JP2022028169A - Image projection device and vehicle lighting equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image projection device and a lamp for a vehicle capable of suppressing the occurrence of disconnection due to erroneous connection of a flexible cable.
SOLUTION: This is an image projection device that reflects light and projects an image by a digital mirror device (102) provided with a plurality of minute mirrors, and is a mirror mounting substrate (101a) on which the digital mirror device (102) is mounted. ), A power supply mounting board (101b) formed separately from the mirror mounting board (101a), and a flexible cable (108) for electrically connecting the mirror mounting board (101a) and the power supply mounting board (101b). The flexible cable (108) is an image projection device in which wiring layers are arranged symmetrically.
[Selection diagram] Fig. 2

Description

The present invention relates to an image projection device and a vehicle lighting device, and more particularly to an image projection device and a vehicle lighting device that reflects light and projects an image by a digital mirror device including a plurality of minute mirrors.

In recent years, with the development of vehicle driving support technology and automatic driving technology, the necessity of transmitting vehicle operation schedules and information to the outside of the vehicle has been discussed. As a method of presenting information to the outside of a vehicle, a method of mounting an image projection device on a vehicle lamp and projecting an image on a road surface or the like has been proposed (see, for example, Patent Document 1). In the image projection device and vehicle lighting equipment described in Patent Document 1, a digital mirror device (DMD: Digital Mirror Device) including a plurality of minute mirrors is used to reflect light and project an image.

Japanese Unexamined Patent Publication No. 2020-055519

In the conventional image projection device, various electronic components including a digital mirror device are mounted on the circuit board, but the mounting density of the electronic components is high and it is difficult to miniaturize the device. Further, there is a problem that the ambient temperature of the digital mirror device rises due to the heat generated in each electronic component. Since the digital mirror device is a component that drives a large number of minute mirrors and reflects the light emitted from the light source unit, the usable temperature range is limited. Further, by driving the digital mirror device in a high temperature environment, there is a problem that the product life is shortened and the reliability is lowered.

In order to solve the above-mentioned problems, when electronic components are distributed and mounted on multiple circuit boards and the boards are electrically connected with flexible cables, it is necessary to supply a large current in order to drive the digital mirror device. Therefore, the problem of incorrect connection occurs as described below.

FIG. 9 is a schematic diagram showing the configuration of the flexible cable 1 for driving the digital mirror device. As shown in FIGS. 9A and 9B, the flexible cable 1 has a structure in which the ground wiring 2, the power supply wiring 3, the single-ended wiring 4, the differential wiring 5, and the like are sealed with a resin material or the like. Has and is flexible. FIG. 9A shows an example in which the ground wiring 2, the power supply wiring 3, and the differential wiring 5 are each composed of one wire, and FIG. 9B shows an example in which each of the ground wiring 2, the power supply wiring 3, and the differential wiring 5 is configured by one wire. There is. Further, since the flexible cable 1 needs to supply a large current in order to drive the digital mirror device, the ground wiring 2 and the power supply wiring 3 are formed to be thicker than the other wirings.

In the conventional flexible cable 1 shown in FIGS. 9A and 9B, the area provided for each type of wiring is determined, and the cable must be connected in the direction corresponding to the terminal of the connector to be connected. For example, in the example shown in FIGS. 9A and 9B, if the flexible cable 1 is turned upside down or turned upside down and erroneously connected to the connector, the terminal to which the ground wiring 2 and the power supply wiring 3 are normally connected is connected. The single-ended wiring 4 and the differential wiring 5 are connected.

Since the ground wiring 2 and the power supply wiring 3 of the flexible cable 1 are formed thicker than the single-ended wiring 4 and the differential wiring 5 in order to supply a large current, the relatively thin single-ended wiring 4 and the erroneously connected single-ended wiring 4 and the differential wiring 5 are formed. When a large current is supplied to the differential wiring 5, disconnection may occur due to heat generation. Further, when the flexible cable 1 is connected to the connector, it is difficult to confirm the direction of the wiring, and it is difficult to check the correctness of the connection after the assembly process.

Therefore, the present invention has been made in view of the above-mentioned conventional problems, and an object of the present invention is to provide an image projection device and a vehicle lamp capable of suppressing the occurrence of disconnection due to erroneous connection of a flexible cable.

In order to solve the above problems, the image projection device of the present invention is an image projection device that reflects light by a digital mirror device provided with a plurality of minute mirrors and projects an image, and is mounted on the digital mirror device. The mirror-mounted board is provided with a power-mounted board formed separately from the mirror-mounted board, and a flexible cable for electrically connecting the mirror-mounted board and the power-mounted board. The feature is that the wiring layers are arranged symmetrically.

In such an image projection device of the present invention, since the wiring layers of the flexible cable are arranged symmetrically, even if the top and bottom or the left and right of the flexible cable are mistakenly connected to the connector, a large current flows through the wiring layer. It is possible to secure the thickness and suppress the occurrence of disconnection due to incorrect connection.

Further, in one aspect of the present invention, the wiring layer includes a first wiring formed with a first line width and a second wiring formed with a second line width thicker than the first wiring. The second wiring is arranged symmetrically on the outermost side in the width direction of the flexible cable.

Further, in one aspect of the present invention, the second wiring has a line width more than twice that of the first wiring.

Further, in one aspect of the present invention, the first wiring includes a single-ended wiring formed with the first line width up to the end of the flexible cable and the first line width at the end of the flexible cable. Includes wider formed differential wiring.

Further, in one aspect of the present invention, the mirror mounting substrate is mounted with a mirror control unit that controls driving of the digital mirror device and a power supply unit for the mirror control unit that supplies power to the mirror control unit. A main power supply unit that supplies electric power to the power supply unit for the mirror control unit is mounted on the power supply mounting board, and the power supply unit for the mirror control unit and the main power supply unit are connected by the second wiring. There is.

Further, in one aspect of the present invention, the power supply mounting board is mounted with a mirror power supply unit that supplies electric power to the digital mirror device, and the mirror power supply unit and the digital mirror are provided by a part of the first wiring. The device is connected.

Further, in one aspect of the present invention, notches are formed rotationally symmetrically at both ends of the flexible cable.

Further, the vehicle lamp of the present invention is characterized by including the image projection device according to any one of the above and a light source unit that irradiates the image projection device with light.

INDUSTRIAL APPLICABILITY The present invention can provide an image projection device and a vehicle lamp capable of suppressing the occurrence of disconnection due to erroneous connection of a flexible cable.

It is a schematic perspective view which shows the structural example of the vehicle lamp 100 which concerns on 1st Embodiment. It is a schematic plan view which shows the structural example of the image projection apparatus 10 which concerns on 1st Embodiment. It is a block diagram which shows typically the power supply line of the image projection apparatus 10 which concerns on 1st Embodiment. FIG. 4A is a schematic diagram showing the structure of the flexible cable 108 according to the first embodiment, FIG. 4A shows a wiring example of the flexible cable 108, and FIG. 4B shows an erroneous fitting with the connector portion 116. Indicates the connection status. FIG. 5A is a schematic diagram showing the structure of the flexible cable 108 according to the second embodiment, FIG. 5A shows an example in which the power supply wiring 108a is formed with the same width as the ground wiring 108e, and FIG. Is shown with the same width as the single-ended wiring 108b. FIG. 6A is a schematic view showing the structure of the flexible cable 108 according to the third embodiment, FIG. 6A shows an example in which the power supply wiring 108a is arranged symmetrically, and FIG. 6B shows the power supply wiring 108a in the width direction. An example of arranging them in a biased manner to one side is shown. It is a top view which shows the structure of the flexible cable 108 which concerns on 4th Embodiment. It is a schematic diagram which shows the connection between the flexible cable 108 and the connector part 116a, 116b which concerns on 4th Embodiment. It is a schematic diagram which shows the structure of the flexible cable 1 for driving a digital mirror device.

(First Embodiment)
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The same or equivalent components, members, and processes shown in the drawings shall be designated by the same reference numerals, and duplicate description thereof will be omitted as appropriate. FIG. 1 is a schematic perspective view showing a configuration example of a vehicle lamp 100 according to the present embodiment. As shown in FIG. 1, the vehicle lamp 100 includes an image projection device 10, a light source unit 20, a reflector 30, a projection lens 40, and a heat sink 50, and projects an image onto a projection surface 60.

The image projection device 10 controls the reflection direction of light in the plane based on the on information and the off information included in the information of the image to be projected, and emits the light emitted from the light source unit 20 into the projected light Lon and the shielding light Loff. It is a device that reflects as. The projected light Lon is irradiated to the projection surface 60 via the projection lens 40, and the image is projected by irradiating the region corresponding to the on information with the light. The shielding light Loff reaches a shielding portion (not shown) and is blocked, and is not irradiated to the outside.

The light source unit 20 is a device that irradiates the reflector 30 with light based on an electric power and a signal supplied from the outside. Emission of Radiation) can be used. The light emitted from the light source unit 20 may be continuous light (CW: Continuous Wave), pulsed light, or PWM (Pulse Width Modulation) controlled light.

The reflector 30 is an optical member that reflects the light emitted from the light source unit 20 to the image projection device 10. The shape of the reflective surface of the reflector 30 is not limited, and a curved surface such as a paraboloid or an elliptic curved surface can be used. The light reflected by the reflector 30 may have an enlarged light diameter toward the image projection device 10, or may be parallel light.

The projection lens 40 is an optical member arranged on the optical path of the projected light Lon reflected by the image projection device 10, and magnifies the projected light Lon and irradiates the projection surface 60 with the projected light Lon. Although FIG. 1 shows an example in which one lens is used as the projection lens 40, a plurality of lenses may be provided. Further, although an example of a convex lens is shown in FIG. 1, a known lens structure such as a concave lens or an aspherical lens can be used.

The heat sink 50 is a member on which the light source unit 20 is mounted and arranged to improve heat dissipation. The material constituting the heat sink 50 is not limited, but for example, copper or aluminum having a high thermal conductivity, a highly thermally conductive resin, or the like can be used. Further, the structure and shape of the heat sink 50 are not limited, but if a plurality of fins are erected on the rear surface side, the heat dissipation can be further improved.

The projection surface 60 is provided outside the vehicle lamp 100, and is a surface on which the projected light Lon is irradiated and an image is projected. Examples of the projection surface 60 include a road surface, a wall surface of a structure, a vehicle body of another vehicle, a vehicle body of a own vehicle, and the like. In FIG. 1, a plane is shown as the projection surface 60, but it may be a surface having a curved surface or unevenness as long as the image can be projected and displayed by being irradiated with the projected light Lon.

FIG. 2 is a schematic plan view showing a configuration example of the image projection device 10 according to the present embodiment. As shown in FIG. 2, the image projection device 10 includes a mirror mounting substrate 101a, a power supply mounting substrate 101b, a digital mirror device 102, a temperature sensor unit 103, a mirror control unit 104, a flash memory 105, and a mirror control unit. Power supply unit 106, voltage monitoring unit 107, flexible cable 108, mirror power supply unit 109, control microcomputer 110, voltage adjustment unit 111, microcomputer power supply unit 112, deserializer 113, cooling power supply unit. It includes 114 and a connector portion 115.

The mirror mounting board 101a and the power supply mounting board 101b are circuit boards on which electronic components formed separately are mounted. A wiring pattern (not shown) is formed on the surface of the circuit board, and the electronic components mounted on the surface are electrically connected to each other. It is a member that is connected to each other to form a circuit. Although FIG. 2 shows an example in which the electronic component is mounted only on the front surface side, a wiring pattern may be formed on the back surface side as well and the electronic component may be mounted. The materials constituting the mirror mounting board 101a and the power supply mounting board 101b are not limited, and a known printed wiring board or the like can be used. In order to improve the heat dissipation of the mirror mounting substrate 101a and the power supply mounting substrate 101b, a composite substrate in which an insulating layer and a wiring pattern are formed on a substrate made of a high thermal conductive material such as metal or ceramic may be used. Further, the mirror mounting substrate 101a and the power supply mounting substrate 101b may be formed of the same material or the same structure, or may be formed of different materials or structures.

As shown in FIG. 2, a digital mirror device 102, a temperature sensor unit 103, a mirror control unit 104, a flash memory 105, a power supply unit 106 for the mirror control unit, and a voltage monitoring unit 107 are mounted on the mirror mounting substrate 101a. ing. Further, on the power supply mounting board 101b, a mirror power supply unit 109, a control microcomputer 110, a voltage adjustment unit 111, a microcomputer power supply unit 112, a deserializer 113, a cooling power supply unit 114, and a connector unit 115 are mounted.

The digital mirror device 102 is an electronic component in which minute mirrors 11 are arranged in a matrix and the tilt angle can be changed between an on state and an off state. Of the mirror 11, the projected light Lon reflected in the on state and the shielding light Loff reflected in the off state are separated, and an image is projected by irradiating the projected light Lon.

The temperature sensor unit 103 is an electronic component that is arranged in the vicinity of the digital mirror device 102 and measures the temperature of the digital mirror device. The temperature measured by the temperature sensor unit 103 is transmitted as temperature information to the mirror control unit 104 and the control microcomputer 110. The specific configuration of the temperature sensor unit 103 is not limited, and a thermistor, a thermocouple, a digital temperature sensor, or the like can be used.

The mirror control unit 104 is an electronic component that transmits a control signal to the digital mirror device 102 based on the on information and the off information included in the image, and switches and controls the on state and the off state of the mirror 11. Further, the mirror control unit 104 is connected to the control microcomputer 110 via a flexible cable 108, and the drive is controlled by a control signal from the control microcomputer 110. Since the mirror control unit 104 and the digital mirror device 102 need to operate at a high speed to the extent necessary for image rendering (for example, 600 MHz or more), they are arranged close to each other on the mirror mounting substrate 101a.

The flash memory 105 is a storage unit for holding information necessary for driving the mirror control unit 104. Examples of the information stored in the flash memory 105 include a program executed by the mirror control unit 104, various setting information, image data, and the like.

The mirror control unit power supply unit 106 is a power supply circuit in which power is supplied from the mirror power supply unit 109 via the flexible cable 108 and power is supplied to the mirror control unit 104. A relatively large voltage is supplied from the mirror power supply unit 109 to the mirror control unit power supply unit 106 via the flexible cable 108, but the mirror control unit power supply unit 106 uses a plurality of DC / DC converters. , The voltage is stepped down to a voltage suitable for driving the mirror control unit 104, and the power is output. As an example of voltage conversion of the power supply unit 106 for the mirror control unit, for example, DC6V is supplied and DC3.3V, 1.8V, 1.1V and the like are output.

The voltage monitoring unit 107 is an electronic component that monitors the mirror drive voltage supplied from the mirror power supply unit 109 to the digital mirror device via the flexible cable 108. Further, the voltage monitoring unit 107 is electrically connected to the mirror control unit 104 and the control microcomputer 110, and transmits the measured value of the monitored voltage. As an example, when the voltage on the mirror mounting substrate 101a supplied from the flexible cable 108 is lower than a predetermined value, the mirror control unit 104 stops the operation of the digital mirror device 102. As a result, it is possible to detect a disconnection or connection failure of the flexible cable 108, a failure of the mirror power supply unit 109, or the like, and prevent a malfunction of the digital mirror device 102.

The flexible cable 108 is a wiring cable in which a plurality of wirings are collectively protected by a flexible resin or the like, and electrically connects between the mirror mounting substrate 101a and the power supply mounting substrate 101b. The connection method between the flexible cable 108, the mirror mounting board 101a, and the power supply mounting board 101b is not particularly limited, and a form of inserting into a connector mounted on both boards can be used. Since the flexible cable 108 has flexibility, it is possible to secure mutual electrical connection regardless of the arrangement of both substrates by bending it.

The mirror power supply unit 109 is supplied with power from the outside of the image projection device 10 via the connector unit 115, and supplies power to the digital mirror device 102 and the mirror control unit power supply unit 106 via the flexible cable 108. It is a power supply circuit. The mirror power supply unit 109 is composed of a plurality of electronic components, and includes a series regulator and a DC / DC converter. Examples of the output of the mirror power supply unit 109 include DC16V, 8.5V, 6V, -10V and the like.

The control microcomputer 110 is an electronic component that controls the drive of the entire image projection device 10 based on control signals and various measured values. The control microcomputer 110 is capable of information communication with the outside via the connector unit 115, and image information and control signals are supplied from the outside. Further, the measured values of the mirror control unit 104, the temperature sensor unit 103, and the voltage monitoring unit 107 are transmitted to the control microcomputer 110.

When the image information is transmitted from the outside, the control microcomputer 110 transmits the image information to the mirror control unit 104 via the flexible cable 108, and controls the on state and the off state of the minute mirror. Further, the control microcomputer 110 controls the drive of a cooling unit (not shown) based on the temperature information from the temperature sensor unit 103 to control the temperature of the digital mirror device 102. Here, as the cooling unit, known ones such as a cooling fan, a liquid cooling device, and a Pelche element can be used. Further, the control microcomputer 110 controls the drive of the image projection device 10 based on the measured value of the voltage monitoring unit 107. For example, when the signal from the voltage monitoring unit 107 is interrupted, the flexible cable 108 is disconnected or dropped. The output from the mirror power supply unit 109 is stopped.

Here, the control microcomputer 110 controls the cooling power supply unit 114 and the cooling unit by executing a program recorded in advance, and also constitutes the cooling control unit in the present invention to cool the image projection device 10. .. Here, an example in which a part of the functions of the control microcomputer 110 functions as a cooling control unit is shown, but a dedicated electronic component may be mounted on the power supply mounting board 101b to function as the cooling control unit.

The voltage adjusting unit 111 is a circuit composed of a series regulator and a DC / DC converter and used in combination with the mirror power supply unit 109 to adjust the voltage. As an example of voltage conversion of the voltage adjusting unit 111, for example, DC6V is supplied and DC3.3V or the like is output.

The microcomputer power supply unit 112 is a power supply circuit in which electric power is supplied from the outside of the image projection device 10 via the connector unit 115 to supply electric power to the control microcomputer 110. The power supply unit 112 for a microcomputer is composed of a series regulator, and examples of outputs include DC 3.3V, 5V, and the like.

The deserializer 113 is an electronic component that receives image information as serial data from the outside via the connector unit 115, converts the serial data into parallel data, and transmits the serial data to the mirror control unit 104.

The cooling power supply unit 114 is a power supply circuit in which electric power is supplied from the outside of the image projection device 10 via the connector unit 115 and power is supplied to the cooling unit (not shown). The cooling power supply unit 114 is composed of a series regulator, and examples of the output include DC5V and the like.

The connector portion 115 is an electronic component that secures an electrical connection with the outside of the image projection device 10 by inserting a cable or the like. Power is supplied to the image projection device 10 from the outside via the connector unit 115 to the mirror power supply unit 109, the microcomputer power supply unit 112, and the cooling power supply unit 114. Further, control signals and information are transmitted between the outside and the control microcomputer 110 via the connector unit 115.

As shown in FIG. 2, in the image projection device 10 of the present embodiment, the mirror mounting substrate 101a and the power supply mounting substrate 101b are electrically connected by a flexible cable 108, and power and control signals are connected between the two. Is said to be communicable. However, since the flexible cable 108 has a structure in which the electric wiring is covered with a flexible resin and has low thermal conductivity, the thermal conduction between the mirror mounting substrate 101a and the power supply mounting substrate 101b is suppressed. There is. As a result, the heat generated from the electronic components mounted on the power supply mounting board 101b is prevented from being transmitted to the mirror mounting board 101a side, and the temperature rise of the digital mirror device 102 can be suppressed.

Further, since the mirror mounting board 101a and the power supply mounting board 101b are formed separately, the electronic components having a relatively small heat generation amount are mounted on the mirror mounting board 101a, and the electronic components having a relatively large heat generation amount are mounted on the power supply mounting board. By mounting it on the 101b, it is possible to suppress the temperature rise of the digital mirror device 102 without increasing the size of the circuit board, and it is possible to reduce the size and weight.

Here, as an electronic component having a relatively small heat generation amount, a power supply unit 106 for a mirror control unit can be mentioned. As described above, the power supply unit 106 for the mirror control unit is composed of a DC / DC converter and has a high conversion efficiency, so that the amount of heat generated is small. Further, the DC / DC converter has the characteristics of having a large current capacity and good response performance to load (current) fluctuations, but on the other hand, the number of parts constituting the circuit is large and the mounting area is large. However, in the image projection device 10 of the present embodiment, by mounting the electronic components on the power supply mounting board 101b, it is easy to secure an area on the mirror mounting board 101a for arranging the power supply unit 106 for the mirror control unit. be.

Examples of the electronic component having a relatively large amount of heat generation include a mirror power supply unit 109, a voltage adjustment unit 111, a microcomputer power supply unit 112, and a cooling power supply unit 114. As described above, the mirror power supply unit 109, the voltage adjustment unit 111, the microcomputer power supply unit 112, and the cooling power supply unit 114 include a series regulator, and the conversion efficiency is low, so that the amount of heat generated is large. The series regulator has a characteristic that the current capacity is small and the response performance to load (current) fluctuation is lower than that of the DC / DC converter, but the mounting area is small because it can be configured with one chip. In the image projection device 10 of the present embodiment, the temperature rise of the digital mirror device 102 can be suppressed by mounting the series regulator on the power supply mounting board 101b different from the mirror mounting board 101a. Further, by mounting a series regulator that can be configured with one chip on the power supply mounting board 101b, the mounting density of electronic components on the power supply mounting board 101b can be reduced, and the temperature rise on the power supply mounting board 101b can be suppressed. can.

As another electronic component, the mirror control unit 104 needs to have a short wiring for high-speed operation similar to that of the digital mirror device 102, and is mounted on the mirror mounting substrate 101a in close proximity to the digital mirror device 102. .. Further, the temperature sensor unit 103 is mounted on the mirror mounting substrate 101a in close proximity to the digital mirror device 102 in order to measure the temperature of the digital mirror device 102. Further, since the flash memory 105 needs to transmit information such as image information and programs to and from the mirror control unit 104, the flash memory 105 is mounted on the mirror mounting substrate 101a in close proximity to the mirror control unit 104. Further, since the voltage monitoring unit 107 is for detecting an abnormality in the voltage supplied to the mirror mounting board 101a, it is mounted on the mirror mounting board 101a.

Since the control microcomputer 110 does not need to be operated at a high speed as the digital mirror device 102, it is necessary to perform information communication with the outside via the connector portion 115 and to continue the operation even if a defect occurs in the flexible cable 108. It is mounted on the power supply mounting board 101b. The deserializer 113 is mounted on the power supply mounting board 101b in order to convert the serial data transmitted via the connector unit 115 into parallel data and transmit the serial data to the control microcomputer 110.

FIG. 3 is a block diagram schematically showing a power supply line of the image projection device 10 according to the present embodiment. The electric power supplied from the outside through the connector unit 115 is transmitted to the mirror power supply unit 109, the microcomputer power supply unit 112, and the cooling power supply unit 114, respectively. Examples of the electric power supplied from the outside include DC12V supplied from an in-vehicle battery. In the example shown in FIG. 3, the power supply unit 112 for a microcomputer includes two series regulators, and outputs 3.3V for driving the control microcomputer 110 and 5V for driving the interface unit, respectively. The interface unit converts the control signal transmitted from the control microcomputer 110 to the LED driver into a voltage level. This control signal is transmitted to the LED driver via the connector 115 of the power supply mounting board 101b. The LED driver has a function of controlling the voltage and current to the light source unit 20 to predetermined values and lighting the light source unit 20. The cooling power supply unit 114 includes one series regulator, and outputs 5V for driving a cooling fan or the like which is a cooling unit.

The mirror power supply unit 109 includes two DC / DC converters 109a and 109b and an auxiliary power supply unit 109c including a series regulator and a DC / DC converter, and the voltage adjusting unit 111 adjusts a part of the voltage of the output. .. The mirror power supply unit 109 boosts 12V supplied from the outside to 20V by the first-stage DC / DC converter 109a, steps down to 6V by the second-stage DC / DC converter 109b, and outputs the step. Part of the output from the second-stage DC / DC converter 109b is supplied to the mirror control unit power supply unit 106 via the flexible cable 108, and partly with the auxiliary power supply unit 109c included in the mirror power supply unit 109. It is supplied to the voltage adjusting unit 111.

Of the mirror power supply units 109, the DC / DC converters 109a and 109b that supply a relatively large current to the mirror control unit power supply unit 106 correspond to the main power supply unit in the present invention. Further, the auxiliary power supply unit 109c of the mirror power supply unit 109 supplies a relatively small current to the digital mirror device 102.

The voltage adjusting unit 111 is composed of a series regulator, converts 6V to 3.3V, and supplies it to the auxiliary power supply unit 109c. The auxiliary power supply unit 109c generates 16V, 8.5V, 6V, -10V from the supplied 6V and 3.3V and supplies them to the digital mirror device 102 via the flexible cable 108.

The power supply unit 106 for the mirror control unit includes three DC / DC converters, and converts 6V supplied via the flexible cable 108 into 1.1V, 1.8V, and 3.3V, respectively, to convert the 6V to 1.1V, 1.8V, and 3.3V, respectively. Supply to 104. The output of 1.8V is also supplied to the digital mirror device 102.

4A and 4B are schematic views showing the structure of the flexible cable 108 according to the present embodiment, FIG. 4A shows a wiring example of the flexible cable 108, and FIG. 4B can be fitted with the connector portion 116. Indicates an incorrect connection status. As shown in FIG. 4A, the flexible cable 108 includes a power supply wiring 108a, a single-ended wiring 108b, a differential wiring 108c, a single-ended wiring 108d, and a ground wiring 108e. Each wiring is formed by extending in the longitudinal direction of the flexible cable 108, and is formed at equal intervals in the width direction. In the example shown in FIG. 4A, the single-ended wiring 108b, 108d and the differential wiring 108c are formed with a narrow line width (first line width), which corresponds to the first wiring in the present invention. .. In FIG. 4A, the differential wiring 108c is shown with diagonal lines, but the two wirings form a set of wirings. Further, the power supply wiring 108a and the grounding wiring 108e are formed with a line width (second line width) thicker than that of the first wiring, and correspond to the second wiring in the present invention.

The power supply wiring 108a is a wiring formed at one end of the flexible cable 108 in the width direction, and is a wiring for electrically connecting the power supply unit 106 for the mirror control unit and the DC / DC converter 109b. Since it is necessary to supply a relatively large current from the DC / DC converter 109b to the power supply unit 106 for the mirror control unit, the line width of the power supply wiring 108a is larger than that of the single-ended wiring 108b, 108d and the differential wiring 108c. It is thickly formed. Specifically, when the single-ended wiring 108b, 108d and the differential wiring 108c are formed with the first line width, the power supply wiring 108a has a second line width that is at least twice the first line width. It is formed. Thereby, for example, even when the allowable current of the single-ended wiring 108b, 108d and the differential wiring 108c is 100 to 200 mA, the allowable current of the power supply wiring 108a can be set to 1 A or more.

The single-ended wirings 108b and 108d are formed with a line width (first line width) narrower than that of the power supply wiring 108a, and are wirings for transmitting an electric signal between the mirror mounting board 101a and the power supply mounting board 101b. .. Further, the single-ended wirings 108b and 108d are formed with a first line width up to both ends of the flexible cable 108.

The differential wiring 108c is formed in the center of the flexible cable 108 in the width direction with a line width (first line width) narrower than that of the power supply wiring 108a, and is formed between the mirror mounting substrate 101a and the power supply mounting substrate 101b. It is a wiring that transmits an electric signal. Further, the differential wiring 108c is designed so that the characteristic impedance is different from that of the single-ended wirings 108b and 108d. As an example, the characteristic impedance of the single-ended wiring 108b and 108d is 50Ω, and the characteristic impedance of the differential wiring 108c is 100Ω.

The ground wiring 108e is a wiring formed at the other end of the flexible cable 108 in the width direction, and is a wiring connecting the ground potentials of the mirror mounting board 101a and the power supply mounting board 101b. Since it is necessary to supply a relatively large current from the DC / DC converter 109b to the power supply unit 106 for the mirror control unit between the mirror mounting board 101a and the power supply mounting board 101b, the line width of the ground wiring 108e is It is formed with the same line width as the power supply wiring 108a. Thereby, for example, even when the allowable current of the single-ended wiring 108b, 108d and the differential wiring 108c is 100 to 200 mA, the allowable current of the grounded wiring 108e can be set to 1 A or more.

As shown in FIG. 4A, each wiring of the flexible cable 108 is arranged so that the thickness of the wiring layer is symmetrical. In particular, the power supply wiring 108a and the ground wiring 108e have a wider line width than the single-ended wiring 108b, 108d and the differential wiring 108c due to the large current flowing, and are arranged symmetrically on the outermost side in the width direction of the flexible cable 108. ing. As a result, even if the top and bottom or left and right of the flexible cable 108 are mistakenly connected to the connector, the thickness of the power supply wiring 108a and the grounding wiring 108e through which a large current flows is secured, and a large current flows through the thin wiring due to the incorrect connection. It is possible to suppress the occurrence of disconnection.

Further, as shown in FIG. 4B, in an erroneously connected state in which the flexible cable 108 cannot be accurately fitted to the connector portion 116, the power supply wiring 108a or the ground wiring 108e provided at both ends in the width direction is connected to the connector portion. The electrical connection with the terminal part of 116 cannot be secured. Therefore, power is not supplied to the electronic components mounted on the mirror mounting substrate 101a, and damage to the electronic components due to erroneous connection of the flexible cable 108 can be suppressed.

As described above, in the image projection device 10 of the present embodiment, since the wiring layers of the flexible cable 108 are arranged symmetrically, even when the top and bottom or the left and right of the flexible cable 108 are mistakenly connected to the connector portion 116. It is possible to secure the thickness of the wiring layer through which a large current flows and suppress the occurrence of disconnection due to erroneous connection.

Further, since the mirror mounting board 101a and the power supply mounting board 101b are electrically connected by the flexible cable 108 and the mirror power supply unit 109 is mounted on the power supply mounting board 101b, the mirror power supply unit 109 tends to generate heat. It is possible to prevent the generated heat from being transferred to the digital mirror device 102, and it is possible to reduce the size and weight of the digital mirror device 102 while suppressing the temperature rise.

Further, the mirror mounting substrate 101a is equipped with a voltage monitoring unit 107 that monitors the mirror drive voltage supplied to the digital mirror device 102, so that when a problem such as disconnection or disconnection occurs in the flexible cable 108, the flexible cable 108 is broken or dropped. Can stop driving the digital mirror device 102 to prevent a failure.

(Second Embodiment)
Next, the second embodiment of the present invention will be described with reference to FIG. The description of the contents overlapping with the first embodiment will be omitted. 5A and 5B are schematic views showing the structure of the flexible cable 108 according to the present embodiment, FIG. 5A shows an example in which the power supply wiring 108a is formed with the same width as the ground wiring 108e, and FIG. 5B shows an example. An example in which the power supply wiring 108a is formed with the same width as the single-ended wiring 108b is shown.

In the example shown in FIG. 5A, ground wiring 108e is provided at both ends in the width direction of the flexible cable 108, and a plurality of power supply wirings 108a are provided adjacent to the inside of the ground wiring 108e. Further, the single-ended wirings 108b and 108d are provided between the power supply wiring 108a and the differential wiring 108c. Further, in the width direction of the flexible cable 108, a plurality of differential wirings 108c are provided in the central region. Further, the single-ended wiring 108b, 108d and the differential wiring 108c are formed by the first line width, and the power supply wiring 108a and the ground wiring 108e are formed by the second line width.

In the example shown in FIG. 5A, the amount of current that can be supplied by the entire power supply wiring 108a can be further increased by configuring the power supply wiring 108a with a plurality of wires. A sub power supply unit 109c of the mirror power supply unit 109 and a digital mirror device 102 are connected to a part of the power supply wiring 108a, and DC / DC converters 109a and 109b of the mirror power supply unit 109 are connected to the remaining power supply wiring 108a. .. FIG. 5A shows an example in which one ground wire 108e is provided at both ends in the width direction, but a plurality of ground wires 108e may be provided at both ends, and a total of four or more ground wires 108e may be provided.

Even in the example shown in FIG. 5B, the arrangement of the power supply wiring 108a, the single-ended wiring 108b, 108d, the differential wiring 108c, and the ground wiring 108e is the same as the example shown in FIG. 5A. However, the power supply wiring 108a, the single-ended wiring 108b, 108d, and the differential wiring 108c are formed by the first line width, and the ground wiring 108e is formed by the second line width. Also in the example shown in FIG. 5B, the amount of current that can be supplied by the entire power supply wiring 108a can be increased by configuring the power supply wiring 108a with a plurality of wires.

As described above, also in the image projection device 10 of the present embodiment, each wiring of the flexible cable 108 is arranged so that the thickness of the wiring layer is symmetrical. As a result, even if the top and bottom or left and right of the flexible cable 108 are mistakenly connected to the connector, the thickness of the power supply wiring 108a and the grounding wiring 108e through which a large current flows is secured, and a large current flows through the thin wiring due to the incorrect connection. It is possible to suppress the occurrence of disconnection.

(Third Embodiment)
Next, the third embodiment of the present invention will be described with reference to FIG. The description of the contents overlapping with the first embodiment will be omitted. 6A and 6B are schematic views showing the structure of the flexible cable 108 according to the present embodiment, FIG. 6A shows an example in which the power supply wiring 108a is arranged symmetrically, and FIG. 6B shows the power supply wiring 108a. An example in which the arrangement is biased to one side in the width direction is shown. The present embodiment is different from the first embodiment and the second embodiment in that the differential wiring 108c is not provided.

In the example shown in FIG. 6A, ground wiring 108e is provided at both ends in the width direction of the flexible cable 108, and a plurality of power supply wirings 108a are provided adjacent to the inside of the ground wiring 108e. Further, a single-ended wiring 108b is provided inside the power supply wiring 108a. Further, the power supply wiring 108a and the single-ended wiring 108b are formed by the first line width, and the ground wiring 108e is formed by the second line width.

In the example shown in FIG. 6B, ground wiring 108e is provided at both ends in the width direction of the flexible cable 108, and a plurality of power supply wiring 108a and a single-ended wiring 108b are provided adjacent to the inside of the ground wiring 108e. Has been done. Further, the power supply wiring 108a and the single-ended wiring 108b are formed by the first line width, and the ground wiring 108e is formed by the second line width.

Also in the example shown in FIGS. 6A and 6B, the amount of current that can be supplied by the entire power supply wiring 108a can be increased by configuring the power supply wiring 108a with a plurality of wires. Further, since the power supply wiring 108a and the single-ended wiring 108b are formed with the same first line width, the allowable current and the characteristic impedance are the same. Therefore, even if the top, bottom, left, or right of the flexible cable 108 is mistakenly connected to the connector, the thickness of the power supply wiring 108a and the grounding wiring 108e through which a large current flows is secured, and a large current flows through the thin wiring due to the incorrect connection. It is possible to suppress the occurrence of disconnection. Further, since the characteristic impedance of each wiring is also symmetrical, it is possible to prevent deterioration of signal transmission characteristics due to incorrect connection.

(Fourth Embodiment)
Next, the fourth embodiment of the present invention will be described with reference to FIGS. 7 and 8. The description of the contents overlapping with the first embodiment will be omitted. FIG. 7 is a plan view showing the structure of the flexible cable 108 according to the present embodiment. The flexible cable 108 of the present embodiment includes power supply wiring 108a, single-ended wiring 108b, 108d, and grounding wiring 108e, and notches 108f are formed at both ends thereof.

As shown in FIG. 7, in the width direction of the flexible cable 108, ground wiring 108e is provided at both ends, and a plurality of power supply wirings 108a are provided adjacent to the inside of the ground wiring 108e. Further, the single-ended wirings 108b and 108d are provided between the power supply wiring 108a and the differential wiring 108c. The power supply wiring 108a, the single-ended wiring 108b, 108d, and the grounding wiring 108e have terminal portions formed at both ends of the flexible cable 108, respectively, and the terminal portions are formed with the same line width in all the wirings at the same intervals. Have been placed.

In the present embodiment, the single-ended wirings 108b and 108d are formed with the first line width in the longitudinal direction of the flexible cable 108 except for the terminal portion. The power supply wiring 108a is formed with a second line width wider than the first line width, and includes two terminal portions at both ends. That is, the power supply wiring 108a is widened by connecting between two adjacent single-ended wirings 108b and 108d. The ground wiring 108e is formed with a third line width that is wider than the second line width.

Here, as a specific setting example of each wiring, the width of the terminal portion is 0.35 mm, the pitch is 0.5 mm, and the line widths (first line widths) of the single-ended wirings 108b and 108d are 0.25 to 0.25. Examples thereof include 0.35 mm, a line width (second line width) of the power supply wiring 108a of 0.75 to 0.85 mm, and a line width of the grounded wiring 108e (third line width) of 3.5 mm.

The cutout portion 108f is a portion formed by notching a rotationally symmetric position at both ends of the flexible cable 108, and the terminal portion, the wiring, and the terminal portion constituting the flexible cable 108 are removed. Further, the notch 108f is formed at a position other than the center in the width direction of the flexible cable 108. As shown in FIG. 7, the cutout portion 108f has a width corresponding to a plurality of terminal portions and is cut out along the longitudinal direction of the flexible cable 108. Examples of the width of the notch 108f include 2.0 mm.

FIG. 8 is a schematic view showing the connection between the flexible cable 108 and the connector portions 116a and 116b according to the present embodiment. As shown in FIG. 8A, the mirror mounting board 101a is mounted with the connector portion 116a, and the power supply mounting board 101b is mounted with the connector portion 116b. Further, the connector portions 116a and 116b are provided with positioning ribs 117a and 117b at positions corresponding to the notch portions 108f.

The connector portions 116a and 116b are components for electrically connecting the wiring formed on the mirror mounting substrate 101a and the power supply mounting substrate 101b and the flexible cable 108, respectively, and the terminal portion of the flexible cable 108 is inserted. Ru.

The positioning ribs 117a and 117b are wall-shaped portions formed in the connector portions 116a and 116b along the depth direction, and the front end thereof is exposed from the structure arranged in the openings of the connector portions 116a and 116b or the openings. It has a structure to be used. Further, the positioning ribs 117a and 117b are formed at positions corresponding to the notch 108f of the flexible cable 108 to be inserted, and have a depth and width slightly smaller than those of the notch 108f.

FIG. 8B schematically shows a state before the flexible cable 108 is inserted into the connector portions 116a and 116b, and FIG. 8C schematically shows a state in which the flexible cable 108 is inserted into the connector portions 116a and 116b. Shows. As shown in FIGS. 8B and 8C, since the positioning ribs 117a and 117b are formed at positions corresponding to the notch 108f, the terminal portion of the flexible cable 108 is inserted into the connector portions 116a and 116b. Accurate positioning can be performed by just using. Positioning can be performed more easily when exposed from the opening of the rib.

Further, since the cutout portion 108f is provided at a position other than the center in rotational symmetry, if the flexible cable 108 is mistakenly inserted into the connector portions 116a and 116b on the front and back surfaces, the positioning ribs 117a and 117b become the flexible cable 108. have a finger in the pie. This makes it possible to prevent erroneous connection between the front and back surfaces of the flexible cable 108. Further, since the positions of the positioning ribs 117a and 117b and the notch 108f are different from each other, it can be easily visually recognized at the stage before insertion. Therefore, the wrong flexible cable 108 is forcibly pushed into the connector portions 116a and 116ba to damage the flexible cable 108. Can be prevented from doing so.

Further, since the wiring of the flexible cable 108 is formed in rotational symmetry as shown in the first to third embodiments, power supply and signal transmission can be performed regardless of which end of the flexible cable 108 is inserted. It can be performed.

The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the embodiments obtained by appropriately combining the technical means disclosed in the different embodiments. Is also included in the technical scope of the present invention.

100 ... Vehicle lighting equipment 10 ... Image projection device 20 ... Light source unit 30 ... Reflector 40 ... Projection lens 50 ... Heat sink 101a ... Mirror mounting board 101b ... Power supply mounting board 102 ... Digital mirror device 103 ... Temperature sensor unit 104 ... Mirror control unit 105 ... Flash memory 106 ... Power supply unit 107 for mirror control unit ... Voltage monitoring unit 108 ... Flexible cable 108a ... Power supply wiring 108b, 108d ... Single-ended wiring 108c ... Differential wiring 108e ... Grounding wiring 108f ... Notch 109 ... Power supply unit for mirror 109a, 109b ... DC / DC converter 109c ... Auxiliary power supply unit 110 ... Control microcomputer 111 ... Voltage adjustment unit 112 ... Microcomputer power supply unit 113 ... Deserializer 114 ... Cooling power supply unit 115, 116a, 116b ... Connector unit 117a, 117b ... Positioning rib

Claims (8)

An image projection device that reflects light and projects an image with a digital mirror device equipped with multiple minute mirrors.
The mirror mounting board on which the digital mirror device is mounted and the
A power supply mounting board formed separately from the mirror mounting board,
A flexible cable for electrically connecting the mirror mounting board and the power supply mounting board is provided.
The flexible cable is an image projection device characterized in that wiring layers are arranged symmetrically. The image projection device according to claim 1.
The wiring layer includes a first wiring formed with a first line width and a second wiring formed with a second line width thicker than the first wiring.
The image projection device is characterized in that the second wiring is symmetrically arranged on the outermost side in the width direction of the flexible cable. The image projection device according to claim 2.
The second wiring is an image projection device having a line width more than twice that of the first wiring. The image projection device according to claim 2 or 3.
The first wiring includes a single-ended wiring formed up to the end of the flexible cable with the first line width and a differential wiring formed at the end of the flexible cable wider than the first line width. An image projection device characterized by including. The image projection device according to any one of claims 2 to 4.
On the mirror mounting board, a mirror control unit that controls the drive of the digital mirror device and a power supply unit for the mirror control unit that supplies electric power to the mirror control unit are mounted.
A main power supply unit that supplies electric power to the power supply unit for the mirror control unit is mounted on the power supply mounting board.
An image projection device characterized in that the power supply unit for the mirror control unit and the main power supply unit are connected by the second wiring. The image projection device according to any one of claims 2 to 5.
A mirror power supply unit that supplies power to the digital mirror device is mounted on the power supply mounting board.
An image projection device characterized in that the mirror power supply unit and the digital mirror device are connected by a part of the first wiring. The image projection device according to any one of claims 1 to 6.
An image projection device characterized in that notches are formed rotationally symmetrically at both ends of the flexible cable. The image projection device according to any one of claims 1 to 7.
A vehicle lamp provided with a light source unit that irradiates the image projection device with light.

Images