KR102087934B1 - Lamp unit and vehicle lamp apparatus for using the same - Google Patents

Abstract

A lamp unit for emitting light according to the rotational speed of the rotating body and a vehicle lamp device using the same, comprising: a power supply unit for supplying power corresponding to the rotating speed of the rotating body, a light source module including a plurality of light sources; According to a power corresponding to the rotational speed of the rotating body, including a driving unit for driving any one of the plurality of light sources, the light source module includes a first light source and a second light source adjacent to each other, the first The light source may have a first forward voltage Vf value, the second light source may have a second forward voltage value, and the first forward voltage value of the first light source may be greater than the second forward voltage value of the second light source.

Description

Lamp unit and vehicle lamp device using same {LAMP UNIT AND VEHICLE LAMP APPARATUS FOR USING THE SAME}

The embodiment relates to a lamp unit that emits light according to the rotational speed of the rotating body and a vehicle lamp device using the same.

Generally a lamp is a device that supplies or regulates light for a specific purpose.

As a light source of a lamp, an incandescent bulb, a fluorescent lamp, a neon lamp, or the like may be used, and recently, a light emitting diode (LED) is used.

LED is a device that changes the electrical signal to infrared or light by using the compound semiconductor characteristics, unlike fluorescent lamps do not use harmful substances such as mercury, so there is little cause of environmental pollution.

In addition, the life of the LED is longer than that of incandescent bulbs, fluorescent lights, neon lights. In addition, compared to incandescent bulbs, fluorescent lamps, neon lights, LEDs have the advantage of low power consumption, high visibility due to high color temperature and less glare.

1 is a view showing a general lamp unit.

As shown in FIG. 1, the lamp unit includes a light source module 1 and a reflector 2 for setting an emission directing angle of light emitted from the light source module 1.

Here, the light source module 1 may include at least one LED light source 1a provided on a printed circuit board (PCB) 1b.

The reflector 2 focuses the light emitted from the LED light source 1a so that the reflector 2 can be emitted through the opening with a predetermined directivity angle and have a reflective surface on the inner surface.

As described above, the lamp unit is a lamp that focuses a plurality of LED light sources 1a to obtain light, and lamps in which the LEDs are used are backlights, display devices, lighting lamps, vehicle indicator lamps, Or a head lamp.

In particular, since the lamp unit used in the vehicle is very closely related to the safe driving of the vehicle, it is very important to be able to clearly identify the driving state of the driving vehicle from the outside.

Therefore, the lamp unit used in the vehicle should secure the amount of light suitable for the safe driving standard and at the same time ensure the aesthetic function of the exterior of the vehicle.

Embodiments provide a lamp unit capable of recognizing a current rotational speed of a rotating body using a plurality of light sources emitting light according to the rotating speed of the rotating body, and a vehicle lamp apparatus using the same.

In addition, the embodiment is to provide a lamp unit and a vehicle lamp device using the same by using a plurality of light sources having different forward voltage, to minimize the power consumption.

In addition, the embodiment is to provide a lamp unit and a vehicle lamp device using the same that can display the current speed of the vehicle to the outside by using a plurality of light sources attached to the wheel of the vehicle.

Lamp unit according to the embodiment, the power supply for supplying power corresponding to the rotational speed of the rotating body, a light source module including a plurality of light sources, and a plurality of light sources according to the power supplied by the power supply Among them, a driving unit for driving any one light source, the light source module includes a first light source and a second light source, the first light source has a first forward voltage (Vf) value, the second light source is a second Has a forward voltage value, the first forward voltage value of the first light source may be greater than the second forward voltage value of the second light source.

Here, the difference between the first forward voltage value of the first light source and the second forward voltage value of the second light source may be 0.1V to 2V.

The first light source may emit color light in the first wavelength band, the second light source may emit color light in the second wavelength band, and the first wavelength band may be smaller than the second wavelength band.

Subsequently, the light source module may be attached to the rotating body.

In addition, the light source module may include a substrate and a plurality of light sources arranged on the substrate, and the plurality of light sources may be disposed adjacent to each other, individually driven, and have different forward voltage values.

Here, the forward voltage value may become smaller or larger gradually from the first light source to the last light source.

The light source module also includes a substrate and a plurality of light sources arranged on the substrate, the plurality of light sources including at least one light source array in which a plurality of light sources are disposed adjacent to each other, The first light source array and the second light source array are individually driven, and the forward voltage value of the light source included in the first light source array and the forward voltage value of the light source included in the second light source array may be different from each other.

Here, the difference between the forward voltage value of the light source included in the first light source array and the forward voltage value of the light source included in the second light source array may be 0.1V to 2V.

The forward voltage value of the light source included in the first light source array gradually decreases from the first light source to the last light source among the first light source array, and the forward voltage value of the light source included in the second light source array is determined by the first value. In an array of two light sources, it may gradually increase from the first light source to the last light source.

Subsequently, the light sources included in the first light source array are individually driven and have different forward voltage values, and the light sources included in the second light source array are individually driven and may have different forward voltage values.

Alternatively, the light sources included in the first light source array may be individually driven and have different forward voltage values, and the light sources included in the second light source array may be simultaneously driven and have the same forward voltage values.

The light sources included in the first light source array may be driven simultaneously and have the same forward voltage value, and the light sources included in the second light source array may be simultaneously driven and have the same forward voltage value.

Next, the first light source array and the second light source array may be arranged in parallel with each other.

In some cases, the first light source array may be disposed in a first direction, and the second light source array may be disposed in a second direction perpendicular to the first direction.

Subsequently, the power supply unit includes a power generation unit that converts rotational force of the rotating body into electric energy, a charging unit that converts and charges electrical energy of the power generation unit into power, and a power corresponding to the rotational speed of the rotating body to the light source module. It may include a charging control unit for controlling the charging unit to supply.

Here, the power generation unit may include a magnetic body fixed to the rotating body and rotating in correspondence with the rotational speed of the rotating body, and a coil disposed on the central axis of rotation of the magnetic body to generate electricity according to the rotation of the magnetic body.

On the other hand, the lamp unit according to another embodiment, the sensor unit for sensing the rotational speed of the rotating body, a light source module attached to the rotating body, including a plurality of light sources, power corresponding to the rotational speed of the rotating body (power ) Is supplied to the light source module, the driving unit for driving any one of the plurality of light sources, and the rotational speed of the rotating body sensed from the sensor unit according to the power corresponding to the rotational speed of the rotating body. Correspondingly, a control unit for controlling the power supply unit and the driving unit, the light source module includes a first light source and a second light source adjacent to each other, the first light source has a first forward voltage (Vf) value, the second The light source has a second forward voltage value, and a difference between the first forward voltage value of the first light source and the second forward voltage value of the second light source may be 0.1V to 2V.

Here, the light source module includes a plurality of light sources having different forward voltage Vf values, and the light source having the minimum forward voltage value is driven when the speed of the rotating body is maximum, and the color light having the maximum wavelength band is generated. The light source having the maximum forward voltage value is driven when the speed of the rotating body is minimum and can generate color light having a minimum wavelength band.

The light source having the smallest forward voltage value may be disposed farthest from the central axis of the rotating body, and the light source having the largest forward voltage value may be disposed closest to the central axis of the rotating body.

The embodiment can recognize the current rotational speed of the rotating body by using a plurality of light sources emitting light according to the rotating speed of the rotating body, so that the speed of the rotating body can be properly controlled.

In addition, the embodiment may use a plurality of light sources having different forward voltages to minimize power consumption.

In addition, the embodiment can display the current speed of the vehicle to the outside by using a plurality of light sources attached to the wheel of the vehicle, it is easy to control the speeding vehicle, it can help the driver's safe driving.

1 is a view showing a typical lamp unit
2 is a cross-sectional view illustrating a lamp unit according to an embodiment.
3A and 3B are plan views illustrating the light source module of FIG. 2.
4A and 4B are sectional views showing the light source module according to the first embodiment.
5A and 5B are cross-sectional views illustrating a light source module according to a second embodiment.
6 is a sectional view showing a light source module according to a third embodiment
7 is a cross-sectional view showing a light source module according to a fourth embodiment.
8A to 8C are cross-sectional views illustrating a light source module to which a phosphor layer is applied.
9A and 9B illustrate an arrangement relationship between a rotating body and a light source module.
10A and 10B are cross-sectional views showing a substrate of a light source module.
11A and 11B are cross-sectional views showing the light source arrangement of the light source module.
12A to 12C are cross-sectional views illustrating a light source module having an uneven pattern.
13A and 13B are plan views illustrating electrical connections of the light source module according to the first embodiment.
14A and 14B are plan views illustrating electrical connections of the light source module according to the second embodiment.
15A and 15B are plan views illustrating electrical connections of the light source module according to the third embodiment.
16A and 16B are plan views illustrating electrical connections of the light source module according to the fourth embodiment.
17 is a plan view showing electrical connection of a light source module according to a fifth embodiment
18A and 18B are plan views illustrating a light source module including a plurality of light source arrays.
19 is a view showing a power supply of FIG.
20A and 20B are sectional views showing the power generation unit of FIG. 19.
21 is a diagram for explaining a lamp unit, according to another embodiment;
22A and 22B show a light source module mounted to a rotating body
23 is a view showing a distance between the central axis of the rotating body and the light source of the light source module
24 is a view showing a light source module mounted to the wheel of the vehicle

Hereinafter, exemplary embodiments will be described with reference to the accompanying drawings.

In the description of the embodiments, each layer, region, pattern or structure is formed “on” or “under” of a substrate, each layer (film), region, pad or pattern. In the case where it is described as, “on” and “under” include both “directly” or “indirectly” formed through another layer. In addition, the criteria for the top or bottom of each layer will be described with reference to the drawings.

In the drawings, the thickness or size of each layer is exaggerated, omitted, or schematically illustrated for convenience and clarity of description. In addition, the size of each component does not necessarily reflect the actual size.

2 is a view for explaining a lamp unit according to an embodiment.

As shown in FIG. 2, the lamp unit 10 according to the embodiment may include a light source module 100, a driver 200, and a power supply 300.

The light source module 100 may include a plurality of light sources 110 disposed on one substrate 120, and a plurality of sub light source modules disposed with one light source 110 disposed on one substrate 120. May be

In addition, the light source module 100 may include a first light source 102 and a second light source 104 adjacent to each other, the first light source 102 has a first forward voltage (Vf) value, the second The light source 104 may have a second forward voltage value.

In this case, the first forward voltage value of the first light source 102 may be greater than the second forward voltage value of the second light source 104.

Subsequently, a difference between the first forward voltage value of the first light source 102 and the second forward voltage value of the second light source 104 may be about 0.1V to 2V.

Here, the forward voltage value of the light source 110 means a voltage consumed by the light source 110 to perform the rated output.

For example, when the light source 110 is a light emitting diode, the light emitting diode may have inherent electrical characteristics such as a forward voltage according to its manufacturing process.

These electrical characteristics may affect optical characteristics such as brightness and color coordinate of the light emitting diode.

Therefore, if the light sources 110 of the light source module 100 have mutually different forward voltage values, the light sources 110 adjacent to each other may have different optical properties, and thus, may be different from each other. It can emit light with light of another wavelength band.

In addition, the light sources 110 of the light source module 100 may not only be disposed in consideration of the forward voltage of each light source 110, but also may be configured in consideration of the forward voltage of each light source 110. The power consumption can be minimized.

For example, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120, wherein the plurality of light sources 110 are arranged side by side, respectively, They are driven separately and can have different forward voltage values.

That is, as shown in FIG. 2, if the plurality of light sources 110 include the first, second, third, and fourth light sources 102, 104, 106, and 108, the forward voltage value of the first light source 102 may be It may be smaller than the forward voltage value of the second, third, fourth light source (104, 106, 108), the forward voltage value of the fourth light source 108 is the first, second, third light source (102, 104) , 106 may be greater than the forward voltage value.

Here, the forward voltage value of the first light source 102 may be about 0.1V to 2V smaller than the forward voltage values of the second, third, and fourth light sources 104, 106, and 108, and the fourth light source 108 The forward voltage value of may be about 0.1V to 2V greater than the forward voltage values of the first, second, and third light sources 102, 104, and 106.

The forward voltage value of the second light source 104 may be greater than the forward voltage value of the first light source 102, and may be smaller than the forward voltage values of the third and fourth light sources 106 and 108. The forward voltage value of the light source 106 may be larger than the forward voltage values of the first and second light sources 102 and 104 and smaller than the forward voltage value of the fourth light source 108.

Here, the forward voltage value of the second light source 104 is about 0.1V to 2V greater than the forward voltage value of the first light source 102, and is about 0.1 greater than the forward voltage values of the third and fourth light sources 106 and 108. V to 2V may be smaller, and the forward voltage value of the third light source 106 is about 0.1V to 2V greater than the forward voltage values of the first and second light sources 102 and 104, and It may be about 0.1V to 2V less than the forward voltage value.

In another embodiment, the forward voltage value of the first light source 102 may be greater than the forward voltage values of the second, third, and fourth light sources 104, 106, and 108, and the forward direction of the fourth light source 108 may be higher. The voltage value may be smaller than the forward voltage values of the first, second, and third light sources 102, 104, and 106.

Here, the forward voltage value of the first light source 102 may be about 0.1V to 2V greater than the forward voltage values of the second, third, and fourth light sources 104, 106, and 108, and the fourth light source 108 The forward voltage value of may be about 0.1V to 2V smaller than the forward voltage values of the first, second, and third light sources 102, 104, and 106.

The forward voltage value of the second light source 104 may be smaller than the forward voltage values of the first light source 102, and may be greater than the forward voltage values of the third and fourth light sources 106 and 108. The forward voltage value of the light source 106 may be smaller than the forward voltage values of the first and second light sources 102 and 104 and greater than the forward voltage value of the fourth light source 108.

Here, the forward voltage value of the second light source 104 is about 0.1V to 2V smaller than the forward voltage value of the first light source 102, and is about 0.1 smaller than the forward voltage values of the third and fourth light sources 106 and 108. V to 2V greater, the forward voltage value of the third light source 106 is about 0.1V to 2V smaller than the forward voltage values of the first and second light sources 102 and 104, and It can be about 0.1V to 2V greater than the forward voltage value.

As such, the forward voltage value of the light source 110 may gradually decrease or increase from the first light source 102 to the fourth light source 108.

As yet another embodiment, the light source module 100 includes a substrate 120 and a plurality of light sources 110 arranged on the substrate 120, wherein the plurality of light sources 110 are arranged in a row, with a plurality of light sources. At least one light source array may be disposed.

Here, among the light source arrays, the first light source array and the second light source array adjacent to each other are individually driven, and the forward voltage value of the light source 110 included in the first light source array and the light source included in the second light source array ( The forward voltage values of 110 may be different.

In this case, the difference between the forward voltage value of the light source 110 included in the first light source array and the forward voltage value of the light source 110 included in the second light source array may be about 0.1V to 2V.

Meanwhile, the light source 110 of the light source module 100 may be a top view type light emitting diode, and in some cases, the light source 110 may be a side view type light emitting diode.

The light source 110 may be a light emitting diode chip, and the light emitting diode chip may include a blue LED chip or an ultraviolet LED chip, or a red LED chip, a green LED chip, a blue LED chip, and yellow green. ) It may be configured in a package form combining at least one or more of LED chip, white LED chip.

In addition, the white LED may be implemented by combining yellow phosphor on the blue LED, or using red phosphor and green phosphor on the blue LED simultaneously, and yellow phosphor on the blue LED. Yellow phosphor, red phosphor, and green phosphor may be simultaneously used.

As an example, the light source 110 is a vertical light emitting chip, and includes a light emitting structure, a first electrode disposed on an upper portion of the light emitting structure, a second electrode disposed on a lower portion of the light emitting structure, and disposed between the light emitting structure and the second electrode. It may include a reflective layer.

In some cases, a phosphor layer (not shown) may be disposed on the light source 110, and the phosphor layer may include a transparent resin and a phosphor.

Here, the phosphor layer may have a content ratio of the transparent resin and the phosphor of about 1: 1 to 1: 3.

In addition, the phosphor layer may include any one or a plurality of phosphors having a wavelength in a range of about 550 to 700 nm.

In some cases, the phosphor layer may include a phosphor having a wavelength in a range of about 580 to 600 nm, for example, (Br, Sr, Ca) ₂ SiO ₄ : Eu and the like.

In addition, the phosphor layer may include a phosphor having a wavelength in the range of about 601 to 650 nm, for example, (Ca, Sr, Ba) ₂ Si ₅ N ₈ : Eu, (Mg, Ca, Sr) AlSiN ₃ : Eu , (Ca, Sr, Ba) Si ₇ N ₁₀ : Eu, (Ca, Sr, Ba) SiN ₂ : Eu, and the like.

As another case, the phosphor layer may include a first phosphor having a wavelength in the range of about 580-600 nm and a second phosphor having a wavelength in the range of about 601-650 nm.

The phosphor layer may include a single layer in which a first phosphor having a wavelength in a range of about 580 to 600 nm and a second phosphor having a wavelength in a range of about 601 to 650 nm are mixed.

In this case, the mixing ratio of the first phosphor having a wavelength in the range of about 580 to 600 nm and the second phosphor having a wavelength in the range of about 601 to 650 nm may be about 1: 1 to 99: 1.

The phosphor layer is a multi-layer in which a first layer including a first phosphor having a wavelength in a range of about 580 to 600 nm and a second layer including a second phosphor having a wavelength in a range of about 601 to 650 nm are stacked. -layer).

Here, the thickness ratio of the first layer including the first phosphor having a wavelength in the range of about 580 to 600 nm and the second layer including the second phosphor having a wavelength in the range of about 601 to 650 nm is about 1: 1 to 1. 3: 1 may be.

The content ratio of the first phosphor included in the first layer and the second phosphor included in the second layer may be about 1: 1 to 99: 1.

Next, the phosphor of the phosphor layer may have at least one of a polygon, a sphere, and a flake shape.

Here, the phosphor of the phosphor layer may have a spherical shape having an average particle diameter of about 100 nm to 50 μm.

The thickness of the phosphor layer may be thicker than that of the light source 110, but in some cases, the thickness of the phosphor layer may be thinner than the thickness of the light source 110.

In another case, the phosphor layer may include a central region and a peripheral region surrounding the central region, where the thickness of the central region may be thicker than the thickness of the peripheral region.

Next, the substrate 120 may be manufactured to have flexibility, but is not limited thereto.

Here, the substrate 120 is a printed circuit board (PCB) made of any material selected from polyethylene terephthalate (PET), glass, polycarbonate (PC), silicon (Si), polyimide, epoxy, etc. ) May be a substrate, or may be formed in a film form.

In addition, the substrate 120 may selectively use a single layer PCB, a multilayer PCB, a ceramic substrate, a metal core PCB, or the like.

In this case, the entire region of the substrate 120 may be made of the same material. In some cases, a part of the entire region of the substrate 120 may be formed of another material.

For example, the substrate 120 may be formed of the same material as the entire region. For example, the substrate 200 may include a base member and a circuit pattern disposed on at least one surface of the base member. The material may be a film having flexibility and insulation, such as polyimide or epoxy (eg FR-4).

In some cases, a part of the entire region of the substrate 120 may be formed of another material. For example, the region of the substrate 120 where the light source 110 is disposed is a conductor, and the substrate where the light source 110 is not disposed. Region 120 may be an insulator.

In addition, the region of the substrate 120 where the light source 110 is disposed may be formed of a hard material without bending to support the light source 110, and the substrate 120 where the light source 110 is not disposed. The region may be made of a flexible material that can be bent, so that the substrate 120 may be manufactured to be applied to a mounting object having curvature.

As described above, the substrate 120 may be bent by applying a soft material, but may be bent by structural deformation.

For example, a portion of the substrate 120 may have a first thickness, and another portion of the substrate 120 may have a second thickness. The first and second thicknesses may be different from each other, thereby making the substrate 120 different. You can also wheel.

In addition, any one of a reflective coating film and a reflective coating material layer may be formed on the substrate 120, and may reflect light emitted from the light source 110 in an upward direction.

The reflective coating film or the reflective coating material layer may include a metal or metal oxide having high reflectance such as aluminum (Al), silver (Ag), gold (Au), titanium dioxide (TiO ₂ ), or the like. .

In some cases, the substrate 120 may be arranged with a plurality of heat radiation fins (not shown) for dissipating heat generated from the light source 110.

For example, the plurality of heat dissipation fins may be disposed in the entire region of the substrate 120, but may be disposed only in the region of the substrate 120 where the light source 110 is disposed.

In addition, the substrate 120 may include conductive patterns for applying a current to drive the light source 110.

For example, the conductive patterns may be disposed in the entire region of the substrate 120, but may be disposed only in the region of the substrate 120 supporting the light source 110, and the region of the substrate 120 not supporting the light source 110. It may also be placed only.

In addition, the embodiment may be implemented as a surface light source.

Here, the surface light source refers to a light source having a light emitting portion that diffuses in a plane shape. In an embodiment, a lamp unit that implements the surface light source may be configured by additionally configuring a lens, an optical member, and the like. Can provide.

Although not shown, the light source 110 may include a lens (not shown), and the lens may include a groove disposed at a position corresponding to the center area of the light exit surface of the light source 110.

In addition, the lower surface of the lens corresponding to the light source 110 may include a groove.

Here, the groove may have a conical or trapezoidal shape with a wide top surface and a narrow bottom surface.

As such, the reason for forming the groove in the lens is to widen the directing angle of the light emitted from the light source 110, and the embodiment is not limited thereto, and various types of lenses may be used.

Further, the lens may be in contact with the phosphor layer, and in some cases, may be disposed away from the phosphor layer by a predetermined distance.

Although not shown, an optical member (not shown) may be disposed at a predetermined interval from the substrate 120 and the light source 110, and the optical member (not shown) may be disposed in a space between the substrate 120 and the optical member. A light mixing area can be formed.

In some cases, the optical member (not shown) may be in contact with the light source 110.

Subsequently, the optical member is formed of at least one sheet, and may optionally include a diffusion sheet, a prism sheet, a brightness enhancement sheet, and the like.

Here, the diffusion sheet diffuses the light emitted from the light source 110, the prism sheet guides the diffused light to the light emitting region, and the luminance diffusion sheet enhances the brightness.

For example, the diffusion sheet may be generally formed of an acrylic resin, but is not limited thereto. In addition, polystyrene (PS), polymethyl methacrylate (PMMA), cyclic olefin copoly (COC), polyethylene terephthalate (PET) It may be made of a material capable of performing a light diffusing function such as a highly transparent plastic such as resin.

In addition, the optical member may have an uneven pattern on the upper surface.

The optical member is for diffusing light emitted from the light source 110, and may have an uneven pattern on the upper surface to increase the diffusion effect.

That is, the optical member can be formed of several layers, and the uneven pattern can be on the top layer or the surface of any one layer.

In addition, the uneven pattern may have a stripe shape arranged in one direction.

In this case, the concave-convex pattern has protrusions on the surface of the optical member, and the protrusions are composed of first and second surfaces facing each other, and an angle between the first and second surfaces may be an obtuse angle or an acute angle.

In some cases, the optical member may include at least two inclined surfaces having at least one inflection point.

Also, the optical member may include a curved surface having one or more curvatures.

Here, the optical member may have a surface having at least one of a concave curved surface, a convex curved surface, and a flat plane, depending on the outer shape of the cover member or the mounting object.

Subsequently, although not shown, a heat dissipation member (not shown) may be disposed under the substrate 120.

Here, the heat dissipation member may serve to discharge heat generated from the light source 110 to the outside.

For example, the heat radiating member may be a material having high thermal conductivity, such as aluminum, an aluminum alloy, copper, or a copper alloy.

Alternatively, the substrate 120 may be a metal core printed circuit board (MCPCB) in which the heat dissipation member is integrated, and a separate heat dissipation member may be disposed on the bottom surface of the MCPCB.

When a separate heat dissipation member is attached to the lower surface of the MCPCB, it may be attached by an acrylic adhesive (not shown).

Next, although not shown, the cover member (not shown) may include a top cover and a side cover, wherein the top cover may be made of a light-transmitting material that can transmit light, and the side cover may be non-transmissive light. It may be made of a light transmitting material.

In some cases, both the top cover and the side cover may be made of a light transmitting material capable of transmitting light.

Here, the cover member protects the light source module including the substrate 120 and the light source 110 from external impact, and may be made of a material (eg, acrylic) through which light emitted from the light source module can be transmitted.

In addition, the cover member may include a curved portion in terms of design, and since the substrate 120 of the light source module has flexibility, it may be easily accommodated in the curved cover member.

Subsequently, a reflector may be disposed on the inner side surface of the side cover of the cover member.

Here, the reflector may be formed of any one of a reflective coating film and a reflective coating material layer, it may reflect the light emitted from the light source 110 in the direction of the optical member.

In this case, the reflector may include a metal or metal oxide having high reflectance such as chromium (Cr), aluminum (Al), silver (Ag), gold (Au), titanium dioxide (TiO ₂ ), or the like.

Next, the power supply unit 300 may supply power corresponding to the rotational speed of the rotor 20.

In addition, the driving unit 200 may drive any one of the plurality of light sources 110 according to a power corresponding to the rotational speed of the rotating body 20.

Here, the power supply unit 300 may be a type including a power generation unit capable of generating electricity by itself, or may be a type not including the power generation unit.

First, the power supply unit 300 including the power generation unit may include a power generation unit, a charging unit, and a charging control unit.

Here, the power generation unit (not shown) converts the rotational force of the rotating body 20 into electrical energy, and the charging unit (not shown) converts the electrical energy of the power generation unit into power and charges the charge control unit (not shown). The control unit may control the charging unit to supply power corresponding to the rotational speed of the rotating body 20 to the light source module 100.

At this time, the power generation unit (not shown) of the power supply unit 300, the magnetic body is fixed to the rotating body 20 and rotates in accordance with the rotational speed of the rotating body 20, the magnetic body is disposed on the rotation center axis of the magnetic body It may include a coil for generating electricity in accordance with the rotation.

In addition, the power supply unit 300, which does not include a power generation unit, may supply power corresponding to the rotational speed of the rotating body 20 to the light source module 100 according to an external control signal.

Here, the control unit for controlling the power supply unit 300 may control the power supply unit 300 and the driving unit 200 in accordance with the rotational speed of the rotating body 20 sensed from the sensor unit.

Therefore, the light sources 110 of the light source module 100 emit light corresponding to the rotation speed of the rotating body 20, so that the current rotating speed of the rotating body 20 can be easily recognized from the outside.

As such, the embodiment can recognize the current rotational speed of the rotating body by using a plurality of light sources that emit light according to the rotating speed of the rotating body, and thus can appropriately control the speed of the rotating body.

In addition, the embodiment may use a plurality of light sources having different forward voltages to minimize power consumption.

In addition, when the embodiment is applied to the wheel of the vehicle, by using a plurality of light sources attached to the wheel of the vehicle, it is possible to display the current speed of the vehicle to the outside, it is easy to control the speeding vehicle, help the driver's safe driving Can give

3A and 3B are plan views illustrating the light source module of FIG. 2.

As shown in FIGS. 3A and 3B, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

As shown in FIG. 3A, the first light source 102 has a first forward voltage Vf1 characteristic, the second light source 104 has a second forward voltage Vf2 characteristic, and the third light source 106 has a third characteristic. The fourth light source 108 may have a characteristic of the forward voltage Vf3, and the fourth light source 108 may have a characteristic of the fourth forward voltage Vf4.

Here, the first forward voltage value Vf1 may be smaller than the second, third, and fourth forward voltage values Vf2, Vf3, and Vf4, and the fourth forward voltage value Vf4 may be smaller than the first, second, and fourth forward voltage values Vf4. It may be larger than the third forward voltage values Vf1, Vf2, and Vf3.

Here, the first forward voltage value Vf1 may be about 0.1V to 2V smaller than the second, third, and fourth forward voltage values Vf2, Vf3, and Vf4, and the fourth forward voltage value Vf4 may be set to the first forward voltage value Vf4. The first, second, and third forward voltage values Vf1, Vf2, and Vf3 may be about 0.1V to 2V greater.

The second forward voltage value Vf2 may be greater than the first forward voltage value Vf1, smaller than the third and fourth forward voltage values Vf3 and Vf4, and the third forward voltage value Vf3. May be greater than the first and second forward voltage values Vf1 and Vf2 and smaller than the fourth forward voltage value Vf4.

Here, the second forward voltage value Vf2 may be about 0.1V to 2V greater than the first forward voltage value Vf1 and about 0.1V to 2V smaller than the third and fourth forward voltage values Vf3 and Vf4. The third forward voltage value Vf3 may be about 0.1V to 2V greater than the first and second forward voltage values Vf1 and Vf2, and about 0.1V to 2V smaller than the fourth forward voltage value Vf4. have.

In another embodiment, the first forward voltage value Vf1 may be greater than the second, third, and fourth forward voltage values Vf2, Vf3, and Vf4, and the fourth forward voltage value Vf4 may be greater than or equal to the first, second, and fourth forward voltage values Vf4. It may be smaller than the second and third forward voltage values Vf1, Vf2, and Vf3.

Here, the first forward voltage value Vf1 may be about 0.1V to 2V greater than the second, third, and fourth forward voltage values Vf2, Vf3, and Vf4, and the fourth forward voltage value Vf4 is set to the first forward voltage value Vf4. The first, second, and third forward voltage values Vf1, Vf2, and Vf3 may be about 0.1V to 2V smaller.

The second forward voltage value Vf2 may be smaller than the first forward voltage value Vf1, larger than the third and fourth forward voltage values Vf3 and Vf4, and the third forward voltage value Vf3. May be smaller than the first and second forward voltage values Vf1 and Vf2 and larger than the fourth forward voltage value Vf4.

Here, the second forward voltage value Vf2 may be about 0.1V to 2V smaller than the first forward voltage value Vf1 and about 0.1V to 2V greater than the third and fourth forward voltage values Vf3 and Vf4. The third forward voltage value Vf3 may be about 0.1V to 2V smaller than the first and second forward voltage values Vf1 and Vf2, and about 0.1V to 2V greater than the fourth forward voltage value Vf4. have.

As such, the forward voltage value of the light source 110 may gradually decrease or increase from the first light source 102 to the fourth light source 108.

In some cases, the forward voltage value of the light source 110 may have a maximum value or a minimum value of the second light source 104 or the third light source 106.

In addition, the light sources 110 adjacent to each other have different forward voltages, and the difference in forward voltages of the light sources 110 adjacent to each other may be about 0.1V to 2V.

As such, the reason why the light sources 110 having different forward voltages are disposed adjacent to each other is to externally identify light generated from the light sources 110 adjacent to each other.

That is, since the light source 110 may have different light characteristics such as luminance and color coordinates due to differences in electrical characteristics such as forward voltage, and the like, when the light sources 110 having different forward voltages are disposed adjacent to each other, the light sources 110 adjacent to each other are disposed. The brightness, color coordinate, color, etc. of light generated from the?

Therefore, the light source module including the light sources 110 can be applied to a device capable of measuring the rotational speed of the rotating body.

That is, the driving voltage corresponding to the forward voltage value of the light source 110 and the rotational speed of the rotating body corresponding to the driving voltage are preset, and the corresponding light source 110 is driven according to the rotational speed of the rotating body. If the driving voltage is applied, the rotational speed of the rotor can be easily recognized from the outside.

Also, as an example, the blue light emitting diode may have a forward voltage of about 2.7V to 3.3V, and the green light emitting diode may have a forward voltage of about 2.4V to 2.9V.

The yellow light emitting diode may have a forward voltage of about 1.9V to 2.4V, and the red light emitting diode may have a forward voltage of about 1.7V to 2.3V.

Thus, as shown in FIG. 3B, the first light source 102 may be a blue light emitting diode having a forward voltage of about 2.7V to 3.3V, and the second light source 103 may have a forward voltage of about 2.4V to 2.9V. It may be a green light emitting diode.

The third light source 106 may be a yellow light emitting diode having a forward voltage of about 1.9 V to 2.4 V, and the fourth light source 108 may be a red light emitting diode having a forward voltage of about 1.7 V to 2.3 V. have.

In some cases, the first light source 102 emits colored light in the first wavelength band, the second light source 104 emits colored light in the second wavelength band, and the third light source 106 is colored in the third wavelength band. The light may be emitted, and the fourth light source 108 may emit color light in the fourth wavelength band.

Here, the first wavelength band may be smaller than the second, third and fourth wavelength bands, and the fourth wavelength band may be larger than the first, second and third wavelength bands.

Here, the first wavelength band may be about 1 nm to 400 nm smaller than the second, third, and fourth wavelength bands, and the fourth wavelength band may be about 1 nm to 400 nm larger than the first, second, and third wavelength bands.

The second wavelength band may be larger than the first wavelength band, smaller than the third and fourth wavelength bands, and the third wavelength band may be larger than the first and second wavelength bands and smaller than the fourth wavelength band.

Here, the second wavelength band may be about 1 nm to 400 nm larger than the first wavelength band, about 1 nm to 400 nm smaller than the third and fourth wavelength bands, and the third wavelength band is about 1 nm to 400 nm larger than the first and second wavelength bands. It may be about 1 nm to 400 nm smaller than the fourth wavelength band.

In another embodiment, the first wavelength band may be larger than the second, third and fourth wavelength bands, and the fourth wavelength band may be smaller than the first, second and third wavelength bands.

Here, the first wavelength band may be about 1 nm to 400 nm larger than the second, third, and fourth wavelength bands, and the fourth wavelength band may be about 1 nm to 400 nm smaller than the first, second, and third wavelength bands.

The second wavelength band may be smaller than the first wavelength band, larger than the third and fourth wavelength bands, and the third wavelength band may be smaller than the first and second wavelength bands and larger than the fourth wavelength band.

The second wavelength band may be about 1 nm to 400 nm smaller than the first wavelength band, about 1 nm to 400 nm larger than the third and fourth wavelength bands, and the third wavelength band is about 1 nm to 400 nm smaller than the first and second wavelength bands. It may be about 1 nm to 400 nm larger than the fourth wavelength band.

As such, the light wavelength band of the light source 110 may be gradually smaller or larger toward the fourth light source 108 from the first light source 102.

In some cases, the light wavelength band of the light source 110 may have the maximum value or the minimum value of the second light source 104 or the third light source 106.

In addition, the light sources 110 adjacent to each other have different light wavelength bands, and the difference in the light wavelength bands of the light sources 110 adjacent to each other may be about 1 nm to 400 nm.

As such, the reason why the light sources 110 having different light wavelength bands are arranged adjacent to each other is to externally identify the color of light generated from the light sources 110 adjacent to each other.

4A and 4B are sectional views showing the light source module according to the first embodiment.

As shown in FIGS. 4A and 4B, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

In addition, the transparent resin 112 may be disposed on the light source 110, and the transparent resin 112 may be any one or a mixture of transparent epoxy resin and silicon.

Here, the transparent resin 112 may be disposed separately from each light source 110, as shown in Figure 4a.

For example, the transparent resins 112 are individually disposed on the first, second, third, and fourth light sources 102, 104, 106, and 108, and the transparent resins 112 adjacent to each other are spaced apart from each other. Can be placed apart.

In addition, the transparent resin 112 may protect the light source 110 and its electrical connection line and serve as a lens.

In addition, the transparent resin 112 may include a phosphor (not shown) to convert the wavelength of the light emitted from the light source 110.

Subsequently, the transparent resin 112 may be disposed to cover the entire light source 110 together, as shown in FIG. 4B.

For example, the transparent resin 112 is disposed to cover the entire first, second, third, and fourth light sources 102, 104, 106, and 108, and the transparent resins 112 adjacent to each other are not spaced apart from each other. Can be connected to each other.

Here, the transparent resin 112 may be disposed to cover the entire light source 110 together, thereby realizing a surface light source.

Here, the surface light source means a light source having a light emitting portion having a diffused shape in a plane shape. In an embodiment, the transparent light source 112 is used to implement a surface light source, thereby providing a light source 110. The color of the light resulting from the keys can be easily identified from the outside.

5A and 5B are cross-sectional views illustrating a light source module according to a second embodiment.

As shown in FIGS. 5A and 5B, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

In addition, the separating walls 113 may be disposed between the light sources 110 adjacent to each other, and the side surfaces of the separating walls 113 may be inclined at an angle from the surface of the substrate 120.

Subsequently, as illustrated in FIG. 5A, a reflective layer 114 may be disposed on the side surface of the inclined partition wall 113.

Here, the reflective layer 114 may include a metal or metal oxide having high reflectance such as aluminum (Al), silver (Ag), gold (Au), titanium dioxide (TiO ₂ ), or the like.

The reflective layer 114 reflects the light generated from the light source 110, thereby increasing the brightness of the light without light loss.

In addition, the transparent resin 112 may be disposed on the light source 110 between the separating walls 113, and the transparent resin 112 may be any one or a mixture of transparent epoxy resin and silicon.

In some cases, as shown in FIG. 5B, the reflective layer 114 of FIG. 5A may not be disposed on the side surface of the inclined partition wall 113.

Here, the dividing wall 113 may include a metal or a metal oxide having high reflectance such as aluminum (Al), silver (Ag), gold (Au), titanium dioxide (TiO ₂ ), or the like.

The separation wall 113 reflects the light generated from the light source 110, thereby increasing the brightness of the light without light loss.

In addition, the transparent resin 112 may be disposed on the light source 110 between the separating walls 113, and the transparent resin 112 may be any one or a mixture of transparent epoxy resin and silicon.

As such, by disposing the separating walls 113 between the light sources 110 adjacent to each other, the luminance of the light may be increased by reducing the loss of the light generated from the light sources 110.

6 is a cross-sectional view illustrating a light source module according to a third embodiment.

As shown in FIG. 6, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

In addition, the light source 110 may be disposed in the groove of the package 115.

Subsequently, the transparent resin 112 may be filled in the groove of the package 115 to cover the light source 110, and the transparent resin 112 may be any one or a mixture of transparent epoxy resin and silicon.

Here, the packages 115 including the light sources 110 may be arranged side by side on the substrate 120, and the packages 115 adjacent to each other may be spaced apart from each other by a predetermined distance.

In addition, the transparent resin 112 may protect the light source 110 and its electrical connection line and serve as a lens.

In addition, the transparent resin 112 may include a phosphor (not shown) to convert the wavelength of the light emitted from the light source 110.

As such, the individual packages 115 including the light source 110 may be spaced apart from each other, and thus may be electrically insulated from each other, and may be individually driven, respectively, and reduce the loss of light generated from the light source 110. The brightness can be increased.

7 is a cross-sectional view illustrating a light source module according to a fourth embodiment.

As shown in FIG. 7, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

In addition, the transparent resin 112 may be disposed on the light source 110, and the transparent resin 112 may be any one or a mixture of transparent epoxy resin and silicon.

Here, the transparent resin 112 may be disposed separately from each light source 110.

For example, the transparent resins 112 are individually disposed on the first, second, third, and fourth light sources 102, 104, 106, and 108, and the transparent resins 112 adjacent to each other are spaced apart from each other. Can be placed apart.

In addition, the transparent resin 112 may protect the light source 110 and its electrical connection line and serve as a lens.

In addition, the transparent resin 112 may include a phosphor 116 to convert the wavelength of the light emitted from the light source 110.

Here, the phosphor 116 may be included in the transparent resin 112 of the light source 110, or may be included in the transparent resin 112 of the entire light source 110.

In some cases, the phosphor 116 may not be included in the transparent resin 112 of the entire light source 110.

For example, the phosphor 116 may be included only in the transparent resin 112 of the third light source 106 among the first, second, third, and fourth light sources 102, 104, 106, and 108.

Here, the content ratio of the transparent resin 112 and the phosphor 116 may be about 1: 1 to 1: 3.

As an example, the phosphor 116 may include any one or multiple of the phosphors 116 having a wavelength in the range of about 550 to 700 nm.

As another example, the transparent resin 112 may include only the phosphor 116 having a wavelength in the range of about 580 to 600 nm, or may include only the phosphor 116 having a wavelength in the range of about 601 to 650 nm.

In some cases, the transparent resin 112 may include both the first phosphor 116 having a wavelength in the range of about 580 to 600 nm and the second phosphor 116 having a wavelength in the range of about 601 to 650 nm.

In addition, the phosphor 116 may have at least one of a polygonal shape, a spherical shape, and a flake shape.

For example, the phosphor 116 may have a spherical shape having an average particle diameter of about 100 nm to 50 μm.

In addition, the transparent resin 112 may further include a viscosity enhancer selected from SiO ₂ , Y ₂ O ₃ , TiO ₂ .

The reason for including the viscosity enhancer is to prevent the particles of the phosphor 116 included in the transparent resin 112 from being concentrated in a predetermined region and to diffuse uniformly.

8A to 8C are cross-sectional views illustrating a light source module to which a phosphor layer is applied.

8A to 8C, a light source may be disposed on the substrate 120, and a phosphor layer may be disposed on the light source.

For example, the third light source 106 of FIG. 7 may include a phosphor layer. The phosphor layer may include a transparent resin 112 and a phosphor 116. The transparent resin 112 and the phosphor 116 may be disposed. The content ratio of may be about 1: 1 to 1: 3.

At this time, the transparent resin 112 of the phosphor layer may be any one or a mixture of transparent epoxy resin and silicon.

In addition, the phosphor 116 of the phosphor layer may include any one or a plurality of phosphors having a wavelength in a range of about 550 to 700 nm.

In addition, the phosphor layer may be disposed to cover the entire surface of the third light source 106, as shown in FIG. 6A.

In some cases, as shown in FIG. 6B, the phosphor layer may be disposed only on the upper part of the third light source 106, or as illustrated in FIG. 6C.

As such, the reason for arranging the phosphor layer in various ways is that the color and the intensity of light generated from the light source may vary depending on the area and the position of the phosphor layer.

9A and 9B are diagrams illustrating an arrangement relationship between a rotating body and a light source module.

As shown in FIGS. 9A and 9B, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

Here, the first light source 102 has a first forward voltage Vf1 characteristic, the second light source 104 has a second forward voltage Vf2 characteristic, and the third light source 106 has a third forward voltage ( Vf3), and the fourth light source 108 may have a fourth forward voltage Vf4.

The light sources 110 of the light source module 100 emit light corresponding to the rotation speed of the rotating body 20, so that the current rotating speed of the rotating body 20 can be easily recognized from the outside.

Therefore, as shown in FIG. 9A, the light source module 100 may be attached to one side of the central axis 22 of the rotating body 20.

Here, when the light source module 100 is attached to the rotating body 20, the substrate 120 of the light source module 100 and the coupling member inside the rotating body 20 so as not to be exposed to the outside of the rotating body 20 The light source 110 of the light source module 100 may be fastened to be exposed to the outer surface of the rotating body 20.

In this case, since the light source module 100 is attached to the rotating body 20, the light generated from the light source 110 by the rotation of the rotating body 20 may be displayed in various shapes.

In another case, as shown in FIG. 9B, the light source module 100 may be disposed away from the rotating body 20 by a distance d.

Here, the light source module 100 may be freely disposed in the display space desired by the user, and thus may have a degree of freedom in design.

10A and 10B are cross-sectional views illustrating a substrate of a light source module.

10A and 10B, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

Here, the first light source 102 has a first forward voltage Vf1 characteristic, the second light source 104 has a second forward voltage Vf2 characteristic, and the third light source 106 has a third forward voltage ( Vf3), and the fourth light source 108 may have a fourth forward voltage Vf4.

The substrate 120 of the light source module 100 may include a first side and a second side facing each other. The thickness t1 of the first side and the thickness t2 of the second side may be the same, but Depending on, they may be different.

For example, when the light source module 100 is attached to one side of the central axis of the rotating body 20 of FIG. 9A, the first side surface of the substrate 120 of the light source module 100 is adjacent to the central axis of the rotating body. If the second side of the substrate 120 of the light source module 100 is disposed away from the central axis of the rotating body, the thickness t1 of the first side may be thicker than the thickness t2 of the second side.

The reason is that the light source module 100 is stably attached to the rotating body when the rotating body is rotationally driven.

If, among the substrates 120 of the light source module 100, the first side of the substrate 120 adjacent to the central axis of the rotating body is thin, and the second side of the substrate 120 far from the central axis of the rotating body is thick. If it is, the center of gravity of the substrate 120 moves in the outer direction of the rotating body, the light source module 100 is detached from the rotating body or attached to the rotating body unstable at high speed during rotation of the rotating body. Can be.

Therefore, if the first side of the substrate 120 adjacent to the central axis of the rotating body is thickened and the second side of the substrate 120 far from the central axis of the rotating body is made thin, the center of gravity of the substrate 120 is Since it moves in the center direction of the rotating body, the light source module 100 can be stably attached to the rotating body even at a high speed of rotation of the rotating body.

The substrate 120 of FIG. 10A is an embodiment in which the upper surface where the light sources 110 are disposed is not parallel to the lower surface where the light sources 110 are not disposed. The lower surface of the substrate 120 is an upper surface of the substrate 120. It may be an inclined plane inclined to the plane.

Here, when the area of the substrate 120 where the first light source 102 is disposed is adjacent to the central axis of the rotating body, and the area of the substrate 120 where the fourth light source 108 is disposed is far from the central axis of the rotating body. The thickness of the substrate 120 may gradually decrease from an area of the substrate 120 where the first light source 102 is disposed to an area of the substrate 120 where the fourth light source 108 is disposed.

In some cases, as shown in FIG. 10B, the substrate 120 may have an upper surface where the light sources 110 are disposed and a lower surface where the light sources 110 are not disposed, and the lower surface of the substrate 120 may be the first surface. It may be divided into a region, a second region, and a third region.

Here, the first region of the substrate 120 is adjacent to the central axis of the rotating body, the third region of the substrate 120 is far from the central axis of the rotating body, the second region of the substrate 120 is a substrate ( It may be disposed between the first region and the third region of the 120.

In this case, the thickness t11 of the first region of the substrate 120 may be thicker than the thickness t12 of the second region of the substrate 120 and the thickness t13 of the third region, and the thickness t12 of the second region of the substrate 120 may be It may be thicker than the thickness t13 of the third region.

The thickness t13 of the third region of the substrate 120 may be thinner than the thickness t11 of the first region of the substrate 120 and the thickness t12 of the second region.

For example, the first region of the substrate 120 on which the first light source 102 is disposed is adjacent to the central axis of the rotating body, and the third region of the substrate 120 on which the fourth light source 108 is disposed is the rotating body. Away from the central axis of the substrate 120, the first region of the substrate 120 on which the first light source 102 is disposed is thickest and the thickness of the substrate 120 on which the fourth light source 108 is disposed The third region may be the thinnest.

As such, if the area of the substrate 120 adjacent to the center axis of the rotating body is made thick and the area of the substrate 120 far from the center axis of the rotating body is made thin, the center of gravity of the substrate 120 is the center of the rotating body. By moving closer to the direction, the light source module 100 can be stably attached to the rotating body even during the high speed rotation of the rotating body.

11A and 11B are cross-sectional views illustrating a light source arrangement of the light source module.

11A and 11B, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

Here, the first light source 102 has a first forward voltage Vf1 characteristic, the second light source 104 has a second forward voltage Vf2 characteristic, and the third light source 106 has a third forward voltage ( Vf3), and the fourth light source 108 may have a fourth forward voltage Vf4.

The light sources 110 of the light source module 100 may be arranged side by side, and the light sources 110 adjacent to each other may be spaced apart from each other.

Here, the intervals between the light sources 110 may be arranged in the same manner, but may be disposed at different intervals.

For example, when the light source module 100 including the first, second, third, and fourth light sources 102, 104, 106, and 108 is attached to one side of the central axis of the rotating body 20 of FIG. 9A. Between the first light source 102 and the second light source 104 if the first light source 102 is adjacent to the central axis of the rotating body and the fourth light source 108 is disposed far from the central axis of the rotating body. The interval d11 may be closer than the interval d13 between the third light source 106 and the fourth light source 108.

That is, as the light sources 110 of the light source module 100 move away from the central axis of the rotating body 20 of FIG. 9A, the distance between the light sources 110 may gradually increase.

Therefore, the light sources 110 of the light source module 100 are disposed at a high density in the region of the substrate 120 adjacent to the central axis of the rotating body 20 of FIG. 9A, and the light source module 100 of the rotating body 20 of FIG. In the region of the substrate 120 remote from the central axis, it may be arranged at a low density.

The reason is that the light source module 100 is stably attached to the rotating body when the rotating body is rotationally driven.

If, among the substrates 120 of the light source module 100, the light sources 110 are disposed at a low density in the region of the substrate 120 adjacent to the central axis of the rotor, the substrate 120 is far from the central axis of the rotor. If the light sources 110 are arranged at a high density in the region, the center of gravity of the substrate 120 moves in the outward direction of the rotating body, so that at high speed rotation of the rotating body, the light source module 100 is moved from the rotating body by the law of inertia. It may fall off or attach unstablely to the rotor.

Therefore, in the region of the substrate 120 adjacent to the central axis of the rotating body, the light sources 110 are disposed at high density, and in the region of the substrate 120 far from the central axis of the rotating body, the light sources 110 are of low density. If disposed, the center of gravity of the substrate 120 is moved in the direction of the center of the rotating body, so that the light source module 100 can be stably attached to the rotating body even at a high speed of rotation of the rotating body.

As shown in FIG. 11A, first, second, third, and fourth light sources 102, 104, 106, and 108 are disposed on the substrate 120, and the first light source 102 is adjacent to the central axis of the rotating body. The fourth light source 108 may be disposed far from the central axis of the rotating body.

Here, the distance d11 between the first light source 102 and the second light source 104 is closer than the distance d12 between the second light source 104 and the third light source 106, and the third light source 106 and the fourth light source 104. It may be closer than the distance d13 between the light sources 108.

The distance d12 between the second light source 104 and the third light source 106 may be closer than the distance d13 between the third light source 106 and the fourth light source 108.

That is, the distance between the light sources 110 may be gradually farther away from the central axis of the rotating body.

In some cases, as shown in FIG. 10B, the substrate 120 may include an eleventh region adjacent to the central axis of the rotating body and a twelfth region away from the central axis of the rotating body. The number of light sources 110 disposed in the region may be greater than the number of light sources 110 disposed in the twelfth region of the substrate 120.

For example, when the first, second, third, and fourth light sources 102, 104, 106, and 108 are disposed on the substrate 120, the eleventh of the substrate 120 adjacent to the central axis of the rotating body The first, second, and third light sources 102, 104, and 106 may be disposed in the region, and only the fourth light source 108 may be disposed in the twelfth region of the substrate 120 that is far from the central axis of the rotating body. .

As such, in the region of the substrate 120 adjacent to the central axis of the rotating body, the light sources 110 are disposed at high density, and in the region of the substrate 120 far from the central axis of the rotating body, the light sources 110 are of low density. If disposed as, the center of gravity of the substrate 120 moves in the direction of the center of the rotating body, so that the light source module 100 can be stably attached to the rotating body even at high speed of rotation of the rotating body.

12A to 12C are cross-sectional views illustrating a light source module having an uneven pattern.

12A through 12C, the light source module 100 may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

Here, the first light source 102 has a first forward voltage Vf1 characteristic, the second light source 104 has a second forward voltage Vf2 characteristic, and the third light source 106 has a third forward voltage ( Vf3), and the fourth light source 108 may have a fourth forward voltage Vf4.

When the light source module 100 is applied to a lamp unit capable of recognizing the current rotational speed of the rotating body, the light source module 100 should be able to recognize the light emission state of the light source module 100 from a distance. Conditions may be required in which the brightness of the light and the straightness of the light must be high.

Therefore, in the embodiment, by arranging the concave-convex pattern on the optical member or the transparent resin, it is possible to manufacture a light source module with improved brightness and straightness of light.

For example, as shown in FIG. 12A, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and the like. The optical member 130 may be disposed on the fourth light sources 102, 104, 106, and 108.

Here, the optical member 130 may be disposed at a predetermined distance from the substrate 120 and the light sources 110, and an air gap may be formed between the optical member 130 and the substrate 120.

In addition, an uneven pattern 132 may be disposed on an upper surface of the optical member 130.

Here, the optical member 130 may be generally formed of an acrylic resin, but is not limited thereto. In addition, polystyrene (PS), polymethyl methacrylate (PMMA), cyclic olefin copoly (COC), and polyethylene terephthalate ( It may be made of a material capable of performing a light diffusing function such as PET), a high permeability plastic such as resin.

In addition, the uneven pattern 132 may have a stripe shape arranged in one direction.

In some cases, the optical member 130 may be formed of several layers, and the uneven pattern 132 may be formed on the top or one surface of the layer.

Subsequently, as shown in FIG. 12B, the transparent resin 112 may be disposed on the light source 110, and the transparent resin 112 may be any one or a mixture of transparent epoxy resin and silicon.

Here, the uneven pattern 112a may be disposed on the upper surface of the transparent resin 112.

In addition, the transparent resin 112 may be disposed to cover the entire light source 110 together.

For example, the transparent resin 112 is disposed to cover the entire first, second, third, and fourth light sources 102, 104, 106, and 108, and the transparent resins 112 adjacent to each other are not spaced apart from each other. Can be connected to each other.

Here, the transparent resin 112 may be disposed to cover the entire light source 110 together, thereby realizing a surface light source.

Here, the surface light source means a light source having a light emitting portion having a diffused shape in a plane shape. In an embodiment, the transparent light source 112 is used to implement a surface light source, thereby providing a light source 110. The color of the light resulting from the keys can be easily identified from the outside.

Next, as shown in FIG. 12C, the transparent resin 112 may be disposed separately from each light source 110.

Here, the uneven pattern 112a may be disposed on the upper surface of each transparent resin 112.

For example, the transparent resins 112 are individually disposed on the first, second, third, and fourth light sources 102, 104, 106, and 108, and the transparent resins 112 adjacent to each other are spaced apart from each other. Can be placed apart.

In addition, the transparent resin 112 may protect the light source 110 and its electrical connection line and serve as a lens.

In addition, the transparent resin 112 may include a phosphor (not shown) to convert the wavelength of the light emitted from the light source 110.

As described above, in the embodiment, by arranging the uneven pattern on the optical member or the transparent resin on the light source module 100, a light source module having improved brightness and linearity of light can be manufactured.

When the light source module 100 is applied to a lamp unit capable of recognizing the current rotational speed of the rotating body, the light emitting module 100 can recognize the light emitting state of the light source module 100 even from a remote place. Even if the position is located in the light source module through the light emitting state can accurately recognize the rotational speed of the rotating body.

13A and 13B are plan views illustrating electrical connections of the light source module according to the first embodiment.

As shown in FIGS. 13A and 13B, the light source module of the first embodiment may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

Here, the plurality of light sources 110 may be arranged side by side, individually driven, and may have different forward voltage values.

In this case, the forward voltage value may gradually decrease or increase from the first light source 110 to the last light source 110.

In addition, the light sources 110 are electrically connected to one first electrode pattern 153 disposed on the substrate 120 as shown in FIG. 13A, and through the wire 155, the substrate ( Electrical connections may be made to the plurality of second electrode patterns 151 disposed on the 120, respectively.

Therefore, the light sources 110 adjacent to each other are electrically insulated from each other, and each of them may be driven separately.

In some cases, as illustrated in FIG. 13B, the light sources 110 may be electrically connected to the plurality of first electrode patterns 153 disposed on the substrate 120, respectively, and the wires 155 may be connected. Through this, electrical connection may be commonly made to one second electrode pattern 151 disposed on the substrate 120.

Therefore, the light sources 110 adjacent to each other are electrically insulated from each other, and each of them may be driven separately.

As such, the plurality of light sources 110 according to the first exemplary embodiment may be configured as one light source array arranged side by side, and each light source 110 may be driven separately, and may have different forward voltage values. Can have

14A and 14B are plan views illustrating electrical connections of the light source module according to the second embodiment.

As shown in FIGS. 14A and 14B, the light source module of the second embodiment may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

Here, the light source module may include at least one light source array in which a plurality of light sources are arranged side by side.

At this time, the first light source array 110a and the second light source array 110b which are adjacent to each other among the light source arrays are individually driven, and the forward voltage value of the light source 110 included in the first light source array 110a and The forward voltage values of the light sources 110 included in the second light source array 110b may be the same or may be different from each other in some cases.

For example, when the forward voltage value of the light source 110 included in the first light source array 110a and the forward voltage value of the light source 110 included in the second light source array 110b are different from each other, the first light source array ( The difference between the forward voltage value of the light source 110 included in 110a and the forward voltage value of the light source 110 included in the second light source array 110b may be about 0.1V to 2V.

In addition, the forward voltage value of the light source 110 included in the first light source array 110a gradually decreases from the first light source 110 to the last light source 110 in the first light source array 110a. The forward voltage value of the light source 110 included in the second light source array 110b may gradually increase from the first light source 110 to the last light source 110 among the second light source array 110b.

In some cases, the forward voltage value of the light source 110 included in the first light source array 110a is gradually smaller from the first light source 110 to the last light source 110 among the first light source array 110a. The forward voltage value of the light source 110 included in the second light source array 110b may gradually decrease from the first light source 110 to the last light source 110 among the second light source array 110b. have.

As another case, the forward voltage value of the light source 110 included in the first light source array 110a gradually increases from the first light source 110 to the last light source 110 among the first light source array 110a. The forward voltage value of the light source 110 included in the second light source array 110b may increase gradually from the first light source 110 to the last light source 110 in the second light source array 110b. .

In addition, the light sources 110 included in the first light source array 110a are individually driven and have different forward voltage values, and the light sources 110 included in the second light source array 110b are each individually driven. And may have different forward voltage values.

As shown in FIG. 14A, the light sources 110 of the first light source array 100a are electrically connected to one first electrode pattern 153 disposed on the substrate 120, and have a wire 155. ), Electrical connections may be made to the plurality of second electrode patterns 151 disposed on the substrate 120, respectively.

Subsequently, the light sources 110 of the second light source array 100b are electrically connected to one third electrode pattern 163 disposed on the substrate 120, and are connected to each other via a wire 165. In addition, electrical connections may be made to the plurality of fourth electrode patterns 161 disposed on the substrate 120, respectively.

Therefore, the light sources 110 adjacent to each other are electrically insulated from each other, and each of them may be driven separately.

In some cases, as shown in FIG. 14B, the light sources 110 of the first light source array 100a may be electrically connected to a plurality of first electrode patterns 153 disposed on the substrate 120, respectively. Through a wire 155, electrical connection may be commonly made to one second electrode pattern 151 disposed on the substrate 120.

Subsequently, the light sources 110 of the second light source array 100b are electrically connected to a plurality of third electrode patterns 163 disposed on the substrate 120, respectively, and wires 155 are provided. The electrical connection may be made in common to one fourth electrode pattern 161 disposed on the substrate 120.

Therefore, the light sources 110 adjacent to each other are electrically insulated from each other, and each of them may be driven separately.

As described above, the light source module according to the second embodiment includes at least one light source array in which a plurality of light sources are arranged side by side, and among the light source arrays, the first light source array 110a adjacent to each other; Each of the second light source arrays 110b may be individually driven and may have different forward voltage values.

In addition, the light sources 110 included in the first light source array 110a are individually driven and have different forward voltage values, and the light sources 110 included in the second light source array 110b are each individually driven. And may have different forward voltage values.

15A and 15B are plan views illustrating electrical connections of the light source module according to the third embodiment.

As shown in FIGS. 15A and 15B, the light source module of the third embodiment may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

Here, the light source module may include at least one light source array in which a plurality of light sources are arranged side by side.

At this time, the first light source array 110a and the second light source array 110b which are adjacent to each other among the light source arrays are individually driven, and the forward voltage value of the light source 110 included in the first light source array 110a and The forward voltage values of the light sources 110 included in the second light source array 110b may be the same or may be different from each other in some cases.

For example, when the forward voltage value of the light source 110 included in the first light source array 110a and the forward voltage value of the light source 110 included in the second light source array 110b are different from each other, the first light source array ( The difference between the forward voltage value of the light source 110 included in 110a and the forward voltage value of the light source 110 included in the second light source array 110b may be about 0.1V to 2V.

In addition, the forward voltage value of the light source 110 included in the first light source array 110a gradually decreases from the first light source 110 to the last light source 110 in the first light source array 110a. The forward voltage values of the light sources 110 included in the second light source array 110b may be the same from the first light source 110 to the last light source 110 among the second light source arrays 110b.

In some cases, the forward voltage value of the light source 110 included in the first light source array 110a is gradually increased from the first light source 110 to the last light source 110 among the first light source array 110a. The forward voltage values of the light source 110 included in the second light source array 110b may be the same from the first light source 110 to the last light source 110 among the second light source array 110b.

As such, the light sources 110 included in the first light source array 110a are individually driven and have different forward voltage values, and the light sources 110 included in the second light source array 110b are simultaneously driven. , May have the same forward voltage value.

As shown in FIG. 15A, the light sources 110 of the first light source array 100a are electrically connected to one first electrode pattern 153 disposed on the substrate 120, and have a wire 155. ), Electrical connections may be made to the plurality of second electrode patterns 151 disposed on the substrate 120, respectively.

Subsequently, the light sources 110 of the second light source array 100b are electrically connected to one third electrode pattern 163 disposed on the substrate 120, and are connected to each other via a wire 165. In addition, electrical connection may be commonly made to one fourth electrode pattern 161 disposed on the substrate 120.

Therefore, the light sources 110 included in the first light source array 110a may be driven separately, and the light sources 110 included in the second light source array 110b may be driven simultaneously.

In some cases, as shown in FIG. 15B, the light sources 110 of the first light source array 100a may be electrically connected to a plurality of first electrode patterns 153 disposed on the substrate 120, respectively. Through a wire 155, electrical connection may be commonly made to one second electrode pattern 151 disposed on the substrate 120.

Subsequently, the light sources 110 of the second light source array 100b are electrically connected to one third electrode pattern 163 disposed on the substrate 120, and are connected to each other via a wire 155. In addition, electrical connection may be commonly made to one fourth electrode pattern 161 disposed on the substrate 120.

Therefore, the light sources 110 included in the first light source array 110a may be driven separately, and the light sources 110 included in the second light source array 110b may be driven simultaneously.

As described above, the light source module according to the third embodiment includes at least one light source array in which a plurality of light sources are arranged side by side, and among the light source arrays, the first light source array 110a adjacent to each other; Each of the second light source arrays 110b may be individually driven and may have different forward voltage values.

In addition, the light sources 110 included in the first light source array 110a are individually driven and have different forward voltage values, and the light sources 110 included in the second light source array 110b are simultaneously driven. , May have the same forward voltage value.

16A and 16B are plan views illustrating electrical connections of the light source module according to the fourth embodiment.

As shown in FIGS. 16A and 16B, the light source module of the fourth embodiment may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

Here, the light source module may include at least one light source array in which a plurality of light sources are arranged side by side.

At this time, the first light source array 110a and the second light source array 110b which are adjacent to each other among the light source arrays are individually driven, and the forward voltage value of the light source 110 included in the first light source array 110a and The forward voltage values of the light sources 110 included in the second light source array 110b may be the same or may be different from each other in some cases.

For example, when the forward voltage value of the light source 110 included in the first light source array 110a and the forward voltage value of the light source 110 included in the second light source array 110b are different from each other, the first light source array ( The difference between the forward voltage value of the light source 110 included in 110a and the forward voltage value of the light source 110 included in the second light source array 110b may be about 0.1V to 2V.

In addition, the forward voltage values of the light sources 110 included in the first light source array 110a may be equal to each other from the first light source 110 to the last light source 110 among the first light source arrays 110a. The forward voltage value of the light source 110 included in the second light source array 110b may gradually decrease from the first light source 110 to the last light source 110 among the second light source array 110b. .

In some cases, the forward voltage values of the light sources 110 included in the first light source array 110a may be the same from the first light source 110 to the last light source 110 among the first light source arrays 110a. The forward voltage value of the light source 110 included in the second light source array 110b may gradually increase from the first light source 110 to the last light source 110 in the second light source array 110b. have.

As such, the light sources 110 included in the first light source array 110a are simultaneously driven and have the same forward voltage value, and the light sources 110 included in the second light source array 110b are individually driven. , May have different forward voltage values.

As illustrated in FIG. 16A, the light sources 110 of the first light source array 100a are electrically connected to one first electrode pattern 153 disposed on the substrate 120, and have a wire 155. In this case, electrical connection may be made to one second electrode pattern 151 disposed on the substrate 120 in common.

Subsequently, the light sources 110 of the second light source array 100b are individually electrically connected to the plurality of third electrode patterns 163 disposed on the substrate 120, and wires 165 may be provided. The electrical connection may be made in common to one fourth electrode pattern 161 disposed on the substrate 120.

Therefore, the light sources 110 included in the first light source array 110a may be driven simultaneously, and the light sources 110 included in the second light source array 110b may be driven individually.

In some cases, as shown in FIG. 16B, the light sources 110 of the first light source array 100a are electrically connected to one first electrode pattern 153 disposed on the substrate 120, and wires may be formed. Through wires 155, electrical connection may be commonly made to one second electrode pattern 151 disposed on the substrate 120.

Subsequently, the light sources 110 of the second light source array 100b are electrically connected to a plurality of third electrode patterns 163 disposed on the substrate 120, respectively, and wires 155 are provided. The electrical connection may be made in common to one fourth electrode pattern 161 disposed on the substrate 120.

Therefore, the light sources 110 included in the first light source array 110a may be driven simultaneously, and the light sources 110 included in the second light source array 110b may be driven individually.

As described above, the light source module according to the fourth embodiment includes at least one light source array in which a plurality of light sources are arranged side by side, and among the light source arrays, the first light source array 110a adjacent to each other; Each of the second light source arrays 110b may be individually driven and may have different forward voltage values.

The light sources 110 included in the first light source array 110a are simultaneously driven and have the same forward voltage value, and the light sources 110 included in the second light source array 110b are individually driven. , May have different forward voltage values.

17 is a plan view illustrating electrical connection of a light source module according to a fifth embodiment.

As shown in FIG. 17, the light source module of the fifth embodiment may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

Here, the light source module may include at least one light source array in which a plurality of light sources are arranged side by side.

At this time, the first light source array 110a and the second light source array 110b which are adjacent to each other among the light source arrays are individually driven, and the forward voltage value of the light source 110 included in the first light source array 110a and The forward voltage values of the light sources 110 included in the second light source array 110b may be the same or may be different from each other in some cases.

For example, when the forward voltage value of the light source 110 included in the first light source array 110a and the forward voltage value of the light source 110 included in the second light source array 110b are different from each other, the first light source array ( The difference between the forward voltage value of the light source 110 included in 110a and the forward voltage value of the light source 110 included in the second light source array 110b may be about 0.1V to 2V.

In addition, the forward voltage values of the light sources 110 included in the first light source array 110a may be equal to each other from the first light source 110 to the last light source 110 among the first light source arrays 110a. The forward voltage values of the light source 110 included in the second light source array 110b may be the same from the first light source 110 to the last light source 110 among the second light source array 110b.

As such, the light sources 110 included in the first light source array 110a are simultaneously driven, have the same forward voltage value, and the light sources 110 included in the second light source array 110b are simultaneously driven. , May have the same forward voltage value.

As illustrated in FIG. 17, the light sources 110 of the first light source array 100a are electrically connected to one first electrode pattern 153 disposed on the substrate 120, and have a wire 155. In this case, electrical connection may be made to one second electrode pattern 151 disposed on the substrate 120 in common.

Subsequently, the light sources 110 of the second light source array 100b are electrically connected to one first electrode pattern 153 disposed on the substrate 120, and are connected to each other via a wire 155. In addition, electrical connection may be commonly made to one second electrode pattern 151 disposed on the substrate 120.

Therefore, the light sources 110 included in the first light source array 110a may be driven simultaneously, and the light sources 110 included in the second light source array 110b may be driven simultaneously.

As such, the light source module according to the fifth embodiment includes at least one light source array in which a plurality of light sources are arranged side by side, and among the light source arrays, the first light source array 110a adjacent to each other; Each of the second light source arrays 110b may be individually driven and may have different forward voltage values.

The light sources 110 included in the first light source array 110a are simultaneously driven and have the same forward voltage value, and the light sources 110 included in the second light source array 110b are simultaneously driven. It may have the same forward voltage value.

18A and 18B are plan views illustrating a light source module including a plurality of light source arrays.

As shown in FIGS. 18A and 18B, the light source module may include a substrate 120 and a plurality of light sources 110 arranged on the substrate 120.

Here, the light source module may include at least one light source array in which a plurality of light sources are arranged side by side.

At this time, among the light source arrays, the first light source array 110a and the second light source array 110b which are adjacent to each other are individually driven, and the forward voltage value of the light source 110 included in the first light source array 110a and The forward voltage values of the light sources 110 included in the second light source array 110b may be the same or may be different from each other in some cases.

For example, when the forward voltage value of the light source 110 included in the first light source array 110a and the forward voltage value of the light source 110 included in the second light source array 110b are different from each other, the first light source array ( The difference between the forward voltage value of the light source 110 included in 110a and the forward voltage value of the light source 110 included in the second light source array 110b may be about 0.1V to 2V.

The light source module including the plurality of light source arrays may arrange the light sources in various arrangements according to the structure of the rotating body to be applied.

For example, as illustrated in FIG. 18A, the first light source array 110a and the second light source array 110b may be disposed in parallel with each other.

In some cases, as shown in FIG. 18B, the first light source array 110a may be disposed in a first direction, and the second light source array 110b may be disposed in a second direction perpendicular to the first direction.

Here, the arrangement method of FIG. 18A may reduce the size of the light source module, and thus, may be advantageously applied to a small rotating body. In the arrangement method of FIG. It may be advantageous to apply to

As such, the light source module including the plurality of light source arrays may arrange the light sources in various arrangements according to the structure of the rotating body to be applied.

19 is a view showing the power supply of FIG.

As shown in FIG. 19, the power supply unit 300 may supply power corresponding to the rotational speed of the rotor 20 to the light source module.

Here, the power supply unit 300 may be a type including a power generation unit 320 that can generate electricity by itself.

In some cases, the power supply unit 300 may be a type that does not include the power generation unit 320.

As illustrated in FIG. 19, the power supply unit 300 including the power generation unit 320 may include a power generation unit 320, a charging unit 330, and a charging control unit 340.

Here, the power generation unit 320 may convert the rotational force of the rotating body 20 into electrical energy, and the charging unit 330 may convert the electrical energy of the power generation unit 320 into power to charge.

In addition, the charging control unit 340 may control the charging unit 330 to supply power corresponding to the rotational speed of the rotating body 20 to the light source module.

At this time, the power generation unit 320 of the power supply unit 300, the magnetic body is fixed to the rotating body 20 and rotates in accordance with the rotational speed of the rotating body 20, the rotational axis of the magnetic body is disposed on the rotation of the magnetic body It may include a coil for generating electricity.

Therefore, the light sources of the light source module emit light corresponding to the rotational speed of the rotating body 20, so that the current rotating speed of the rotating body 20 can be easily recognized from the outside.

20A and 20B are cross-sectional views illustrating the power generation unit of FIG. 19.

As shown in FIGS. 20A and 20B, the power generation unit 320 of the power supply unit 300 may include a magnetic body 322 and a coil 324.

Here, as shown in Figure 20a, the magnetic body 322 is fixed to the rotating body (20 of Figure 19) can be rotated corresponding to the rotational speed of the rotating body, the coil 324 to the rotation center axis of the magnetic body 322 Disposed to generate electricity according to the rotation of the magnetic body 322.

That is, the magnetic body 322 may be formed with a hollow hole, and the coil 324 may be disposed in the hole of the magnetic body 322.

Therefore, the magnetic body 322 may have a structure surrounding the outside of the coil 324.

In some cases, as shown in FIG. 20B, the magnetic body 322 may be fixed to the rotating body 20 of FIG. 19, and the coil 324 may be disposed to surround the outside of the magnetic body 322.

Accordingly, the magnetic body 322 may be fixed to the rotating body to rotate in accordance with the rotational speed of the rotating body, and the coil 324 surrounding the outside of the magnetic body 322 may generate electricity according to the rotation of the magnetic body 322. have.

As such, the embodiment may minimize power consumption of the light source module by using a power supply capable of self-generating.

21 is a view for explaining a lamp unit according to another embodiment.

As shown in FIG. 21, the lamp unit according to the embodiment may include a light source module 100, a driving unit 200, a power supply unit 300, a control unit 400, and a sensor unit 500.

Here, the light source module 100 may be attached to the rotating body 20 and may include a plurality of light sources 110.

In addition, among the plurality of light sources 110, adjacent light sources 110 may have different forward voltages.

In this case, the difference between the forward voltage values of the light sources 110 adjacent to each other may be about 0.1V to 2V.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

Here, the first light source 102 has a first forward voltage Vf1 characteristic, the second light source 104 has a second forward voltage Vf2 characteristic, and the third light source 106 has a third forward voltage ( Vf3), and the fourth light source 108 may have a fourth forward voltage Vf4.

The forward voltage value of the first light source 102 may be about 0.1V to 2V smaller than the forward voltage values of the second, third, and fourth light sources 104, 106, and 108, and the fourth light source 108 The forward voltage value of may be about 0.1V to 2V greater than the forward voltage values of the first, second, and third light sources 102, 104, and 106.

Further, the forward voltage value of the second light source 104 may be greater than the forward voltage value of the first light source 102, and may be smaller than the forward voltage values of the third and fourth light sources 106 and 108, and the third The forward voltage value of the light source 106 may be larger than the forward voltage values of the first and second light sources 102 and 104 and smaller than the forward voltage value of the fourth light source 108.

Here, the forward voltage value of the second light source 104 is about 0.1V to 2V greater than the forward voltage value of the first light source 102, and is about 0.1 greater than the forward voltage values of the third and fourth light sources 106 and 108. V to 2V may be smaller, and the forward voltage value of the third light source 106 is about 0.1V to 2V greater than the forward voltage values of the first and second light sources 102 and 104, and It may be about 0.1V to 2V less than the forward voltage value.

In another embodiment, the forward voltage value of the first light source 102 may be greater than the forward voltage values of the second, third, and fourth light sources 104, 106, and 108, and the forward direction of the fourth light source 108 may be higher. The voltage value may be smaller than the forward voltage values of the first, second, and third light sources 102, 104, and 106.

Here, the forward voltage value of the first light source 102 may be about 0.1V to 2V greater than the forward voltage values of the second, third, and fourth light sources 104, 106, and 108, and the fourth light source 108 The forward voltage value of may be about 0.1V to 2V smaller than the forward voltage values of the first, second, and third light sources 102, 104, and 106.

The forward voltage value of the second light source 104 may be smaller than the forward voltage values of the first light source 102, and may be greater than the forward voltage values of the third and fourth light sources 106 and 108. The forward voltage value of the light source 106 may be smaller than the forward voltage values of the first and second light sources 102 and 104 and greater than the forward voltage value of the fourth light source 108.

Here, the forward voltage value of the second light source 104 is about 0.1V to 2V smaller than the forward voltage value of the first light source 102, and is about 0.1 smaller than the forward voltage values of the third and fourth light sources 106 and 108. V to 2V greater, the forward voltage value of the third light source 106 is about 0.1V to 2V smaller than the forward voltage values of the first and second light sources 102 and 104, and It can be about 0.1V to 2V greater than the forward voltage value.

As such, the forward voltage value of the light source 110 may gradually decrease or increase from the first light source 102 to the fourth light source 108.

Next, the sensor unit 500 senses the rotational speed of the rotating body 20, and the power supply unit 300 may supply power corresponding to the rotating speed of the rotating body 20 to the light source module 100. have.

Here, the power supply unit 300 is a power supply unit 300 does not include a power generation unit, according to the control signal of the control unit 400, the power (power) corresponding to the rotational speed of the rotating body 20, the light source module 100 ) Can be supplied.

Subsequently, the driving unit 200 drives one of the plurality of light sources 110 among the plurality of light sources 110 according to a power corresponding to the rotational speed of the rotating body 20, and the controller 400 includes a sensor unit ( The power supply unit 300 and the driving unit 200 may be controlled in correspondence with the rotational speed of the rotating body 20 sensed from the 500.

As described above, the embodiment is configured to use the power supply unit 300 does not include a power generation unit, the control unit 400 controls the sensor unit 500 to sense the rotational speed of the rotating body 20, the sensed While controlling the power supply unit 300 to supply power corresponding to the rotation speed to the light source module 100, the driving unit 200 may be controlled to drive the light source 110 to the corresponding power.

Therefore, the light sources 110 of the light source module 100 emit light corresponding to the rotation speed of the rotating body 20, so that the current rotating speed of the rotating body 20 can be easily recognized from the outside.

As such, the embodiment can recognize the current rotational speed of the rotating body by using a plurality of light sources that emit light according to the rotating speed of the rotating body, and thus can appropriately control the speed of the rotating body.

In addition, the embodiment may use a plurality of light sources having different forward voltages to minimize power consumption.

In addition, when the embodiment is applied to the wheel of the vehicle, by using a plurality of light sources attached to the wheel of the vehicle, it is possible to display the current speed of the vehicle to the outside, it is easy to control the speeding vehicle, help the driver's safe driving Can give

22A and 22B are views illustrating a light source module mounted to a rotating body.

As shown in FIGS. 22A and 22B, the light source module 100 may be attached to the rotating body 20 and may include a plurality of light sources 110.

Here, among the plurality of light sources 110, adjacent light sources 110 may have different forward voltages.

In this case, the difference between the forward voltage values of the light sources 110 adjacent to each other may be about 0.1V to 2V.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

Here, when the light source module 100 including the first, second, third, and fourth light sources 102, 104, 106, and 108 is attached to one side of the central axis of the rotating body 20, the first light source ( 102 may be adjacent to the central axis of the rotating body, and the fourth light source 108 may be disposed away from the central axis of the rotating body.

In this case, the first light source 102 may have a maximum forward voltage value, and the fourth light source 108 may have a minimum forward voltage value.

In some cases, the first light source 102 may have a minimum forward voltage value, and the fourth light source 108 may have a maximum forward voltage value.

For example, the first light source 102 may be a blue light emitting diode having a forward voltage of about 2.7V to 3.3V, and the second light source 103 may be a green light emitting diode having a forward voltage of about 2.4V to 2.9V. Can be.

The third light source 106 may be a yellow light emitting diode having a forward voltage of about 1.9 V to 2.4 V, and the fourth light source 108 may be a red light emitting diode having a forward voltage of about 1.7 V to 2.3 V. have.

As such, the light source module 100 mounted on the rotating body 20 may include a plurality of light sources having different forward voltage Vf values, as shown in FIG. 22A, a fourth light source having a minimum forward voltage value. 108 is driven when the speed of the rotating body 20 is maximum, and can generate colored light having a maximum wavelength band.

In addition, as illustrated in FIG. 22B, when the speed of the rotating body 20 is minimum, the first light source 102 having the maximum forward voltage value may be driven and generate color light having a minimum wavelength band.

Therefore, the embodiment can recognize the current rotational speed of the rotating body by using a plurality of light sources emitting light according to the rotating speed of the rotating body, so that the speed of the rotating body can be properly controlled.

In addition, the embodiment may use a plurality of light sources having different forward voltages to minimize power consumption.

FIG. 23 is a diagram illustrating a distance between a central axis of a rotating body and a light source of a light source module.

As shown in FIG. 23, the light source module 100 may be attached to the rotating body 20 and may include a plurality of light sources 110.

Here, among the plurality of light sources 110, adjacent light sources 110 may have different forward voltages.

In this case, the difference between the forward voltage values of the light sources 110 adjacent to each other may be about 0.1V to 2V.

For example, if the first, second, third, and fourth light sources 102, 104, 106, and 108 are arranged side by side on the substrate 120, the first, second, third, and fourth light sources ( 102, 104, 106 and 108 may be driven separately and may have different forward voltage values.

Here, when the light source module 100 including the first, second, third, and fourth light sources 102, 104, 106, and 108 is attached to one side of the central axis of the rotating body 20, the first light source ( The distance D21 between 102 and the central axis of the rotating body 20 is the distance D23 between the second light source 104 and the central axis of the rotating body 20, and the distance of the third light source 106 and the rotating body 20. It may be closer than the distance D24 between the central axis and the distance D25 between the central axis of the fourth light source 108 and the rotating body 20.

In addition, the distance D23 between the second light source 104 and the central axis of the rotating body 20 is the distance D24 between the third light source 106 and the central axis of the rotating body 20 and the fourth light source 108. And a distance D25 between the central axis of the rotating body 20 and the distance D24 between the third light source 106 and the central axis of the rotating body 20 is the fourth light source 108 and the rotating body ( 20) may be closer than the distance D25 between the central axes.

In this case, the first light source 102 may have a maximum forward voltage value, and the fourth light source 108 may have a minimum forward voltage value.

In some cases, the first light source 102 may have a minimum forward voltage value, and the fourth light source 108 may have a maximum forward voltage value.

As such, the light source module 100 mounted on the rotating body 20 may include a plurality of light sources having different forward voltage Vf values, and the light source 110 having the minimum forward voltage value may be a rotating body. When the speed of 20 is maximum, it is driven and can generate colored light having a maximum wavelength band.

In addition, the light source 110 having the maximum forward voltage value is driven when the speed of the rotor 20 is minimum, and may generate color light having a minimum wavelength band.

Therefore, the embodiment can recognize the current rotational speed of the rotating body by using a plurality of light sources emitting light according to the rotating speed of the rotating body, so that the speed of the rotating body can be properly controlled.

In addition, the embodiment may use a plurality of light sources having different forward voltages to minimize power consumption.

24 is a view showing a light source module mounted to a wheel of the vehicle.

As shown in FIG. 24, the lamp unit according to the embodiment may be applied to the wheel 600 of the vehicle 30.

Here, the wheel 600 of the vehicle 30 may include a wheel 610 and a tire 620 surrounding the circumference of the wheel 610. The light sources 110 of the light source module may include wheels 610 of the wheel 600. ) Can be mounted.

In this case, only the light sources 110 may be exposed to the outside of the wheel 610 of the light source module.

Therefore, when the wheel 610 of the vehicle 30 rotates, the light sources 110 mounted on the wheel 610 also rotate.

Subsequently, the power supply unit (not shown) of the lamp unit supplies power corresponding to the rotational speed of the wheel 610 to the light source module, and the driving unit (not shown) of the lamp unit is connected to the rotational speed of the wheel 610. According to the corresponding power, any one of the plurality of light sources 110 may be driven.

For example, when the first, second, third, and fourth light sources are disposed in the edge direction of the wheel 610 in the center axis of the wheel 610, the first light sources are disposed closest to the center axis of the wheel 610. The first light source may be a blue light emitting diode having a forward voltage of about 2.7V to 3.3V, the second light source may be a green light emitting diode having a forward voltage of about 2.4V to 2.9V, and the third light source may be about 1.9 It may be a yellow light emitting diode having a forward voltage of V to 2.4V, and the fourth light source farthest from the central axis of the wheel 610 may be a red light emitting diode having a forward voltage of about 1.7V to 2.3V.

Here, when the speed of the vehicle 30 is about 60 km / h or less, the blue light emitting diode which is the first light source is driven, and when the speed of the vehicle 30 is about 61 ~ 80 km / h, the green light emitting diode which is the second light source is When the speed of the vehicle 30 is about 81 to 110km / h, the yellow light emitting diode which is the third light source is driven. When the speed of the vehicle 30 is about 111km / h or more, the red light emitting diode which is the fourth light source is Can be driven.

As such, when the embodiment is applied to the wheel 610 of the vehicle 30, the current speed of the vehicle 30 may be externally displayed by using a plurality of light sources attached to the wheel 610 of the vehicle 30. Therefore, it is easy to control the speeding vehicle and can help the driver to drive safely.

Features, structures, effects, etc. described in the above embodiments are included in at least one embodiment of the present invention, and are not necessarily limited to only one embodiment. Furthermore, the features, structures, effects, and the like illustrated in the embodiments may be combined or modified with respect to other embodiments by those skilled in the art to which the embodiments belong. Therefore, it should be interpreted that the contents related to such a combination and modification are included in the scope of the present invention.

In addition, the above description has been made with reference to the embodiments, which are merely exemplary and are not intended to limit the present invention, and those of ordinary skill in the art may not be exemplified above within the scope not departing from the essential characteristics of the embodiments. It will be understood that various modifications and applications are possible. For example, each component specifically shown in the embodiment can be modified. And differences relating to these modifications and applications will have to be construed as being included in the scope of the invention defined in the appended claims.

100: light source module 110: light source
120: substrate 200: drive unit
300: power supply unit 400: control unit
500: sensor 600: wheel
610: wheel 620: tire

Claims (21)

A power supply unit supplying power corresponding to the rotational speed of the rotating body;
A light source module including a substrate and a plurality of light sources disposed on the substrate; And,
In accordance with the power supplied by the power supply, includes a driving unit for driving any one of the plurality of light sources,
The plurality of light sources,
A first light source and a second light source,
The first light source has a first forward voltage (Vf) value, the second light source has a second forward voltage value,
The first forward voltage value of the first light source is greater than the second forward voltage value of the second light source,
The light source module is attached to one side of the central axis of the rotating body,
The first side surface of the substrate of the light source module is adjacent to the central axis of the rotating body,
The second side facing the first side of the substrate of the light source module is disposed farther from the first side from the central axis of the rotating body,
And the thickness of the first side is thicker than the thickness of the second side. delete delete delete delete delete A power supply unit supplying power corresponding to the rotational speed of the rotating body;
A light source module including a substrate and a plurality of light sources disposed on the substrate; And,
In accordance with the power supplied by the power supply, includes a driving unit for driving any one of the plurality of light sources,
The plurality of light sources,
At least one light source array (array) in which a plurality of light sources are disposed adjacent to each other,
Among the light source arrays, the first light source array and the second light source array are each driven separately,
The forward voltage value of the light source included in the first light source array and the forward voltage value of the light source included in the second light source array are different from each other,
The light source module is attached to one side of the central axis of the rotating body,
The first side surface of the substrate of the light source module is adjacent to the central axis of the rotating body,
The second side facing the first side of the substrate of the light source module is disposed farther from the first side from the central axis of the rotating body,
And the thickness of the first side is thicker than the thickness of the second side. delete The method of claim 7, wherein the forward voltage value of the light source included in the first light source array is gradually smaller from the first light source to the last light source of the first light source array,
And a forward voltage value of a light source included in the second light source array increases gradually from a first light source to a last light source among the second light source arrays. The light source of claim 7, wherein the light sources included in the first light source array are individually driven and have different forward voltage values.
The light sources included in the second light source array are driven separately and have different forward voltage values. The light source of claim 7, wherein the light sources included in the first light source array are individually driven and have different forward voltage values.
The lamp unit of claim 2, wherein the light sources included in the second light source array are simultaneously driven and have the same forward voltage value. The light source of claim 7, wherein the light sources included in the first light source array are simultaneously driven and have the same forward voltage value.
The light sources included in the second light source array are driven separately and have different forward voltage values. The light source of claim 7, wherein the light sources included in the first light source array are simultaneously driven and have the same forward voltage value.
The lamp unit of claim 2, wherein the light sources included in the second light source array are simultaneously driven and have the same forward voltage value. delete The method of claim 7, wherein the first light source array is arranged in a first direction,
And the second light source array is disposed in a second direction perpendicular to the first direction. The power supply unit according to any one of claims 1 to 7, wherein the power supply unit,
A power generation unit converting the rotational force of the rotating body into electrical energy;
A charging unit configured to charge and convert electrical energy of the power generation unit into power; And,
And a charging control unit controlling the charging unit to supply power corresponding to the rotational speed of the rotating body to the light source module. The method of claim 16, wherein the power generation unit,
A magnetic body fixed to the rotating body and rotating according to the rotational speed of the rotating body; And
And a coil disposed on a central axis of rotation of the magnetic material to generate electricity according to the rotation of the magnetic material. delete delete delete A vehicle lamp apparatus using the lamp unit according to any one of claims 1, 7, 9, 13, and 15.

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