JP7011870B1 - Lighting equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting device capable of illuminating not only a user's hand but also a user's face without disturbing the surroundings.
SOLUTION: A lighting device attached to a display of a computer and illuminating a user's hand has a first light source that emits a first illumination light toward the user's hand and a second light source toward the user's face. A second light source that emits illumination light, a control unit that controls the first light source and the second light source, an operation unit that receives input from the user and outputs a control signal to the control unit, and a first light source and a second light source. It is characterized by including a main body portion that accommodates a control unit and an operation unit and extends substantially horizontally along the upper end portion of the display, and a hooking portion that supports the main body portion and hooks on the upper end portion of the display. do.
[Selection diagram] Fig. 1

Description

The present invention relates to a lighting device that is attached to a computer display and illuminates the user's hand.

In recent years, with the spread of telework, opportunities for online conferences using computers are increasing. In such an online conference, the computer (that is, the user) is not always under ideal lighting, and depending on the environment in which the computer is installed, there is no space for installing an existing desk light. Materials and keyboards may be difficult to see. As described above, when the working environment is dark, a lighting device that illuminates the user's hand is used (for example, Patent Document 1).

Patent Document 1 describes a light source unit that can be detachably attached to the upper part of a computer display. This light source unit has a plurality of LED elements built-in, and is configured to irradiate a keyboard arranged below the display with illumination light from above.

Japanese Patent Application Laid-Open No. 2003-2208

According to the light source unit of Patent Document 1, even when the work environment is dark, the keyboard and the like are brightly illuminated, so that the work can be performed comfortably without disturbing the surroundings.
However, the light source unit of Patent Document 1 illuminates only the user's hand such as a keyboard, and is therefore unsuitable for online conferencing. That is, when the light source unit of Patent Document 1 is used in an online conference in a dark environment, the conference materials and the keyboard at the user's hand are illuminated, but the user's face photographed by the camera still appears dark. There is a problem that the image quality in an online conference is poor (that is, it is not suitable for an online conference).

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a lighting device capable of illuminating not only the user's hand but also the user's face without disturbing the surroundings.

In order to achieve the above object, the lighting device of the present invention is a lighting device that is attached to a display of a computer and illuminates the user's hand, and is a first lighting device that emits a first illumination light toward the user's hand. A light source, a second light source that emits white second illumination light toward the user's face, a control unit that controls the first light source and the second light source, and a control unit that receives input from the user and sends a control signal to the control unit. The operation unit that outputs It is characterized in that it is provided with a hooking portion for hooking.

According to such a configuration, the user's hand and the user's face are illuminated, so that when used in an online conference in a dark environment, the conference materials and keyboard at hand can be easily seen and at the online conference. The image quality is good.

Further, it is desirable that the first light source has a first substrate extending substantially horizontally along the upper end portion of the display, and a plurality of first LED elements arranged on the surface of the substrate. Further, in this case, it is desirable that the plurality of first LED elements are composed of a plurality of white LED chips that emit white light and a plurality of bulb-colored LED chips that emit light bulb-colored light. Further, the control unit controls the emission intensity of at least one of the white LED chip and the light bulb color LED chip according to the control signal to change the illuminance of the first illumination light, and the white LED chip and the light bulb. It is desirable to control the first light source by a second mode in which the emission intensity of the color LED chip is controlled and the illumination color of the first illumination light is changed.

Further, the second light source has a plurality of second LED elements that emit white light, and the control unit controls the emission intensity of the second LED element according to the control signal to change the illuminance of the second illumination light. It is desirable to control the second light source by the third mode. Further, in this case, it is desirable that the control unit reduces the emission intensity of the white LED chip and the light bulb color LED chip according to the illuminance of the second illumination light in the third mode.

Further, it is desirable that the main body portion has a light guide plate that guides the second illumination light to the outside of the main body portion.

Further, it is desirable to further have a third light source that emits the third illumination light from the main body portion. Further, in this case, the third light source has at least one third LED element that emits at least red, green, and blue light, and the control unit determines the emission color of the third LED element according to the control signal. It is desirable to control the third light source by a fourth mode that changes at a predetermined cycle.

Further, the hooking portion protrudes from the weight portion arranged so as to be in contact with the back surface of the display, the arm portion connecting between the weight portion and the main body portion, and the arm portion so as to be in contact with the front surface of the display. It is desirable to have a tongue, and the weight and tongue to hold the display. Further, in this case, the weight portion and the arm portion are relatively rotatable with respect to the first rotation axis extending substantially horizontally along the upper end portion of the display, and the arm portion and the main body portion are the upper end portion of the display. It is desirable that the rotation is relatively possible with respect to the second rotation axis extending substantially horizontally along the axis.

It is also desirable that the lighting device be driven by the power supplied from the USB port of the computer.

As described above, according to the lighting device of the present invention, it is possible to illuminate not only the user's hand but also the user's face. Therefore, even in an online conference in a dark environment, the conference materials and keyboard at hand can be easily seen, and the image quality in the online conference is also good.

FIG. 1 is a diagram showing a configuration of a lighting device according to an embodiment of the present invention. FIG. 2 is a schematic diagram illustrating a state of illumination light emitted from the illumination device according to the embodiment of the present invention. FIG. 3 is an exploded perspective view showing the internal configuration of the main body of the lighting device according to the embodiment of the present invention. FIG. 4 is a cross-sectional view taken along the line AA of FIG. 1 (c). FIG. 5 is a plan view illustrating the configuration of the light source unit of the lighting device according to the embodiment of the present invention. FIG. 6 is a block diagram illustrating an electrical connection of a lighting device according to an embodiment of the present invention. FIG. 7 is a flowchart of a white LED lighting process executed by the lighting device according to the embodiment of the present invention. FIG. 8 is a flowchart of the brightness adjustment process executed by the lighting device according to the embodiment of the present invention. FIG. 9 is a flowchart of the whiteness adjustment process executed by the lighting device according to the embodiment of the present invention. FIG. 10 is a flowchart of a face LED / color LED lighting process executed by the lighting device according to the embodiment of the present invention. FIG. 11 is a flowchart of a face LED / color LED lighting process executed by the lighting device according to the embodiment of the present invention. FIG. 12 is a flowchart of a face LED / color LED lighting process executed by the lighting device according to the embodiment of the present invention. FIG. 13 is a flowchart of a face LED / color LED lighting process executed by the lighting device according to the embodiment of the present invention. FIG. 14 is a diagram showing a state (posture) when the lighting device according to the embodiment of the present invention is hooked on the upper end portion of the display.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals and the description thereof will not be repeated.

1 is a diagram showing the configuration of the lighting device 1 according to the embodiment of the present invention, FIG. 1A is a perspective view of the lighting device 1 when viewed from diagonally forward, and FIG. 1B is a perspective view. Is a perspective view of the illuminating device 1 when viewed from diagonally rearward, and FIG. 1 (c) is a bottom view of the illuminating device 1. FIG. 2 is a schematic diagram illustrating a state of illumination light emitted from the illumination device 1.
As shown in FIG. 2, the lighting device 1 of the present embodiment is a device used by being attached to the upper end portion of the display D of the computer, and is a lighting light L1 (first lighting light) that illuminates the hand of the user U. , The illumination light L2 (second illumination light) that illuminates the face of the user U is emitted (FIG. 2A). Further, illumination light L3 (third illumination light) that functions as decorative light (illumination) is emitted from the diffuser plates 103 arranged at both ends in the X-axis direction of the illumination device 1 (FIG. 2 (b)). In this specification, as shown in the coordinates of FIGS. 1 and 2, the arrangement direction of the white LED chip 115 and the light bulb color LED chip 116, which will be described later, is the X-axis direction, the vertical direction is the Z-axis direction, and the X-axis direction. And the direction orthogonal to the Z-axis direction is defined as the Y-axis direction and will be described.

As shown in FIG. 1, the lighting device 1 of the present embodiment includes a main body 100 that emits illumination lights L1 to L3 , a hook 200 that supports the main body 100 and hooks on the upper end of the display D. It is equipped with.

FIG. 3 is an exploded perspective view showing the internal configuration of the main body 100. Further, FIG. 4 is a cross-sectional view taken along the line AA of FIG. 1 (c).
As shown in FIGS. 1 to 4, the main body 100 extends long in the X-axis direction and includes a case 101 having a substantially rhombic cross section. The case 101 includes a window portion 102 on which the illumination light L1 is emitted on the bottom surface (Z-axis direction-side surface) side, and inside, a light source unit 110 (first light source) and a face LED substrate 120 (second light source). , MPU (Micro Processor Unit) board 130 (control unit) is provided. Further, the case 101 includes a diffusion plate 103 at both ends in the X-axis direction, a side cover 104 that covers the outside of the diffusion plate 103, a light guide plate 105 on the front surface, and a sensor cover 106 on the upper surface. The lighting device 1 of the present embodiment is electrically connected to a computer (not shown) via a USB cable C, and power is supplied from the USB port of the computer (FIG. 4).

FIG. 5 is a plan view illustrating the configuration of the light source unit 110. Further, FIG. 6 is a block diagram illustrating an electrical connection of the lighting device 1 of the present embodiment.
As shown in FIG. 5, the light source unit 110 includes a rectangular plate-shaped substrate 112 extending in the X-axis direction, a plurality of (for example, 40) white LED chips 115 (first LED elements), and a plurality (for example, 40). ), A light bulb color LED chip 116 (first LED element), two color LED chips 117 (third light source, third LED element), and an MPU 118.

The plurality of white LED chips 115 and the plurality of light bulb color LED chips 116 are arranged on the surface of the substrate 112 every other time with the optical axes aligned in the direction perpendicular to the substrate 112 and at predetermined intervals in the X-axis direction. , Is electrically connected to the substrate 112. Further, the two color LED chips 117 are arranged at both left and right (X-axis directions) ends of the substrate 112 with their optical axes facing the outside of the substrate 112 (that is, toward the + side and the-side in the X-axis direction), respectively. And is electrically connected to the substrate 112. Further, the board 112 is electrically connected by a wiring cable (not shown) extending from the MPU board 130, and the MPU board 130 is connected to each white LED chip 115, each light bulb color LED chip 116, and each color LED chip 117. The drive current from is supplied from.
When a drive current is supplied to each white LED chip 115, white light having an amount of light corresponding to the drive current is emitted from each white LED chip 115. Further, when a drive current is supplied to each light bulb color LED chip 116, light bulb color light having a light amount corresponding to the drive current is emitted from each light bulb color LED chip 116. As described above, in the present embodiment, since the plurality of white LED chips 115 and the plurality of light bulb color LED chips 116 are arranged in every other arrangement, the white light from the white LED chip 115 and the light bulb color LED chip 116 The bulb-colored light from is emitted in an overlapping (ie, mixed) manner in the light path. Then, the white light emitted from each white LED chip 115 and the light bulb color emitted from each light bulb color LED chip 116 are emitted through the window portion 102 arranged in the optical path, and are in the hands of the user U. Illuminate. In the present embodiment, the drive current of the white LED chip 115 and the drive current of the bulb color LED chip 116 are configured to be adjustable by the control of the MPU 131, whereby the illumination light L1 (white light and the bulb color) is configured. It is possible to adjust the illumination color (whiteness) of the mixed light of the light.

When a drive current is supplied to the two color LED chips 117, color light (red, green, blue and mixed colors thereof) having an amount of light corresponding to the drive current is emitted from each color LED chip 117 as illumination light L3. Will be done. As described above, in the present embodiment, the optical axes are arranged at both left and right (X-axis directions) ends of the substrate 112 toward the outside of the substrate 112 (that is, toward the + side and the-side in the X-axis direction), respectively. Therefore, the color light emitted from each color LED chip 117 is diffused by the diffuser plate 103 arranged in the optical path, and is emitted from the end surface of the diffuser plate 103. In the present embodiment, the color light emitted from the diffuser plate 103 functions as so-called decorative light (illumination). The drive current of each color LED chip 117 is configured to be adjustable by the control of the MPU 118 under the instruction from the MPU 131, whereby the color of the color light (that is, the emission color of the color LED chip 117) is determined at a predetermined timing. So, for example, it changes in the order of "green-> yellow-> red-> pink-> purple-> blue-> light blue-> green".

The face LED substrate 120 includes a rectangular plate-shaped substrate 122 extending in the X-axis direction and a plurality (for example, three) white LED elements 125 (second LED elements) (FIG. 3). The plurality of white LED elements 125 are arranged in a row on the surface of the substrate 122 at predetermined intervals in the X-axis direction, and are electrically connected to the substrate 122. Further, the substrate 122 is electrically connected by a wiring cable (not shown) extending from the MPU substrate 130, and the drive current from the MPU substrate 130 is supplied to each white LED element 125. .. When a drive current is supplied to each white LED element 125, white light having an amount of light corresponding to the drive current is emitted from each white LED element 125 as illumination light L2. Then, the white light emitted from the white LED element 125 is guided by the light guide plate 105 arranged in the optical path of the white LED element 125 and emitted to illuminate the face of the user U.
As described above, in the present embodiment, the face of the user U is illuminated by lighting the white LED element 125 on the face LED substrate 120. In the present embodiment, the white LED element 125 is driven by PWM (Pulse Width Modulation) at a reference frequency of 20 kHz under the control of the MPU 131, whereby the amount of light is adjusted.

The MPU board 130 is electrically connected to the light source unit 110 and the face LED board 120, and the white LED chip 115, the light bulb color LED chip 116, and the color LED of the light source unit 110 are received according to the input (operation) from the user U. It is an electronic circuit that controls the light source of the white LED element 125 of the chip 117 and the face LED substrate 120.
As shown in FIG. 6, the MPU board 130 of the present embodiment has an MPU 131 (control unit), a first sensor 132 to a fourth sensor 135 (operation unit), an LED driver 136, 137, and a USB connector 139. ..

The MPU 131 is composed of a calculation unit (not shown) that executes logical operations, a RAM (not shown) in which data and the like are temporarily stored, a ROM (not shown) in which a control program is stored, and the like, and the entire lighting device 1. It has a function to control. The MPU 131 is electrically connected to the first sensor 132 to the fourth sensor 135 (operation unit) and the LED driver 136 and 137, and is stored in a ROM (not shown) when the power is input to the lighting device 1. Read the control program and control each of these parts (details will be described later).

The first sensor 132 to the fourth sensor 135 are user interfaces (switches) that receive input from the user U and output a control signal to the MPU 131. The first sensor 132 of the present embodiment is a so-called touchless sensor composed of a photo interrupter or the like, and the second sensor 133 to the fourth sensor 135 are touch sensors and are arranged directly under the sensor cover 106. ing. Therefore, when the user U points or touches the position corresponding to each of the first sensor 132 to the fourth sensor 135 on the sensor cover 106, the MPU 131 is moved from the first sensor 132 to the fourth sensor 135. It recognizes the input and executes the process assigned to each of the first sensor 132 to the fourth sensor 135.

In the present embodiment, the first sensor 132 is a switch for controlling the on / off of the white LED chip 115 and the light bulb color LED chip 116 of the light source unit 110, and corresponds to the first sensor 132 on the sensor cover 106. By holding a finger over the position, the white LED chip 115 and the light source color LED chip 116 are turned on / off.
Further, the second sensor 133 is a switch that controls the brightness (illuminance) of the illumination light L1 emitted from the light source unit 110, and by touching the position corresponding to the second sensor 133 on the sensor cover 106. , The total of the light amount (light emission intensity) of the white LED chip 115 and the light bulb color LED chip 116 changes stepwise.
Further, the third sensor 134 is a switch that controls the color (whiteness) of the illumination light L1 emitted from the light source unit 110, and by touching the position corresponding to the third sensor 134 on the sensor cover 106. , The balance (ratio) of the amount of light of the white LED chip 115 and the amount of light (light emission intensity) of the light bulb color LED chip 116 changes stepwise, thereby changing the illumination color (whiteness) of the illumination light L1.
Further, the fourth sensor 135 is a switch that controls the brightness of the illumination light L2 emitted from the face LED substrate 120, the brightness of the illumination light L1 emitted from the light source unit 110, and the on / off of the color LED chip 117. be. By touching the position corresponding to the fourth sensor 135 on the sensor cover 106, the light amount (emission intensity) of the white LED element 125 on the face LED substrate 120 changes stepwise. If the white LED chip 115 and the light bulb color LED chip 116 are turned on when the white LED element 125 is turned on, the power consumption increases and the USB power supply capacity (4.5 W) may be exceeded. In the present embodiment, when the white LED element 125 is turned on, the light amount (emission intensity) of the white LED chip 115 and the light bulb color LED chip 116 is controlled to be reduced (the drive current is reduced).
Further, in the present embodiment, the color LED chip 117 can be turned on / off by continuously touching (that is, pressing and holding) the position corresponding to the fourth sensor 135 on the sensor cover 106 for a predetermined time. It is configured as follows.

The LED drivers 136 and 137 are electronic circuits that supply current to the white LED chip 115 and the light bulb color LED chip 116, respectively, and a predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 according to the control of the MPU 131. ..

The USB connector 139 is a connector connected to the USB cable C, and power is supplied to the MPU board 130, the light source unit 110, and the face LED board 120 by connecting the USB port of the computer and the USB connector 139.

FIG. 7 is a flowchart of the white LED lighting process executed by the MPU 131 when a finger is held over the position corresponding to the first sensor 132 on the sensor cover 106. FIG. 8 is a flowchart of the brightness adjustment process (first mode) executed by the MPU 131 when the position corresponding to the second sensor 133 on the sensor cover 106 is touched. Further, FIG. 9 is a flowchart of the whiteness adjustment process (second mode) executed by the MPU 131 when the position corresponding to the third sensor 134 on the sensor cover 106 is touched. Further, FIGS. 10 to 13 show the face LED / color LED lighting process (third mode, fourth mode) executed by the MPU 131 when the position corresponding to the fourth sensor 135 on the sensor cover 106 is touched. It is a flowchart of. In the white LED lighting process, brightness adjustment process, whiteness adjustment process, and face LED / color LED lighting process, the USB cable C is connected to the USB connector 139, and power is supplied to the MPU board 130, the light source unit 110, and the face LED board 120. Performed by being supplied.

As shown in FIG. 7, when the white LED lighting process is executed, the MPU 131 monitors the signal of the first sensor 132 and determines whether or not the first sensor 132 is on (step S101). Then, when the first sensor 132 is not turned on, it waits until the first sensor 132 is turned on (step S101: NO), and when the first sensor 132 is turned on (step S101: YES), the process is step S102. Proceed to.
In step S102, the MPU 131 controls the LED driver 136 so that the white LED chip 115 has a preset maximum light amount (100%) and the bulb-colored LED chip 116 has a minimum light amount of 0%. A predetermined current is supplied to the 115 and the bulb color LED chip 116. When step S102 is completed, the process proceeds to step S103.
In step S103, the MPU 131 monitors the signal of the first sensor 132 and determines whether or not the first sensor 132 is on (step S103). Then, when the first sensor 132 is not turned on, it waits until the first sensor 132 is turned on (step S103: NO), and when the first sensor 132 is turned on (step S103: YES), the process is step S104. Proceed to.
In step S104, the MPU 131 controls the LED driver 136, sets the amount of electricity supplied to the white LED chip 115 and the light bulb color LED chip 116 to zero, and turns off the white LED chip 115 and the light bulb color LED chip 116. When the step S104 is completed, the process returns to the step S101.
As described above, when the white LED lighting process of the present embodiment is executed, the user U holds his / her finger on the sensor cover 106 at the position corresponding to the first sensor 132, whereby the white LED chip 115 and the light bulb color are used. The LED chip 116 turns on / off.

As shown in FIG. 8, when the brightness adjustment process is executed, the MPU 131 monitors the signal of the second sensor 133 and determines whether or not the second sensor 133 is on (step S201). Then, when the second sensor 133 is not turned on, it waits until the second sensor 133 is turned on (step S201: NO), and when the second sensor 133 is turned on (step S201: YES), the process is step S202. Proceed to.
In step S202, the MPU 131 controls the LED driver 136, and is white while maintaining the balance between the light amount of the white LED chip 115 and the light amount of the light bulb color LED chip 116 set in steps S301 to S316 of FIG. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the total light amount of the LED chip 115 and the light bulb color LED chip 116 is 60% of the preset maximum light amount. When step S202 is completed, the process proceeds to step S203.
In step S203, the MPU 131 monitors the signal of the second sensor 133 and determines whether or not the second sensor 133 is on (step S203). Then, when the second sensor 133 is not turned on, it waits until the second sensor 133 is turned on (step S203: NO), and when the second sensor 133 is turned on (step S203: YES), the process is step S204. Proceed to.
In step S204, the MPU 131 controls the LED driver 136, and is white while maintaining the balance between the light amount of the white LED chip 115 and the light amount of the light bulb color LED chip 116 set in steps S301 to S316 of FIG. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the total light amount of the LED chip 115 and the light bulb color LED chip 116 is 30% of the preset maximum light amount. When step S204 is completed, the process proceeds to step S205.
In step S205, the MPU 131 monitors the signal of the second sensor 133 and determines whether or not the second sensor 133 is on (step S205). Then, when the second sensor 133 is not turned on, it waits until the second sensor 133 is turned on (step S205: NO), and when the second sensor 133 is turned on (step S205: YES), the process is step S206. Proceed to.
In step S206, the MPU 131 controls the LED driver 136 and is white while maintaining the balance between the light amount of the white LED chip 115 and the light amount of the light bulb color LED chip 116 set in steps S301 to S316 of FIG. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the total light amount of the LED chip 115 and the light bulb color LED chip 116 is 60% of the preset maximum light amount. When step S206 is completed, the process proceeds to step S207.
In step S207, the MPU 131 monitors the signal of the second sensor 133 and determines whether or not the second sensor 133 is on (step S207). Then, when the second sensor 133 is not turned on, it waits until the second sensor 133 is turned on (step S207: NO), and when the second sensor 133 is turned on (step S207: YES), the process is step S208. Proceed to.
In step S208, the MPU 131 controls the LED driver 136, and is white while maintaining the balance between the light amount of the white LED chip 115 and the light amount of the light bulb color LED chip 116 set in steps S301 to S316 of FIG. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the total light amount of the LED chip 115 and the light bulb color LED chip 116 becomes a preset maximum light amount (100%). When step S208 ends, the process returns to step S201.
As described above, when the brightness adjustment process of the present embodiment is executed, the user U touches the position corresponding to the second sensor 133 on the sensor cover 106 to obtain the white LED chip 115 and the light bulb color LED chip. The total amount of light of 116 changes stepwise.

As shown in FIG. 9, when the whiteness adjustment process is executed, the MPU 131 monitors the signal of the third sensor 134 and determines whether or not the third sensor 134 is on (step S301). Then, when the third sensor 134 is not turned on, it waits until the third sensor 134 is turned on (step S301: NO), and when the third sensor 134 is turned on (step S301: YES), the process is step S302. Proceed to.
In step S302, the MPU 131 controls the LED drivers 136 and 137, the white LED chip 115 has a light amount of 75% of the preset light amount (set in steps S201 to S208), and the light bulb color LED chip 116 has a light bulb color LED chip 116. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the light amount is 25% of the light amount set in advance (set in steps S201 to S208). When step S302 is completed, the process proceeds to step S303.
In step S303, the MPU 131 monitors the signal of the third sensor 134 and determines whether or not the third sensor 134 is on (step S303). Then, when the third sensor 134 is not turned on, it waits until the third sensor 134 is turned on (step S303: NO), and when the third sensor 134 is turned on (step S303: YES), the process is step S304. Proceed to.
In step S304, the MPU 131 controls the LED drivers 136 and 137, the white LED chip 115 has a light amount of 50% of the preset light amount (set in steps S201 to S208), and the light bulb color LED chip 116 has a light bulb color LED chip 116. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the light amount is 50% of the light amount set in advance (set in steps S201 to S208). When step S304 is completed, the process proceeds to step S305.
In step S305, the MPU 131 monitors the signal of the third sensor 134 and determines whether or not the third sensor 134 is on (step S305). Then, when the third sensor 134 is not turned on, it waits until the third sensor 134 is turned on (step S305: NO), and when the third sensor 134 is turned on (step S305: YES), the process is step S306. Proceed to.
In step S306, the MPU 131 controls the LED drivers 136 and 137, the white LED chip 115 has a light amount of 25% of the preset light amount (set in steps S201 to S208), and the light bulb color LED chip 116 has a light bulb color LED chip 116. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the light amount is 75% of the light amount set in advance (set in steps S201 to S208). When step S306 is completed, the process proceeds to step S307.
In step S307, the MPU 131 monitors the signal of the third sensor 134 and determines whether or not the third sensor 134 is on (step S307). Then, when the third sensor 134 is not turned on, it waits until the third sensor 134 is turned on (step S307: NO), and when the third sensor 134 is turned on (step S307: YES), the process is step S308. Proceed to.
In step S308, the MPU 131 controls the LED drivers 136 and 137, the white LED chip 115 becomes 0% of the preset light amount (set in steps S201 to S208), and the light bulb color LED chip 116 becomes. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the light amount is 100% of the light amount set in advance (set in steps S201 to S208). When step S308 is completed, the process proceeds to step S309.
In step S309, the MPU 131 monitors the signal of the third sensor 134 and determines whether or not the third sensor 134 is on (step S309). Then, when the third sensor 134 is not turned on, it waits until the third sensor 134 is turned on (step S309: NO), and when the third sensor 134 is turned on (step S309: YES), the process is step S310. Proceed to.
In step S310, the MPU 131 controls the LED drivers 136 and 137, the white LED chip 115 has a light amount of 25% of the preset light amount (set in steps S201 to S208), and the light bulb color LED chip 116 has a light bulb color LED chip 116. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the light amount is 75% of the light amount set in advance (set in steps S201 to S208). When step S310 is completed, the process proceeds to step S311.
In step S311 the MPU 131 monitors the signal of the third sensor 134 and determines whether or not the third sensor 134 is on (step 311). Then, when the third sensor 134 is not turned on, it waits until the third sensor 134 is turned on (step 311: NO), and when the third sensor 134 is turned on (step S311: YES), the process is step S312. Proceed to.
In step S312, the MPU 131 controls the LED drivers 136 and 137, the white LED chip 115 has a light amount of 50% of the preset light amount (set in steps S201 to S208), and the light bulb color LED chip 116 has a light bulb color LED chip 116. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the light amount is 50% of the light amount set in advance (set in steps S201 to S208). When step S312 is completed, the process proceeds to step S313.
In step S313, the MPU 131 monitors the signal of the third sensor 134 and determines whether or not the third sensor 134 is on (step 313). Then, when the third sensor 134 is not turned on, it waits until the third sensor 134 is turned on (step 313: NO), and when the third sensor 134 is turned on (step S313: YES), the process is step S314. Proceed to.
In step S314, the MPU 131 controls the LED drivers 136 and 137, the white LED chip 115 has a light amount of 75% of the preset light amount (set in steps S201 to S208), and the light bulb color LED chip 116 has a light bulb color LED chip 116. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the light amount is 25% of the light amount set in advance (set in steps S201 to S208). When step S314 is completed, the process proceeds to step S315.
In step S315, the MPU 131 monitors the signal of the third sensor 134 and determines whether or not the third sensor 134 is on (step 315). Then, when the third sensor 134 is not turned on, it waits until the third sensor 134 is turned on (step 315: NO), and when the third sensor 134 is turned on (step S315: YES), the process is step S316. Proceed to.
In step S316, the MPU 131 controls the LED drivers 136 and 137, the white LED chip 115 becomes the preset light amount (100%) (set in steps S201 to S208), and the light bulb color LED chip 116 is preset. A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so that the light amount is 0% of the set light amount (set in steps S201 to S208). When step S316 is completed, the process returns to step S301.
As described above, when the whiteness adjustment process of the present embodiment is executed, the user U touches the position corresponding to the third sensor 134 on the sensor cover 106 to obtain the light amount of the white LED chip 115 and the light bulb. The amount of light of the color LED chip 116 changes stepwise, thereby changing the color (whiteness) of the illumination light. In this embodiment, the total of the light amount of the white LED chip 115 and the light amount of the light bulb color LED chip 116 is balanced so as to be 100% of the preset light amount (set in steps S201 to S208). Therefore, even if the amount of light of the white LED chip 115 and the amount of light of the light bulb color LED chip 116 change stepwise, the change in power consumption is small and does not exceed the power supply capacity (4.5 W) of USB.

As shown in FIG. 10, when the face LED / color LED lighting process is executed, the MPU 131 monitors the signal of the fourth sensor 135 and determines whether or not the fourth sensor 135 is on (step S401). ). Then, when the fourth sensor 135 is not turned on, it waits until the fourth sensor 135 is turned on (step S401: NO), and when the fourth sensor 135 is turned on (step S401: YES), the process is step S402. Proceed to.
In step S402, the MPU 131 measures the time during which the fourth sensor 135 is on, and determines whether or not the fourth sensor 135 is on for a longer time than a predetermined time (that is, whether the fourth sensor 135 is held down) (that is, whether the fourth sensor 135 is held down). Step S402). Then, if it is determined that the fourth sensor 135 is long-pressed, the process proceeds to step S404, and if it is determined that the fourth sensor 135 is not long-pressed, the process proceeds to step S403.
In step S403, the MPU 131 controls the PWM signal supplied to the white LED element 125, and adjusts the duty ratio of the PWM signal so that the white LED element 125 has a preset maximum light amount (100%). When step S403 is completed, the process proceeds to step S407.
In step S404, the MPU 131 determines whether or not the color LED chip 117 is already lit (step S404). Then, when it is determined that the color LED chip 117 is already lit, the color LED chip 117 is turned off (step S405), and when it is determined that the color LED chip 117 is not lit, the color LED chip 117 is turned on. (Step S406). When steps S405 and S406 are completed, the process returns to step S401.
In step S407, the MPU 131 confirms the current light amount setting value of the white LED chip 115 and the current light amount setting value of the light bulb color LED chip 116 set in steps S201 to S208 and steps S301 to S316. , It is determined whether or not the sum of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is larger than 70% of the maximum light amount (step S407). When the sum of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is larger than 70% of the maximum light amount (step S407: YES), the process proceeds to step S408, and when it is small. (Step S407: NO), the process proceeds to step S411.
In step S408, the MPU 131 controls the LED drivers 136 and 137 so that the sum of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is 70% of the maximum light amount (for example). , The light amount of the white LED chip 115: 52.5%, the light amount of the light bulb color LED chip 116: 17.5%), and apply a predetermined current to the white LED chip 115 and the light bulb color LED chip 116. Supply. When step S408 is completed, the process proceeds to step S411.
In step S411 (FIG. 11), the MPU 131 monitors the signal of the fourth sensor 135 and determines whether or not the fourth sensor 135 is on (step S411). Then, when the fourth sensor 135 is not turned on, it waits until the fourth sensor 135 is turned on (step S411: NO), and when the fourth sensor 135 is turned on (step S411: YES), the process is step S412. Proceed to.
In step S412, the MPU 131 measures the time during which the fourth sensor 135 is on, and determines whether or not the fourth sensor 135 is on for a longer time than a predetermined time (that is, whether the fourth sensor 135 is held down) (that is, whether the fourth sensor 135 is held down). Step S412). Then, if it is determined that the fourth sensor 135 is long-pressed, the process proceeds to step S414, and if it is determined that the fourth sensor 135 is not long-pressed, the process proceeds to step S413.
In step S413, the MPU 131 controls the PWM signal supplied to the white LED element 125, and adjusts the duty ratio of the PWM signal so that the white LED element 125 has a light amount of 50% of the preset maximum light amount. When step S413 is completed, the process proceeds to step S417.
In step S414, the MPU 131 determines whether or not the color LED chip 117 is already lit (step S414). Then, when it is determined that the color LED chip 117 is already lit, the color LED chip 117 is turned off (step S415), and when it is determined that the color LED chip 117 is not lit, the color LED chip 117 is turned on. (Step S416). When steps S415 and S416 are completed, the process returns to step S411.
In step S417, the MPU 131 confirms the current light amount setting value of the white LED chip 115 and the current light amount setting value of the light bulb color LED chip 116 set in steps S201 to S208 and steps S301 to S316. , It is determined whether or not the sum of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is larger than 70% (step S417). When the total of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is larger than 70% of the maximum light amount (step S417: YES), the process proceeds to step S418, and when it is smaller. (Step S417: NO), the process proceeds to step S421.
In step S418, the MPU 131 controls the LED drivers 136 and 137 so that the sum of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is 70% of the maximum light amount (for example). , The light amount of the white LED chip 115: 52.5%, the light amount of the light bulb color LED chip 116: 17.5%), and apply a predetermined current to the white LED chip 115 and the light bulb color LED chip 116. Supply. When step S418 is completed, the process proceeds to step S421.
In step S421 (FIG. 12), the MPU 131 monitors the signal of the fourth sensor 135 and determines whether or not the fourth sensor 135 is on (step S421). Then, when the fourth sensor 135 is not turned on, it waits until the fourth sensor 135 is turned on (step S421: NO), and when the fourth sensor 135 is turned on (step S421: YES), the process is step S422. Proceed to.
In step S422, the MPU 131 measures the time during which the fourth sensor 135 is on, and determines whether or not the fourth sensor 135 is on for a longer time than a predetermined time (that is, whether the fourth sensor 135 is held down) (that is, whether the fourth sensor 135 is held down). Step S422). Then, if it is determined that the fourth sensor 135 is long-pressed, the process proceeds to step S424, and if it is determined that the fourth sensor 135 is not long-pressed, the process proceeds to step S423.
In step S423, the MPU 131 controls the PWM signal supplied to the white LED element 125, and adjusts the duty ratio of the PWM signal so that the white LED element 125 has a light amount of 30% of the preset maximum light amount. When step S423 is completed, the process proceeds to step S427.
In step S424, the MPU 131 determines whether or not the color LED chip 117 is already lit (step S424). Then, when it is determined that the color LED chip 117 is already lit, the color LED chip 117 is turned off (step S425), and when it is determined that the color LED chip 117 is not lit, the color LED chip 117 is turned on. (Step S426). When steps S425 and S426 are completed, the process returns to step S421.
In step S427, the MPU 131 confirms the current light amount setting value of the white LED chip 115 and the current light amount setting value of the light bulb color LED chip 116 set in steps S201 to S208 and steps S301 to S316. , It is determined whether or not the sum of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is larger than 70% (step S427). When the sum of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is larger than 70% of the maximum light amount (step S427: YES), the process proceeds to step S428, and when it is smaller. (Step S427: NO), the process proceeds to step S431.
In step S428, the MPU 131 controls the LED drivers 136 and 137 so that the sum of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is 70% of the maximum light amount (for example). , The light amount of the white LED chip 115: 52.5%, the light amount of the light bulb color LED chip 116: 17.5%), and apply a predetermined current to the white LED chip 115 and the light bulb color LED chip 116. Supply. When step S428 is completed, the process proceeds to step S431.
In step S431 (FIG. 13), the MPU 131 monitors the signal of the fourth sensor 135 and determines whether or not the fourth sensor 135 is on (step S431). Then, when the fourth sensor 135 is not turned on, it waits until the fourth sensor 135 is turned on (step S431: NO), and when the fourth sensor 135 is turned on (step S431: YES), the process is step S432. Proceed to.
In step S432, the MPU 131 measures the time during which the fourth sensor 135 is on, and determines whether or not the fourth sensor 135 is on for a longer time than a predetermined time (that is, whether the fourth sensor 135 is held down) (that is, whether the fourth sensor 135 is held down). Step S432). Then, if it is determined that the fourth sensor 135 is long-pressed, the process proceeds to step S434, and if it is determined that the fourth sensor 135 is not long-pressed, the process proceeds to step S433.
In step S433, the MPU 131 controls the PWM signal supplied to the white LED element 125, and adjusts the duty ratio of the PWM signal so that the white LED element 125 has a light amount of 0% of the preset maximum light amount. When step S433 is completed, the process proceeds to step S438.
In step S434, the MPU 131 determines whether or not the color LED chip 117 is already lit (step S434). Then, when it is determined that the color LED chip 117 is already lit, the color LED chip 117 is turned off (step S435), and when it is determined that the color LED chip 117 is not lit, the color LED chip 117 is turned on. (Step S436). When steps S435 and S436 are completed, the process returns to step S431.
In step S438, the MPU 131 controls the LED drivers 136 and 137, and the white LED chip 115 and the bulb color LED chip 116 are preset (that is, set in steps S201 to S208 and steps S301 to S316). A predetermined current is supplied to the white LED chip 115 and the light bulb color LED chip 116 so as to light up with the amount of light. When step S438 is completed, the process returns to step S401 (FIG. 10).
As described above, when the face LED / color LED lighting process of the present embodiment is executed, the user U touches the position corresponding to the fourth sensor 135 on the sensor cover 106, thereby on the face LED substrate 120. The amount of light of the white LED element 125 of the above changes stepwise, whereby the amount of light of the illumination light L2 toward the face of the user U changes. Further, when the white LED element 125 is turned on, if the total of the set value of the light amount of the white LED chip 115 and the set value of the light amount of the light bulb color LED chip 116 is larger than 70% of the maximum light amount, the white LED chip 115 Since the sum of the set value of the light amount and the set value of the light amount of the light bulb color LED chip 116 is adjusted to be 70% of the maximum light amount, the power supply capacity of the USB even if the white LED element 125 is turned on (4. It does not exceed 5W).
Further, the color LED chip 117 can be turned on / off by continuously touching (that is, pressing and holding) the position corresponding to the fourth sensor 135 on the sensor cover 106 for a predetermined time.

Next, returning to FIGS. 1, 2 and 4, the configuration of the hooking portion 200 of the lighting device 1 of the present embodiment will be described.
As shown in FIGS. 1, 2 and 4, the hooking portion 200 is a member that supports the main body portion 100 and hooks on the upper end portion of the display D when the lighting device 1 is attached to the display D. It has a weight portion 210 having a weight for balance inside, and an arm portion 230 connecting between the weight portion 210 and the main body portion 100.

The weight portion 210 is a member arranged so as to come into contact with the back surface of the display D when the lighting device 1 is hooked on the upper end portion of the display D.
The arm portion 230 is a plate-shaped member that engages with the upper end portion of the display D when the lighting device 1 is hooked on the upper end portion of the display D. A tongue portion 232 that projects downward so as to come into contact with the surface of the display D is formed.
Further, the weight portion 210 and the arm portion 230 are rotatably connected via a rotation shaft 215 (first rotation shaft) extending in the X-axis direction, and the weight portion 210 is armed around the rotation shaft 215. A torsion spring (not shown) that rotates (urges) the portion 230 is provided. Therefore, when the lighting device 1 is hooked on the upper end portion of the display D, the lower end portion of the weight portion 210 presses the back surface of the display D, and the display D is narrowed by the weight portion 210 and the tongue portion 232.
FIG. 14 is a diagram showing a state (posture) when the lighting device 1 is hooked on the upper end portion of the display D, and FIG. 14 (a) shows a state where the lighting device 1 is hooked on the thick display D1. 14 (b) shows how the display D2 is hooked to a general thickness, and FIG. 14 (c) shows how the display D3 is hooked to the thin display D3.
As described above, the tongue portion 232 of the arm portion 230 engages with the upper end portion of the display D, and the weight portion 210 rotates with respect to the arm portion 230. Although it differs depending on the situation, since the display D is narrowed by the weight portion 210 and the tongue portion 232, both are stopped in a stable posture.

Further, in the present embodiment, the arm portion 230 and the main body portion 100 are rotatably connected via a rotation shaft 235 (second rotation shaft) extending in the X-axis direction.
Therefore, after the illuminating device 1 is attached to the display D, the main body 100 is rotated around the rotation shaft 235, so that the direction of the illuminating light L1 from the illuminating device 1 toward the user U's hand and the illuminating device 1 The direction of the illumination light L2 toward the face of the user U can be adjusted.

As described above, the lighting device 1 of the present embodiment is configured to be stably hooked to the upper end portion of the display D.
Further, as described above, the lighting device 1 of the present embodiment is configured to not only illuminate the hand of the user U but also illuminate the face of the user U.
Therefore, even in an online conference in a dark environment, the conference materials and keyboard at hand can be easily seen, and the image quality in the online conference is also good.

Although the above is the description of the present embodiment, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the technical idea of the present invention.

For example, in the lighting device 1 of the present embodiment, the color LED chip 117 is turned on by continuously touching (that is, pressing and holding) the position corresponding to the fourth sensor 135 on the sensor cover 106 for a predetermined time. The configuration is set to turn off / off, but the configuration is not necessarily limited to such a configuration. For example, a configuration in which the color LED chip 117 is turned on when the USB cable C is connected to the USB connector 139 and power is supplied. You can also do it.

It should be noted that the embodiments disclosed this time are examples in all respects and should be considered not to be restrictive. The scope of the present invention is shown by the scope of claims, not the above description, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

1: Lighting device 100: Main body 101: Case 102: Window 103: Diffusing plate 104: Side cover 105: Light guide plate 106: Sensor cover 110: Light source unit 112: Board 115: White LED chip 116: Light bulb color LED chip 117 : Color LED chip 118: MPU
120: Face LED board 122: Board 125: White LED element 130: MPU board 131: MPU
132: 1st sensor 133: 2nd sensor 134: 3rd sensor 135: 4th sensor 136: LED driver 137: LED driver 139: USB connector 200: Hooking part 210: Weight part 215: Rotating shaft 230: Arm part 232 : Tongue 235: Rotating axis C: USB cable D: Display D1: Display D2: Display D3: Display L1: Illumination light L2: Illumination light L3: Illumination light U: User

Claims (12)

A lighting device that is attached to a computer display and illuminates the user's hands.
A first light source that emits the first illumination light toward the user's hand,
A second light source that emits white second illumination light toward the user's face,
A control unit that controls the first light source and the second light source,
An operation unit that receives input from the user and outputs a control signal to the control unit,
A main body portion that houses the first light source, the second light source, the control unit, and the operation unit and extends substantially horizontally along the upper end portion of the display.
A hooking portion that supports the main body portion and hooks onto the upper end portion of the display,
A lighting device characterized by being provided with. The first aspect of claim 1, wherein the first light source includes a first substrate extending substantially horizontally along the upper end portion of the display, and a plurality of first LED elements arranged on the surface of the substrate. Lighting device. The second aspect of claim 2, wherein the plurality of first LED elements are composed of a plurality of white LED chips that emit white light and a plurality of light bulb-colored LED chips that emit light bulb-colored light. Lighting equipment. The first mode in which the control unit controls the emission intensity of at least one of the white LED chip and the light bulb color LED chip according to the control signal to change the illuminance of the first illumination light, and the white LED. The lighting device according to claim 3, wherein the first light source is controlled by a second mode in which the emission intensity of the chip and the light bulb color LED chip is controlled to change the illumination color of the first illumination light. The second light source has a plurality of second LED elements that emit white light.
Claims 1 to 4 in which the control unit controls the second light source by a third mode in which the emission intensity of the second LED element is controlled according to the control signal and the illuminance of the second illumination light is changed. The lighting device according to any one of the above. 3 . The lighting device according to claim 5, wherein 4 is cited . The lighting device according to any one of claims 1 to 6, wherein the main body portion has a light guide plate that guides the second illumination light to the outside of the main body portion. The lighting device according to any one of claims 1 to 7, further comprising a third light source that emits a third illumination light from the main body. The third light source has at least one third LED element that emits at least red, green, and blue light.
The lighting device according to claim 8, wherein the control unit controls the third light source by a fourth mode in which the emission color of the third LED element is changed at a predetermined cycle in response to the control signal. The hooking portion is
A weight portion arranged so as to be in contact with the back surface of the display,
An arm portion connecting between the weight portion and the main body portion,
A tongue portion protruding from the arm portion so as to be in contact with the surface of the display, and a tongue portion.
Equipped with
The lighting device according to any one of claims 1 to 9, wherein the display is narrowed by the weight portion and the tongue portion. The weight portion and the arm portion are rotatable relative to a first rotation axis extending substantially horizontally along the upper end portion of the display.
The lighting device according to claim 10, wherein the arm portion and the main body portion are rotatable relative to a second rotation axis extending substantially horizontally along the upper end portion of the display. The lighting device according to any one of claims 1 to 11, wherein the lighting device is driven by electric power supplied from a USB port of the computer.

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