32M). When the lens module (32M) is formed in a shape corresponding to any one of the illumination area (S1) and the responsible area (S11, S12), the condenser lens (32) is collected. Concentrating light from the LED (40) on the illumination area (S1) or the area (S11, S12) corresponding to the shape of the lens module (32M) simply by making the lens module (32M) of an appropriate shape. Can be. Also, by collecting a plurality of lens modules (32M) and forming an appropriate shape, the light from the LED (40) is condensed on the illumination area (S1) or the area (S11, S12) corresponding to the shape. It can also be done.
[0052]
The condensing lens (32) condenses the light with high radiation energy from the LED (40) to the peripheral area (S14) of the illumination area (S1) or the area (S11, S12), while the light with low radiation energy. Is formed so as to converge the light on the central part (S13) of the illumination area (S1) or the area (S11, S12), the central part (S1) of the illumination area (S1) or the area (S11, S12). The respective illuminances of S13) and the peripheral portion (S14) are substantially the same, and the uniformity of the illumination area (S1) or the area of responsibility (S11, S12) can be increased.
[0053]
In the case where the condenser lens (32) and the lens support member (33) are integrally formed and the light blocking material (36) is applied to the back or the surface of the lens support member (33), the condenser lens (32) The lens supporting member (33) is integrally formed with a material having a light-transmitting property, and thereafter, a light shielding material (36) is applied to the rear surface or the front surface side of the lens supporting member (33). By integrally forming the condenser lens (32) and the lens support member (33), it is not necessary to separately manufacture and assemble them.
[0054]
A heat-dissipating gap (SL) for releasing heat from the LED (40) is formed between the condenser lens (32) and the LED (40), and the condenser lens (32) is connected to the lens support member (33). ) Protrudes from the LED (40) toward the LED (40) and is close to the LED (40), the heat from the LED (40) is released to the gap (SL) for heat radiation so as not to overheat the LED (40). I have to. The durability of the LED is increased so that almost all of the light from the LED (40) is made incident on the condenser lens (40) so that the light from the LED (40) is not unnecessarily diffused.
[0055]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a plan view of an operating light according to a first embodiment of the present invention, showing a state in which light from a central LED is focused on the entire illumination area, and FIG. FIG. 3 is a side view of the surgical light, and FIG. 3 is a plan view of the surgical light, showing how light from each LED is individually focused on the entire illumination area. FIG. 5 is a view showing a state in which light from each LED is individually condensed on the entire illumination area, FIG. 5 is a front view of the surgical light, and FIG. 6 is a partially enlarged plan view of the surgical light; FIG. 3 is a diagram illustrating a condenser lens.
[0056]
As shown in FIGS. 1 to 6, the operating light according to the first embodiment of the present invention focuses light from a light source on an illumination area S1, and includes a substrate 20 and an optical system 30. And The surgical light is supported by an arm (not shown). The light source includes a plurality of LEDs 40. The substrate 20 is arranged so that the surface 21 of the substrate 20 faces the illumination area S1. The plurality of LEDs 40 are arranged so as to spread along the surface 21 of the substrate 20. The substrate 20 is a front plate of the main body 10 of the operating lamp. The spread shape of the plurality of LEDs 40 corresponds to the shape of the illumination area S1. In the first embodiment, the plurality of LEDs 40 also extend in a rectangular shape along the surface 21 of the substrate 20 in accordance with the rectangular illumination area S1. As the LED 40, for example, a white LED in which a fluorescent material is covered on a package of an ultraviolet LED is used.
[0057]
In the present embodiment, the LEDs 40 are arranged on the substrate 20 in a 5 × 7 matrix. The optical system 30 is arranged so as to individually condense the light from each LED 40 to the entire illumination area S1. The board 20 is formed with a counterbore (not shown) for passing the leads of the LEDs 40 from the front side to the back side of the board 20. On the back side of the substrate 20, a driver for driving a white LED, a power supply and an AD converter (both not shown) are arranged. Each LED 40 is connected in series to a power supply. The driver has a function of controlling brightness by adjusting current.
[0058]
A front cover 31 for covering the plurality of LEDs 40 from the front is provided. The front cover 31 is positioned and fixed at a predetermined position by being fitted to the body 10 of the operating light. The optical system 30 includes a plurality of condenser lenses 32. The plurality of condenser lenses 32 are arranged corresponding to the respective LEDs 40. Further, the plurality of condenser lenses 32 are formed integrally with the front cover 31. The condenser lens 32 is a single-convex lens with a flat front side. As shown in FIGS. 1 and 2, the condenser lens 32 condenses light from the LED 40 over the entire illumination area S1. That is, the light path L1 of the light from the LED 40 is gradually increased by the condenser lens 32 to the entire width of the illumination area S1. Similarly, as shown in FIGS. 3 and 4, the other condensing lenses 32 individually condense the light from each LED 40 over the entire illumination area S1.
[0059]
The plurality of condenser lenses 32 and the front cover 31 are integrally formed by a resin mold. As a material, a resin material having translucency is used. Each condenser lens 32 is formed such that the direction of the optical axis thereof is directed to the center of the illumination area S1. Therefore, the shape of the condenser lens 32 differs depending on the position where the condenser lens 32 is formed. For example, the shape of the condenser lens 32 formed at the center of the substrate 20 is different from the shape of the condenser lens 32 formed at the end of the substrate 20.
[0060]
Next, the operation of the first embodiment will be described.
By arranging a plurality of LEDs 40 in a predetermined number of rows and columns on the surface 21 of the substrate 20, the plurality of LEDs 40 are not bulky, the substrate 20 of the LEDs 40 can be reduced, and the size of the surgical light can be reduced. Light from each LED 40, which is arranged at each position of the substrate 20 and emitted to the front side of the substrate 20, is individually condensed to the entire illumination area S1 by the condensing lens 32. Can be obtained. Further, each of the LEDs 40 has a small light source, and the condenser lens 32 easily condenses the light from the LED 32 to the illumination area S1. Furthermore, since each condenser lens 32 individually condenses the light from each LED 40 over the entire illumination area S1, a shadow image may be generated in the illumination area S1 even if a light-shielding object enters the light path L1 of the LED 40. There is no.
[0061]
FIG. 7 is a partially enlarged plan view of the surgical light, in which a condensing lens is shown as an optical system, and light from an LED is collected at one point before an illumination area. As shown in FIG. 7, the light from the LED 40 gathers at one point before the illumination area S1 and then spreads toward the entire illumination area S1. In order to collect the light from the LED 40 at one point before the illumination area S1, a condenser lens having a short focal length and a small outer diameter is used. By using the condensing lens 32 having a small outer diameter, the distance between the adjacent condensing lenses 32 is shortened, the distance between the adjacent LEDs 40 is shortened, the substrate 20 can be small, and the operating light can be reduced in size. Can be
[0062]
FIG. 8 is a front view of the surgical light, and FIG. 9 is a front view of the surgical light, showing a condenser lens having a rectangular cross-sectional shape. As described above, the condensing lens 32 is a one-convex lens, but as shown in FIG. 8, the condensing lens 32 may be a one-convex lens having a circular cross-sectional shape, and as shown in FIG. The shape may be a one-convex lens. The rectangular cross-sectional shape of the condenser lens 32 corresponds to the shape of the illumination area S1.
[0063]
FIG. 10 is a partial plan view of an operating light showing a second embodiment of the present invention, in which a Fresnel lens is shown as an optical system, and FIG. 11 is a drawing showing a second embodiment of the present invention. FIG. 12 is a front view of a shadowless lamp similarly showing a second embodiment of the present invention.
[0064]
As shown in FIG. 10, a Fresnel lens 32a is used as the optical system 30, and the Fresnel lens 32a and the front cover 31 are integrally formed. As shown in FIG. 11, the Fresnel lens 32a may be one in which only the curvatures of convex lenses having a circular cross-sectional shape are arranged on a plane, and as shown in FIG. Alternatively, only the curvature of the convex lens having a rectangular cross section may be arranged on a plane.
[0065]
FIG. 13 is a plan view of a surgical light showing a third embodiment of the present invention, and FIG. 14 is a side view of the surgical light showing a third embodiment of the present invention. As shown in FIGS. 13 and 14, the surface 21 of the substrate 20 has a curved surface 22 recessed in a direction opposite to the illumination area S1. The curved surface 22 is formed so that the direction of the optical axis of the LED 40 disposed on the curved surface 22 is directed toward the center of the illumination area S1. The curved surface 22 includes a paraboloid of revolution, a hyperboloid, a spheroid, and a sphere.
[0066]
Further, the front cover 31 has a recessed surface 31a recessed in a direction opposite to the illumination area S1. The concave surface 31a is formed so that the direction of the optical axis of the condenser lens 32 formed integrally with the illumination cover is directed to the center of the illumination area S1. Similarly, the concave surface 31a includes a paraboloid of revolution, a hyperboloid, a spheroid, and a sphere.
[0067]
A counterbore hole (not shown) for passing the lead of the LED 40 is also formed on the curved surface 22 of the substrate 20. When the LED 40 is arranged along the curved surface 22 of the substrate 20, for example, the lead of the LED 40 is connected to the substrate 20. By simply mounting the LED 40 at a predetermined position on the curved surface 22 through the counterbore hole, the direction of the optical axis of the LED 40 is directed toward the center of the illumination area S1. Thereby, when mounting the LED 40 on the substrate 20, it is not necessary to specifically perform the optical axis alignment of the LED 40.
[0068]
As described in the first embodiment, it is necessary to change the direction of the condenser lens 32 depending on the position where the condenser lens 32 is formed. However, since the front cover 31 is the concave surface 31a, Simply forming the condenser lenses 32 of the same shape along the concave surface 31a of the front cover 31 so that the direction of the optical axis of the condenser lens 32 faces the center of the illumination area S1. That is, it is not necessary to change the shape of each condenser lens 32 depending on the position where the condenser lens 32 is formed. Thereby, the integral shape of the front cover 31 and the condensing lens 32 can be simplified, and the manufacture becomes easy.
[0069]
FIG. 15 is a partial plan view of a surgical light showing a fourth embodiment of the present invention, in which a reflecting mirror is shown as an optical system, and FIG. FIG. 5 is a diagram in which light from an LED reflected by a mirror is collected at one point in front of an illumination area.
[0070]
As shown in FIG. 15, the optical system 30 includes a plurality of reflecting mirrors 35. The plurality of reflecting mirrors 35 are arranged corresponding to the respective LEDs 40. The plurality of reflecting mirrors 35 are used in place of the condenser lens 32, and are formed so as to reflect and collect light from each LED 40 individually to the entire illumination area S1. The reflecting mirror 35 reflects light emitted from the LED 40 out of the illumination area S1 toward the illumination area S1, so that almost all of the light from the LED 40 is condensed in the illumination area S1, and the light amount loss is reduced. Thus, a sufficient amount of light can be obtained. When the reflecting mirror 35 is similar to a concave mirror, each reflecting mirror 35 is arranged such that the mirror axis of the reflecting mirror 35 passes through the center of the illumination area S1.
[0071]
As shown in FIG. 16, the reflecting mirror 35 may be formed so as to reflect the light from the LED 40 and collect it at one point before the illumination area S1. For example, when the reflecting mirror 35 is similar to a concave mirror, by using the reflecting mirror 35 having a short focal length and a small outer diameter, the light from the LED 40 is gathered at one point before the illumination area S1 and then illuminated. It spreads toward the whole area S1. By using the reflecting mirror 35 having a small outer diameter, the distance between the adjacent reflecting mirrors 35 is shortened, the distance between the adjacent LEDs 40 is shortened, and a plurality of predetermined LEDs 40 are arranged within a narrow range of the substrate 20. The operating light can be reduced in size.
[0072]
FIG. 17 is a partial plan view of a surgical light according to a fifth embodiment of the present invention, showing a condenser lens and a reflecting mirror as an optical system. As shown in FIG. 17, a reflecting mirror 35 is used together with the condenser lens 32. The LED 40 and the reflecting mirror 35 are arranged so that their optical axes are aligned with each other. When the reflecting mirror 35 is used together with the condenser lens 32, the reflecting mirror 35 is formed so as to reflect light from the LED 40 emitted to the outside of the condenser lens 32 and direct the light toward the condenser lens 32. As a result, almost all of the light from the LED 40 passes through the condenser lens 32 and is condensed on the illumination area S1, so that a loss of light quantity can be reduced and a sufficient light quantity can be obtained.
[0073]
FIG. 18 is a partial plan view conceptually showing a surgical light according to a sixth embodiment of the present invention, in which light from an LED is condensed over the entire illumination area by a condenser lens, and FIG. FIG. 20 is a partial plan view in which a region where light from an LED is collected by a condenser lens is made different for each LED, and FIG. 20 is a partial plan view also showing a plurality of LEDs. FIG. 3 is a diagram in which light from the LEDs according to each group is divided into two groups, and is condensed in a region where the light is condensed by a condenser lens.
[0074]
As shown in FIG. 18, the optical system 30 includes a plurality of condenser lenses 32 each arranged along the surface 21 of the substrate 20 and a lens support member 33 for supporting the plurality of condenser lenses 32. Have. The mounting surface 33 a of the lens support member 33 is formed to be curved along the surface 21 of the substrate 20. The plurality of condenser lenses 32 are formed in a one-convex lens shape, and are arranged along the mounting surface 33a. The lens support member 33 supports the plurality of condenser lenses 32 so as to correspond to the plurality of LEDs 40, respectively.
[0075]
Further, the lens support member 33 is formed such that each optical axis L2 of the plurality of condenser lenses 32 matches each optical axis L2 of the plurality of LEDs 40. Mounting holes 33b are formed in the lens support member 33 so that the central axes thereof coincide with the optical axis L2 of each LED 40. Thereby, if the same condenser lens 40 is fitted into each mounting hole 33b, the optical axis L2 of each condenser lens 32 and the optical axis L2 of each LED 40 become coincident, and the assembly of the condenser lens 32 is completed. Become easy.
[0076]
In FIG. 18, the light from the LED 40 is focused on the entire illumination area S1 by the condenser lens 32. However, as shown in FIG. The light may be condensed on the respective areas S11 and S12. When the peripheral portions S14 of the responsible regions S11 and S12 are overlapped with each other in the neighboring responsible regions S1 and S2, the illuminance of the peripheral portions S14 increases, and is substantially equal to the illuminance of the central portion S13 of the responsible regions S1 and S2. As a result, the uniformity of the illumination area S1 can be increased.
[0077]
As shown in FIG. 20, the plurality of LEDs 40 are divided into two groups G11 and G12. The illumination area S1 includes coverage areas S11 and S12, which are areas covered by the groups G11 and G12, and the condenser lens 40 collects light from the LEDs 40 related to the groups G11 and G12. It is arranged to light. Not limited to this, the plurality of LEDs 40 may be divided into two or more groups G11, G12,..., And light from the LEDs 40 in each group G11, G12,. It may be.
[0078]
FIG. 21 is a partial perspective view mainly showing the condenser lens of the surgical light according to the seventh embodiment of the present invention, FIG. 22 is a view taken along arrow XXII of FIG. 21, and FIG. 23 is an arrow XXIII of FIG. FIG.
[0079]
As shown in FIGS. 21 to 23, the condenser lens 32 is formed by integrally forming a plurality of front convex lens portions 32b and a plurality of rear convex lens portions 32c. The front convex lens portion 32b projects forward from the front of the condenser lens 32, and the rear convex lens portion 32c projects rearward from the rear surface of the condenser lens 32. The plurality of front convex lens portions 32b extend in a cylindrical shape along the rows where the LEDs 40 are arranged, and are formed to be continuous with each other. The plurality of rear convex lens portions 32c extend in a cylindrical shape along the rows in which the LEDs 40 are arranged, and are formed so as to be continuous with each other. Since the plurality of front convex lens portions 32b and the plurality of rear convex lens portions 32c are integrally formed, it is not necessary to form the plurality of condenser lenses 32 individually and assemble them individually.
[0080]
The pair of the front convex lens portion 32b and the rear convex lens portion 32c causes light from each LED 40 to be focused on the illumination area S1 or the area S11 or S12. Each of the front convex lens portion 32b and the rear convex lens portion 32c protrudes forward and rearward with different curvatures, respectively, and is formed so as to condense light from the LED 40 to the illumination area S1 or the areas S11 and S12. . For example, when the illumination area S1 or the coverage areas S11 and S12 are substantially rectangular, the light from the LED 40 is condensed by the rear convex lens portion 32c in the short direction of the illumination area S1 or the coverage areas S11 and S12 and transmitted. Light is further condensed by the front lens portion 32b in the longitudinal direction of the illumination area S1 or the coverage areas S11 and S12.
[0081]
FIG. 24 is an explanatory diagram of a surgical light showing an eighth embodiment of the present invention. As shown in FIG. 24, the plurality of LEDs 40 include RGB LEDs 40 that emit red, green, and blue, respectively, and the ratio of the amount of luminous flux from the red LED 40r is represented by the area of “R” in the pie chart. , The ratio of the amount of luminous flux from the green LED 40g is indicated by the area of “G” in the pie chart, and the ratio of the amount of luminous flux from the blue LED 40b is indicated by the area of “B” in the pie graph. In FIG. 24A, the ratio of the amount of light flux from each of the RGB LEDs 40 is 1/3, which is standard white light. In FIG. 24B, the ratios of the amounts of the luminous flux from the RGB LEDs 40 are 、, １ ／, and ４, respectively, and red is strong white light. Further, in FIG. 24c, the ratio of the amount of light flux from each LED 40 of RGB is ４, 、, １ ／, respectively, and green becomes strong white light. Further, in FIG. 24D, the ratios of the amounts of the luminous flux from the RGB LEDs 40 are １ ／, １ ／, and そ れ ぞ れ, respectively, and blue becomes strong white light.
[0082]
The LED control means outside the figure keeps the total amount of luminous flux from each of the RGB LEDs 40 constant and, for example, changes the ratio of the luminous flux from each of the RGB LEDs 40 as shown in FIGS. It adjusts the temperature. The LED control means performs pulse control on each of the LEDs 40, so that dimming can be performed with the lighting voltage kept constant.
[0083]
FIGS. 25A and 25B are explanatory diagrams of an operating light according to a ninth embodiment of the present invention. FIG. 25A is an explanatory diagram showing that a red LED is included in a plurality of white LEDs, and FIG. () Is an explanatory diagram showing that white LEDs of respective systems having red, green, and blue colors are arranged so as not to be collected at one place in the same system.
[0084]
As shown in FIG. 25A, the plurality of LEDs 40 include a plurality of LED modules 40M that collect two or more white LEDs 40w, and one or more red LEDs 40r. In the ninth embodiment, the LED module 40M is a collection of ten white LEDs 40w, and six LED modules 40M are arranged on the surface 21 of the substrate 20. A white LED 40w is arranged in a gap between adjacent LEDs 40 or around each LED module 40M. By turning on the red LED 40r, a red object that looks yellowish only by turning on the white LED 40w can be shown in its original color, and the color rendering properties are enhanced.
[0085]
As shown in FIG. 25b, the plurality of LEDs 40 include white LEDs 40w of each system whose color tone is red, green, and blue, and the white LEDs 40w of each system do not converge at one place in the same system. It is arranged in. In FIG. 25b, the red-based white LED 40w is indicated by “A”, the green-based white LED 40w is indicated by “B”, and the blue-based white LED 40w is indicated by “C”. By controlling the lighting of the white LED 40w of each system by an LED control unit (not shown), the color temperature can be changed to a color temperature desired by the user without changing the illuminance of the illumination area S1 or the areas S11 and S12.
[0086]
As shown in FIG. 25b, the arrangement of white LEDs 40w in the first column from the left end “AABBCC”, the arrangement of white LEDs 40w in the second column from the left end “CCAABB”, and the arrangement of white LEDs 40w in the third column from the left end “ BBCCAA "may be one module each.
[0087]
FIG. 26 is a partial cross-sectional view of the surgical light according to the tenth embodiment of the present invention, in which the front cover is cut away, and FIG. 27 is a front view of the surgical light similarly.
[0088]
As shown in FIG. 26, on the back surface 15 side of the surgical light, a heat radiating member 50 for radiating heat from the LED 40 as a light source to the outside of the surgical light is arranged. The heat dissipating member 50 is formed by forming a large number of ribs 52 on a base 51. Many pins may be formed instead of the ribs. The base 51 of the heat radiating member 50 is the back surface 15 of the surgical light. Handles 70 are attached to both side edges of the base 51. The heat from the LED 40 is transmitted from the base 51 to the rib 52, and is further radiated from the rib 52.
Thereby, the LED 40 is maintained at an appropriate temperature, and the durability of the LED 40 can be improved.
[0089]
FIG. 28 is a partial sectional view showing a surgical light according to an eleventh embodiment of the present invention, in which the back surface of the surgical light is formed of a flat surface by a metal material.
[0090]
The back surface 15 of the surgical light is formed as a flat surface with a metal material such as an aluminum material having excellent heat conduction. In the present embodiment, the back surface 15 of the surgical light has a mirror surface formed of a metal material and includes an auxiliary lighting lamp 60 for illuminating the rear of the surgical light. By turning the operating light upside down, it can be used as a mirror. The back surface 15 of the operating light may be formed by mirror plating.
[0091]
FIG. 29 is a partial perspective view of the surgical light according to the twelfth embodiment of the present invention. As shown in FIG. 29, the LEDs 40 are formed such that the light emission distribution is in a shape corresponding to any one of the illumination area S1 and the area S11 or S12.
[0092]
For example, when the illumination area S1 or the areas S11 and S12 are rectangular, the LEDs 40 are arranged so that the longitudinal direction of the light emission distribution of the LEDs 40 corresponds to the longitudinal direction of the illumination area S1 and the like. Thereby, the shape of the light emission distribution of the LED 40 corresponds to the shape of the illumination area S1 and the like, and the light from the LED 40 can be applied to the illumination area S1 and the like simply by condensing it with a simple condenser lens. .
[0093]
FIG. 30 is a perspective view of a lens module of a surgical light showing a thirteenth embodiment of the present invention, and FIG. 31 is a perspective view of the same.
[0094]
As shown in FIG. 30, the condenser lens 32 is formed so as to irradiate the light from the LED onto the substantially square area 15. Two or more of the condenser lenses 32 constitute a lens module 32M by being gathered together. In the thirteenth embodiment, one lens module 32M is configured by ten condensing lenses 32.
[0095]
As shown in FIG. 31, nine lens modules 32M are mounted on the substrate 20. In the thirteenth embodiment, the lens module 32M is formed in a shape corresponding to the shape of the illumination area S1 or any one of the areas S11 and S12. As described above, the light from the LED 40 can be condensed on the illumination area S1 or the like corresponding to the shape of the lens module 32M by the lens module 32M in which the two or more condensing lenses 32 are collected in a predetermined shape. The module 32M can be easily manufactured.
[0096]
FIG. 32 is a conceptual diagram of a surgical light showing a fourteenth embodiment of the present invention. As shown in FIG. 32A, the distribution of the radiation (emission) energy of the LED has a mountain shape, and the radiation energy of the light radiated in the direction of the optical axis L2 has the highest value, and is radiated in the direction of the optical axis L2. As the direction of the emitted light increases, the radiant energy of the light decreases.
[0097]
As shown in FIG. 32B, the condenser lens 32 condenses the light with high radiant energy from the LED 40 on the illumination area S1 or the peripheral edge S14 of the coverage areas S11 and S12, while it condenses the light with low radiation energy on the illumination area S1. Alternatively, the light is focused on the central part S13 of the responsible areas S11 and S12. Thereby, the illuminance of the central portion S13 and the peripheral edge portion S14 of the illumination area S1 or the coverage areas S11 and S12 become substantially the same, and the uniformity of the illumination area S1 or the coverage areas S11 and S12 can be increased.
[0098]
FIGS. 33 to 36 show an operating lamp according to a fifteenth embodiment of the present invention. FIG. 33 shows a case where a condenser lens and a lens supporting member are integrally formed, and light is shielded on the rear surface of the lens supporting member. FIG. 34 is a diagram in which a condensing lens and a lens support member are integrally formed, and a light-shielding material is applied to the surface of the lens support member. FIG. FIG. 36 is a view in which a gap between the lens support member and the LED is made as large as possible while a gap between the lens support member and the LED is made as large as possible. FIG. 3 is a diagram in which a gap between the lens support member and the LED is made as large as possible while a gap between the lens support member and the LED is made as small as possible, and a light shielding material is applied to the surface of the lens support member.
[0099]
As shown in FIG. 33, the condenser lens 32 and the lens support member 33 are integrally formed of a light-transmitting material, and then the front and back surfaces of the condenser lens 32 are polished, so that the lens support member 33 is formed. A light shielding material 36 is applied to the back side of the. Since the condenser lens 32 and the lens support member 33 are integrally formed, there is no need to separately manufacture and assemble them. Further, as shown in FIG. 34, a light shielding material 36 may be applied to the surface side of the lens support member 33.
[0100]
As shown in FIG. 35, a wide heat dissipation gap SL is formed between the lens support member 33 and the LED 40, and heat is emitted from the LED 40 to the heat dissipation gap SL. Further, the rear surface 37 of the condenser lens 32 may be made to protrude from the lens support member 33 toward the LED 40 (toward the rear), so that the rear surface 37 side of the condenser lens 32 may be made closer to the LED 40.
[0101]
Also, in FIG. 35, similarly to FIGS. 33 and 34, the condenser lens 32 and the lens support member 33 are integrally formed of a light-transmitting material. The light-blocking material 36 is applied to the back side of the lens support member 33. Further, as shown in FIG. 36, a light shielding material 36 may be applied to the surface side of the lens support member 33.
[0102]
FIGS. 37 and 38 show a surgical light according to a sixteenth embodiment of the present invention. FIG. 37 shows an arrangement in which a condenser lens is arranged in a matrix on a lens support member, and the condenser lens and the lens support member are arranged in a matrix. (A) is a front view, (b) is a cross-sectional view taken along the line bb of (a), and FIG. 38 is similarly formed integrally with a condenser lens and a lens support member. FIG. 3A is a front view and FIG. 3B is a bottom view in which a light-blocking material is applied to a lens supporting member.
[0103]
As shown in FIG. 37, the condenser lens 32 is formed in a substantially semi-spherical shape, is arranged in a matrix on a flat lens support member 33, and has a plurality of condenser lenses 32 and a lens support member 33. Are integrally formed of a light-transmitting material. Further, as shown in FIG. 38, a light-blocking material 36 is applied on the surface side of the lens support member 33, and almost all of the light from the LED 40 is made to enter the condenser lens 32, so that unnecessary diffusion of light is prevented. Preventing. 38, the light blocking material 36 may be applied to the back surface side of the lens support member 33.
[0104]
In the above-described embodiment, the plurality of LEDs 40 are arranged in a matrix on the surface 21 of the substrate 20. However, the LEDs 40 may be arranged so as to be substantially uniformly dispersed on the surface 21 of the substrate 20.
[0105]
In the above embodiment, the curved surface 22 of the substrate 20 and the concave surface 31a of the front cover 31 are formed as a paraboloid of revolution, a hyperboloid, a spheroid, and a sphere. It may not be an object surface or the like, but may be a curved surface approximating this.
[0106]
Further, in the embodiment, the curved surface 22 of the substrate 20 and the concave surface 31a of the front cover 31 are described as one smooth curved surface, but the substrate 20 and the front cover 31 are divided into a plurality of regions, respectively. Each region may be formed by a predetermined curved surface.
[0107]
Further, in the above embodiment, the front convex lens portion 32b extends in a cylindrical shape along the row where the LEDs 40 are arranged, and the rear convex lens portion 32c extends in a cylindrical shape along the row where the LEDs 40 are arranged. Although the extension is shown, the opposite aspect, that is, the front convex lens portion 32b extends along the row where the LEDs 40 are arranged, and the rear convex lens portion 32c extends along the row where the LEDs 40 are arranged. May extend in a cylindrical shape.
[0108]
【The invention's effect】
According to the surgical light according to the present invention, the plurality of LEDs are arranged so as to spread along the surface of the substrate, and the optical system is arranged so as to individually condense light from each LED to the entire illumination area. Therefore, the configuration is such that the light quantity loss of the LED is small, and a sufficient light quantity can be obtained even with a small number of LEDs, so that the cost can be reduced. In addition, since each LED arranged on the boat is a small light source, light from the light source can be easily focused on the illumination area. Further, since the plurality of condenser lenses are formed integrally with the front cover, the number of components is greatly reduced, and the production cost and the assembly cost can be reduced. Further, even if a light-shielding object enters the light path of the LED, no image is generated in the illumination area, and the degree of shadowlessness can be improved.
[0109]
Further, since the condensing lens is arranged to collect the light from the LED at one point before the illumination area, a condensing lens having a small outer diameter may be used, and the condensing lens between the adjacent condensing lenses may be used. Since the distance becomes shorter, the operating light can be made smaller. Further, since a plurality of reflecting mirrors are formed so as to individually reflect and condense the light from each LED to the entire illumination area, the light from each LED can be condensed on the illumination area, The configuration is low in loss, and a sufficient amount of light can be obtained.
[0110]
Furthermore, since the reflecting mirror is formed so as to reflect the light from the LED and collect it at one point before the illumination area, a reflecting mirror having a small outer diameter may be used. It is shorter and the operating light can be made smaller. Furthermore, since the surface of the substrate has a curved surface recessed in the direction opposite to the illumination area, and the curved surface is formed so that the direction of the optical axis of the LED arranged on the curved surface is directed toward the center of the illumination area, For example, simply by mounting the LED on the surface of the substrate, the direction of the optical axis of the LED automatically turns to the center of the illumination area, so that the LED can be easily aligned.
[0111]
The front cover has a concave surface recessed in a direction opposite to the illumination area, and the concave surface is formed so that the direction of the optical axis of the condenser lens formed integrally with the illumination cover is directed toward the center of the illumination area. Is formed, a plurality of condenser lenses integrally formed with the front cover can be made to have the same shape, which facilitates the manufacture of the front cover.
[0112]
A plurality of condenser lenses are respectively arranged along the surface of the substrate, and a lens support member supports the plurality of condenser lenses so as to correspond to the plurality of LEDs, respectively, and aligns each optical axis of the plurality of condenser lenses. Since the respective optical axes of the plurality of LEDs are made to coincide with each other, for example, the entire lens support member is formed into a curved surface like the surface of the substrate, or, for example, a mounting hole for mounting a condenser lens. , It is possible to make each optical axis of the condensing lens coincide with each optical axis of a plurality of LEDs, and it is necessary to prepare various shapes of condensing lenses corresponding to the positions where the LEDs are arranged. Therefore, the same condenser lens can be used for a plurality of condenser lenses, and the manufacturing cost and assembly cost of the condenser lens can be reduced.
[0113]
Since the light from the LEDs related to the group is condensed on the responsible area by the condenser lens, for example, the illuminance at the peripheral part around the central part is lower than the illuminance at the central part of the responsible area. In such a case, in the adjacent receiving area, if the illuminance is increased by overlapping the peripheral portions of the receiving area, the uniformity of the illumination area is increased, and uniform brightness is realized to every corner of the illumination area. Can be.
[0114]
The condenser lens includes a front convex lens part protruding forward from the front of the condenser lens, and a rear convex lens part protruding backward from the back of the condenser lens, and a plurality of front convex lens parts are arranged with LEDs. Each of which has a cylindrical shape extending along one of the rows or columns, and is formed so as to be continuous with each other, and a plurality of rear convex lens portions each extend in a cylindrical shape along the other of each row or each column, and Since it is formed so as to be continuous, it is possible to reduce the manufacturing cost and the assembly cost of the condenser lens without forming a plurality of condenser lenses individually and assembling them individually.
[0115]
Each of the front convex lens portion and the rear convex lens portion protrudes forward and rearward with a different curvature from each other, and is formed so as to condense light from the LED to the illumination area or the responsible area, so that the light from the LED is By condensing light in one direction by the rear convex lens part and further condensing it in the other direction by the front convex lens part, light from each LED can be condensed to the illumination area or the responsible area.
[0116]
The plurality of LEDs include RGB LEDs that emit red, green, and blue colors, and the LED control unit controls the lighting of each of the RGB LEDs, so that the total amount of light flux from each of the RGB LEDs is constant. Without changing the illuminance of the illumination area or the assigned area, the ratio of the luminous flux from each of the RGB LEDs can be changed to change the color temperature desired by the user, thereby improving the usability.
[0117]
Since one or two or more red LEDs are included in a plurality of LED modules each of which collects two or more white LEDs, for example, a red object that looks yellowish due to lack of a red component only by turning on the white LEDs, By turning on the red LED, the original color can be seen, and the color rendering can be enhanced.
[0118]
Includes red LEDs, green LEDs, and white LEDs of each system whose color tone is blue, and the white LEDs of each system are arranged so that they do not converge at one place in the same system. By doing so, the color temperature can be changed to a color temperature desired by the user without changing the illuminance of the illumination area or the assigned area.
[0119]
Since the heat radiating member is arranged on the back side of the operating light, the heat radiating member radiates heat from the back side of the operating light, so that the inside of the operating light is not heated and the durability of the LED can be increased. Further, since the rear surface of the surgical light is formed as a flat surface by a metal material, the heat radiation effect from the rear surface side of the surgical light can be enhanced. Furthermore, since the back surface of the surgical light is formed in a mirror surface by a metal material and an auxiliary lighting for illuminating the back of the surgical light is provided, the surgical light can be used as a mirror by turning the light upside down. By turning on the auxiliary lighting, it is possible to illuminate the object reflected in the mirror.
[0120]
Since the LED is formed such that the light emission distribution of the LED corresponds to any one of the shape of the illumination area and the area of responsibility, the light area from the LED or the area of charge is simply collected by collecting the light from the LED. Since irradiation is performed, there is no need to use a special lens, and the manufacturing cost of the condenser lens can be reduced.
[0121]
A condensing lens is formed so as to irradiate light from the LED onto a substantially square area, and two or more of the condensing lenses form a lens module by converging with each other, and the lens module is provided in either an illumination area or a responsible area. Since it is formed in a shape corresponding to one shape, simply collecting the condensing lenses into a lens module of an appropriate shape collects the light from the LED in an illumination area or an area corresponding to the shape of the lens module. The light can be illuminated, and the condenser lens can be easily designed.
[0122]
The condenser lens was formed so that the light with high radiant energy from the LED was condensed on the periphery of the illumination area or the area where the light was emitted, while the light with low radiant energy was condensed on the center of the illumination area or area where the charge was. The illuminance at the center and the periphery of the illuminated area or area is almost the same, the uniformity of the illuminated area or area is increased, and uniform brightness is achieved at every corner of the illuminated area or area. Can be.
[0123]
Since the lens support member and the condenser lens are integrally formed, and a light-blocking material is applied to at least one of the front side and the back side of the lens support member, the lens support member and the condenser lens are separately manufactured and assembled. There is no need, and manufacturing and assembly costs can be reduced.
[0124]
Since a heat-dissipating gap for releasing heat from the LED is formed between the lens support member and the LED, the heat from the LED is released to the heat-dissipating gap, and the heat from the LED is efficiently released. By preventing the LED from overheating, the durability of the LED is increased. On the other hand, almost all of the light from the LED is collected by projecting the condenser lens from the lens support member toward the LED and approaching the LED. Since the light is made to enter the lens, the diffusion of light from the LED can be suppressed, and the light from the LED can be condensed to the illumination area without waste by the condenser lens.
[Brief description of the drawings]
FIG. 1 is a plan view of an operating light according to a first embodiment of the present invention, showing a state in which light from a central LED is focused on an entire illumination area.
FIG. 2 is a side view of the surgical light, showing a state in which light from a central LED is focused on the entire illumination area.
FIG. 3 is a plan view of the surgical light, showing how light from each LED is individually focused on the entire illumination area.
FIG. 4 is a side view of the surgical light, showing how light from each LED is individually focused on the entire illumination area.
FIG. 5 is a front view of the surgical light.
FIG. 6 is a partially enlarged plan view of the surgical light, showing a condenser lens as an optical system.
FIG. 7 is a partially enlarged plan view of the surgical light, showing a condensing lens as an optical system, and collecting light from an LED at one point before an illumination area.
FIG. 8 is a front view of the surgical light.
FIG. 9 is a front view of the surgical light, showing a condenser lens having a rectangular cross-sectional shape.
FIG. 10 is a partial plan view of a surgical light according to a second embodiment of the present invention, showing a Fresnel lens as an optical system.
FIG. 11 is a front view of a surgical light showing a second embodiment of the present invention.
FIG. 12 is a front view of an operating light showing a second embodiment of the present invention.
FIG. 13 is a plan view of a surgical light according to a third embodiment of the present invention.
FIG. 14 is a side view of an operating light according to a third embodiment of the present invention.
FIG. 15 is a partial plan view of an operating light according to a fourth embodiment of the present invention, showing a reflecting mirror as an optical system.
FIG. 16 is a partial plan view of an operating light showing a fourth embodiment of the present invention, in which light from an LED reflected by a reflector is collected at one point before an illumination area. is there.
FIG. 17 is a partial plan view of an operating light according to a fifth embodiment of the present invention, showing a condenser lens and a reflecting mirror as an optical system.
FIG. 18 is a partial plan view conceptually showing a surgical light according to a sixth embodiment of the present invention, in which each LED and each condenser lens are arranged along a curved surface that is recessed together, and FIG. 4 is a diagram in which light axes from an LED are focused on the entire irradiation area by a focusing lens by aligning each optical axis with a focusing lens.
FIG. 19 is a partial plan view conceptually showing the surgical light, in which the optical axes of the LED and the condensing lens are aligned, and light from the LED is condensed by the condensing lens. Is different for each LED.
FIG. 20 is a partial plan view conceptually showing an operating light, in which the optical axes of an LED and a condenser lens are matched, and a plurality of LEDs are divided into two groups; FIG. 5 is a diagram in which light from such an LED is collected by a condensing lens in a region where the LED is responsible.
FIG. 21 is a partial perspective view mainly showing a condenser lens of an operating light according to a seventh embodiment of the present invention.
FIG. 22 is a view on arrow XXII of FIG. 21;
FIG. 23 is a view on arrow XXIII of FIG. 21;
FIG. 24 is an explanatory diagram of an operating light according to an eighth embodiment of the present invention, in which the ratio of the luminous flux from each of the RGB LEDs is changed while the total amount of luminous flux from each of the RGB LEDs is kept constant. FIG. 9 is a diagram showing that the color temperature is adjusted by changing the color temperature.
FIGS. 25A and 25B are explanatory diagrams of an operating light according to a ninth embodiment of the present invention, in which FIG. 25A is an explanatory diagram showing that a plurality of white LEDs include a red LED, and FIG. () Is an explanatory diagram showing that white LEDs of respective systems having red, green, and blue colors are arranged so as not to be collected at one place in the same system.
FIG. 26 is a partial cross-sectional view showing the front cover of the surgical light according to the tenth embodiment of the present invention.
FIG. 27 is also a front view of the surgical light.
FIG. 28 is a partial sectional view showing a surgical light according to an eleventh embodiment of the present invention, in which a back surface of the surgical light is formed as a flat surface by a metal material.
FIG. 29 is a surgical light according to a twelfth embodiment of the present invention, showing an LED formed so as to have a light emission distribution in a shape corresponding to any one of an illumination area and a responsible area. It is.
FIG. 30 is a perspective view of a lens module of an operating light according to a thirteenth embodiment of the present invention.
FIG. 31 is a perspective view of the surgical light, in which a plurality of lens modules formed in a shape corresponding to any one of the illumination area and the receiving area are incorporated.
FIGS. 32A and 32B show a surgical light according to a fourteenth embodiment of the present invention, in which FIG. 32A shows a distribution of radiant (emission) energy of the LED, and FIG. FIG. 6 is a diagram showing that light with high radiant energy from the light source is focused on the periphery of an illumination area or a responsible area, while light with low radiant energy is focused on the center part of the illumination area or the responsible area.
FIG. 33 is a diagram showing a surgical light according to a fifteenth embodiment of the present invention, in which a condenser lens and a lens support member are integrally formed, and a light blocking material is applied to the back surface of the lens support member. .
FIG. 34 is a diagram showing a surgical light according to the fifteenth embodiment, in which a condenser lens and a lens support member are integrally formed, and a light-shielding material is applied to the surface of the lens support member.
FIG. 35 is also a surgical light according to a fifteenth embodiment, wherein the gap between the condenser lens and the LED is made as small as possible, while the gap between the lens support member and the LED is made as large as possible. FIG. 3 is a diagram in which a light blocking material is applied to the back surface of a lens support member.
FIG. 36 is a surgical light according to a fifteenth embodiment, in which the gap between the condenser lens and the LED is made as small as possible, while the gap between the lens support member and the LED is made as large as possible. FIG. 3 is a diagram in which a light shielding material is applied to the surface of a lens support member.
FIG. 37 is a surgical light according to a sixteenth embodiment of the present invention, in which condensing lenses are arranged in a matrix on a lens supporting member, and the condensing lens and the lens supporting member are integrally formed. FIG. 3A is a front view, and FIG. 3B is a cross-sectional view taken along line bb of FIG.
FIG. 38 is also a diagram in which a condensing lens and a lens supporting member are integrally formed, wherein a light shielding material is applied to the lens supporting member, (a) is a front view, and (b) is a bottom surface. FIG.
[Explanation of symbols]
G11, G12… Group
L1 ... Light path
L2: Optical axis
S1: Lighting area
S11, S12: Responsible area
S13: Central part
S14: Peripheral part
S15: Substantially square area
SL: gap for heat dissipation
10 ... body
15 ... Back side
20 ... substrate
21 ... surface
22 ... Curved surface
30 Optical system
31 Front cover
31a ... concave surface
32 ... Condensing lens
32a ... Fresnel lens
32b ... front convex lens part
32c: rear convex lens part
32s ... Lens surface
32M ... Lens module
33 ... Lens support member
33a: Mounting surface
33b ... Mounting hole
35 ... Reflector
36 ... Shading material
37 ... Back of condenser lens
40 ... LED
40b… Blue LED
40g… green LED
40r red LED
40w ... white LED
40M LED module
41 ... Light-emitting unit
50: heat dissipation member
51 ... Base
52 ... rib
60… Auxiliary lighting
70 ... handle

Claims (22)

The light from the light source is focused on the illumination area, and in a surgical light having a substrate and an optical system,
The light source includes a plurality of LEDs,
The substrate is arranged so that a surface of the substrate faces the illumination area,
The plurality of LEDs are arranged to extend along a surface of the substrate,
The operating light is characterized in that the optical system is arranged so as to individually condense light from each LED to the entire illumination area. A front cover for covering the plurality of LEDs from the front,
The optical system includes a plurality of condenser lenses,
The plurality of condenser lenses are respectively arranged corresponding to each LED,
Further, a plurality of condenser lenses are formed integrally with the front cover. The operating light according to claim 2, wherein the condenser lens is arranged to collect the light from the LED at one point before the illumination area. The optical system includes a plurality of reflecting mirrors,
The plurality of reflecting mirrors are respectively arranged corresponding to each LED,
3. The shadowless mirror according to claim 1, wherein the plurality of reflecting mirrors are formed so as to reflect and collect light from the LEDs individually to the entire illumination area. 4. light. The operating light according to claim 4, wherein the reflecting mirror is formed so as to reflect light from the LED and collect the light at one point before the illumination area. The surface of the substrate has a curved surface recessed in a direction opposite to the illumination area,
The surgical light according to claim 1, wherein the curved surface is formed so as to direct an optical axis of an LED disposed on the curved surface toward a center of the illumination area. The front cover has a concave surface that is concave in a direction opposite to the illumination area,
The said recessed surface is formed so that the direction of the optical axis of the condensing lens integrally formed with the said illumination cover may be turned to the center part of the said illumination area, The claim 2 characterized by the above-mentioned. Operating light. The light from the light source is focused on the illumination area, and in a surgical light having a substrate and an optical system,
The light source includes a plurality of LEDs,
The plurality of LEDs are arranged to extend along a surface of the substrate,
The surface of the substrate has a curved surface recessed in a direction opposite to the illumination area,
The curved surface is formed so as to direct a direction of an optical axis of an LED arranged on the curved surface to the illumination area,
The optical system, a plurality of condenser lenses respectively arranged along the surface of the substrate, and a lens support member for supporting the plurality of condenser lenses corresponding to the plurality of LEDs, respectively. With
The operating light is characterized in that the lens support member is formed so that each optical axis of the plurality of condenser lenses coincides with each optical axis of the plurality of LEDs. The plurality of LEDs are divided into two or more groups,
The illuminated area includes a responsible area that is an area assigned to the group, and the condensing lens is arranged to collect light from the LEDs related to the group to the assigned area. The operating lamp according to claim 8, wherein The plurality of LEDs are arranged in a matrix,
The condenser lens includes a front convex lens portion that projects forward from the front of the condenser lens, and a rear convex lens portion that projects rearward from the back of the condenser lens,
The plurality of front convex lens portions extend in a cylindrical shape along one of each row or each column where the LEDs are arranged, and are formed so as to be continuous with each other,
The plurality of rear convex lens portions each extend in a cylindrical shape along the other of each row or each column, and are formed so as to be continuous with each other. Surgical light. Each of the front convex lens portion and the rear convex lens portion is projected forward and rearward with a different curvature from each other, and is formed so as to condense light from an LED to the illumination area or the responsible area. The surgical light according to any one of claims 1 to 10, wherein: The plurality of LEDs include RGB LEDs that emit red, green, and blue colors, respectively, and control the lighting of each of the RGB LEDs so that the total amount of luminous flux from each of the RGB LEDs remains constant. 12. The operating light according to claim 1, further comprising an LED control unit configured to adjust a color temperature by changing a ratio of light beams from each of the RGB LEDs. . The operating light according to any one of claims 1 to 11, wherein the plurality of LEDs include a plurality of LED modules including two or more white LEDs and one or two or more red LEDs. . The plurality of LEDs include a white LED of each system whose color tone is red, green, and blue,
The operating light according to any one of claims 1 to 11, wherein the white LEDs of each system are arranged so as not to be gathered at one place in the same system. The heat radiation member for releasing heat from the light source to the outside of the surgical light is disposed on a back surface side of the surgical light. Shadow light. The surgical light according to any one of claims 1 to 14, wherein a back surface of the surgical light is formed as a flat surface by a metal material. The back surface of the operating light is formed in a mirror surface by a metal material,
The surgical light according to any one of claims 1 to 14, further comprising an auxiliary light for illuminating the rear of the surgical light. The said LED is formed so that the light emission distribution of the said LED may become in the shape corresponding to any one shape of the said illumination area | region or the said responsible area | region. Surgical light. The condenser lens is formed so as to irradiate light from the LED onto a substantially square area,
Two or more of the condensing lenses form a lens module by converging with each other, and the lens module is formed in a shape corresponding to any one of the illumination area and the responsible area. The surgical light according to any one of claims 1 to 18. The condensing lens focuses light with high radiation energy from the LED on the periphery of the illumination area or the responsible area, and focuses light with low radiation energy on the central part of the illumination area or the responsibility area. The surgical light according to any one of claims 1 to 19, wherein the surgical light is formed to emit light. The lens support member and the condenser lens are integrally formed,
21. The surgical light according to claim 1, wherein a light-shielding material is applied to at least one of a front side and a rear side of the lens support member. Between the lens support member and the LED, a gap for heat radiation for releasing heat from the LED is formed,
The condensing lens is arranged so as to project almost all of the light from the LED to the condensing lens by projecting from the lens support member toward the LED and approaching the LED. The surgical light according to any one of claims 1 to 21, characterized in that:

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