JP2017105246A - Head-up display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a head-up display device capable of displaying an information notification image in a virtual image in a manner securely making an occupant notice the image.SOLUTION: A head-up display device 100 is mounted in a vehicle A, and displays a virtual image 60 visible to a driver D regarded as an occupant. The head-up display device 100 comprises: a display unit 40 projecting beams of an image 70 to form the virtual image 60; a combiner unit 20 having a plurality of projection plane parts 30; and a rotation mechanism 90. The projection plane parts 30 magnify the images 70 to be projected, and display them as the virtual images 60. The respective projection plane parts 30 have mutually different magnifications. The rotation mechanism 90 can change the projection plane part 30 arranged within a projection area PA1 onto which the beams are projected from the display unit 40, by displacing the combiner 20.SELECTED DRAWING: Figure 2

Description

  The disclosure according to this specification relates to a head-up display device that displays a virtual image that can be visually recognized by an occupant of a moving object.

  Conventionally, for example, Patent Document 1 discloses a head-up display device for vehicles (hereinafter referred to as a HUD device) including a combiner on which light of an image emitted from a display is projected. In this HUD device, in order to facilitate the positioning operation of the combiner, a horizontal position adjustment mechanism that enables adjustment of the position of the combiner in the horizontal direction of the vehicle, and a vertical position that enables adjustment of the position of the combiner in the vertical direction of the vehicle. A directional position adjusting mechanism is provided.

JP-A-9-66757

  Nowadays, HUD devices have been required to notify a wide variety of information to a passenger by virtual image display. Here, in the HUD device of Patent Document 1, even if the position of the combiner is adjusted by the horizontal and vertical position adjustment mechanisms, the imaging position and size of the virtual image are finely adjusted. As described above, in the HUD device disclosed in Patent Document 1, it is substantially impossible to significantly change the imaging position of the virtual image for notifying information or the size of the range in which the virtual image can be displayed. For this reason, the occupant may fail to recognize the information presented by the HUD device.

  The present disclosure has been made in view of such problems, and an object of the present disclosure is to provide a HUD device capable of displaying a virtual image so as to be accurately noticed by an occupant. is there.

  In order to achieve the above object, a disclosed first aspect is a HUD device that displays a virtual image (60) that is mounted on a moving object (A) and is visible by an occupant (D) of the moving object. Display unit (40, 240) that emits light of an image (70) formed as a projection surface, and a projection plane unit (30, 230, 330) that displays a virtual image obtained by enlarging the projected image by forming a concave surface. ), And the projection area (20, 220, 320) in which the enlargement ratios of the projection plane portions are different from each other, and the projection range (in which the light emitted from the display is projected by displacing the projection member) A displacement mechanism (90, 290) that changes the projection plane portion arranged in PA1) is a HUD device.

  The projection member in this aspect is provided with a plurality of projection surface portions having different magnifications. Therefore, if the projection surface portion on which the light emitted from the display unit arranged in the projection range is projected is changed by the displacement of the projection member by the changing mechanism, the imaging position of the virtual image is eventually changed by changing the magnification ratio of the virtual image. It can be clearly changed.

  With such a HUD device, it is possible to switch the imaging position at which the light of the image is formed as a virtual image according to the characteristics of the information notified to the occupant by this image by changing the projection surface portion. Become. Therefore, the HUD device can display a virtual image so as to be accurately noticed by an occupant.

  Moreover, the 2nd aspect disclosed is a HUD apparatus which mounts in a moving body (A) and displays the virtual image (60) visually recognizable by the passenger | crew (D) of a moving body, Comprising: It forms as a virtual image A projection member (220, 421 to 423) that has a display (240) that emits light of the image (70) and a projection surface portion (230, 430, 530) on which the light of the image is projected, and displays a virtual image of the image. , 520), and a displacement mechanism (290, 490, 590) for increasing or decreasing the area of the projection surface portion located in the projection range (PA1) where the light emitted from the display device is projected by displacing the projection member, It is set as the HUD apparatus provided with.

  According to this aspect, due to the displacement of the projection member by the increase / decrease mechanism, the area of the projection plane onto which the light emitted from the display unit arranged in the projection range is projected is increased or decreased. By such enlargement / reduction of the area of the projection surface, the size of the range in which the virtual image can be displayed can be clearly changed. With such an HUD device, the size or display position of an image formed as a virtual image can be changed according to the characteristics of information notified to the occupant by this image. Therefore, the HUD device can display a virtual image so as to be accurately noticed by an occupant.

  Note that the reference numbers in the parentheses merely show an example of a correspondence relationship with a specific configuration in an embodiment described later, and do not limit the technical scope at all.

In the HUD device of a first embodiment, it is a front view showing virtual image display by the first display mode seen from a driver's seat. It is sectional drawing which shows the structure of a HUD apparatus typically. It is a front view which shows the virtual image display by the 2nd display mode seen from the driver's seat. It is a front view which shows the structure of a combiner. It is a block diagram which shows the structure of the electric system of a HUD apparatus. It is a front view which shows the virtual image display by the 1st display mode seen from the driver's seat in the HUD apparatus of 2nd embodiment. It is a front view which shows the virtual image display by the 2nd display mode seen from the driver's seat. It is sectional drawing which shows the structure of a HUD apparatus typically. It is a front view which shows the virtual image display by the 3rd display mode seen from the driver's seat in the HUD apparatus of 3rd embodiment. It is sectional drawing which shows the structure of a HUD apparatus typically. It is a front view which shows the virtual image display by the 1st display mode seen from the driver's seat in the HUD apparatus of 4th embodiment. It is a front view which shows the virtual image display by the 2nd display mode seen from the driver's seat. It is a block diagram which shows the structure of the electric system of a HUD apparatus. In the HUD device of a fifth embodiment, it is a front view showing virtual image display by the first display mode seen from the driver's seat. It is a front view which shows the virtual image display by the 2nd display mode seen from the driver's seat. It is sectional drawing which shows the structure of a HUD apparatus typically.

  Hereinafter, a plurality of embodiments of the present disclosure will be described based on the drawings. In addition, the overlapping description may be abbreviate | omitted by attaching | subjecting the same code | symbol to the corresponding component in each embodiment. When only a part of the configuration is described in each embodiment, the configuration of the other embodiment described above can be applied to the other part of the configuration. In addition, not only combinations of configurations explicitly described in the description of each embodiment, but also the configurations of a plurality of embodiments can be partially combined even if they are not explicitly specified unless there is a problem with the combination. .

(First embodiment)
The HUD device 100 according to the first embodiment of the present disclosure shown in FIGS. 1 to 4 is mounted on a vehicle A. The HUD device 100 displays various virtual images 60 that can be visually recognized by the driver D who is an occupant of the vehicle A. The HUD device 100 is disposed in front of the driver D. The main body portion of the HUD device 100 is accommodated in the instrument panel 11 of the vehicle A.

  The HUD device 100 includes a combiner 20, a display 40, a housing 50, a rotation mechanism 90, a control circuit 80 (see FIG. 5), and the like.

  The combiner 20 is provided separately from the windshield 13 at a position away from the windshield 13 of the vehicle A toward the driver's seat on which the driver D is seated. The combiner 20 is a half mirror that transmits a part of incident light and reflects the other part. The combiner 20 is formed in an elliptical plate shape using a plate material made of a translucent material such as polycarbonate resin, acrylic resin, and glass. The combiner 20 is curved in a concave shape. The combiner 20 is provided with a rotation support portion 25 and a plurality of projection surface portions 30.

  The rotation support portion 25 is formed at the center (center) of the combiner 20. The rotation support portion 25 is attached to the housing 50. The combiner 20 is supported by the housing 50 so as to be rotationally displaceable around a virtual rotation axis RA defined by the rotation support portion 25, and rotates relative to the housing 50. The rotation axis RA is along the front-rear direction of the vehicle A, and has a substantially horizontal posture with respect to the ground on which the vehicle A is placed.

  The plurality of projection surface portions 30 are formed on one surface of the combiner 20 facing the driver seat. Each projection surface portion 30 is formed in a concave shape. Lights of various images 70 formed as virtual images 60 are projected onto some of the plurality of projection surface portions 30. The specific projection plane 30 on which the light of the image 70 is projected (hereinafter, the selective projection plane 30s) reflects the light of the image 70 toward the driver D. As a result, the virtual image 60 obtained by enlarging the projected image 70 is displayed so as to be visible by the driver D at a position farther than the selected projection plane 30s.

  The combiner 20 includes a plurality (four) of the near projection surface portions 32 and a plurality (two) of the far projection surface portions 31 as the projection surface portion 30. Each of the neighboring projection surface portions 32 is formed in a perfectly circular region around the rotation support portion 25 in the inner peripheral surface of the combiner 20. Each neighboring projection surface portion 32 is defined side by side with the combiner 20 in an arrangement shifted by 90 ° in the circumferential direction around the rotation support portion 25. The corner portions of the neighboring projection surface portions 32 overlap each other. The pair of neighboring projection surface portions 32 are located with the rotation support portion 25 in between in the minor axis direction of the combiner 20. The remaining pair of neighboring projection surface portions 32 are positioned with the rotation support portion 25 in between in the major axis (longitudinal) direction of the combiner 20. The pair of far projection surface portions 31 are located on the outer peripheral side of each of the neighboring projection surface portions 32 with the rotation support portion 25 interposed therebetween in the major axis direction of the combiner 20.

  The near projection surface portion 32 and the far projection surface portion 31 are curved in a concave shape with different curvatures. Therefore, the near projection surface portion 32 and the far projection surface portion 31 function as concave mirrors having different magnifications. Specifically, the curvature of the far projection surface portion 31 is defined to be larger than the curvature of the near projection surface portion 32. Therefore, the enlargement factor of the far projection surface part 31 is larger than the enlargement factor of the near projection surface part 32.

  The above combiner 20 changes the selected projection plane part 30 s to be arranged in the projection range PA <b> 1 among the plurality of near projection plane parts 32 and the far projection plane part 31 by rotating with respect to the housing 50. The selected projection plane part 30s in the projection range PA1 faces the driver's seat in a state of protruding from the upper surface of the instrument panel 11. The light of the image 70 emitted from the display device 40 is projected onto the selective projection plane unit 30s. The light of the image 70 projected onto the near projection plane 32 and the light of the image 70 projected onto the far projection plane 31 are imaged as virtual images 60 at different imaging positions.

  Specifically, when the combiner 20 is fixed in a posture along the short axis in the vertical direction of the vehicle A (see FIG. 1), one neighboring projection surface portion 32 is disposed in the projection range PA1. . The light of the image 70 projected on the near projection plane 32 is formed as a near virtual image 62, for example, about 0.5 meters ahead of the near projection plane 32.

  On the other hand, when the combiner 20 is fixed in a posture along the long axis in the vertical direction of the vehicle A (see FIG. 3), in addition to the one near projection surface portion 32, one far projection surface portion 31 is in the projection range PA1. Has been placed. The light of the image 70 projected on the far projection surface portion 31 is formed as a far virtual image 61, for example, about 1.5 meters ahead of the far projection surface portion 31.

  In the HUD device 100, a state in which the minor axis of the combiner 20 is along the vertical direction of the vehicle A is referred to as “first display mode”, and a state in which the long axis of the combiner 20 is along the vertical direction of the vehicle A is This is called “two display mode”. In the second display mode, the HUD device 100 allows the driver to visually recognize both the far virtual image 61 and the near virtual image 62. The distant virtual image 61 is displayed above the near virtual image 62 when viewed from the driver D.

  The display device 40 is configured to emit light of the image 70 toward the selected projection plane unit 30s arranged in the projection range PA1. The indicator 40 is disposed behind the combiner 20 in the front-rear direction of the vehicle A. The display 40 includes a liquid crystal panel 41, a projection light source 43, and the like.

  The liquid crystal panel 41 has a display surface 42. The display surface 42 is formed in a rectangular flat plate shape. A large number of pixels are two-dimensionally arranged on the display surface 42. Each pixel is provided with red, green, and blue sub-pixels. The liquid crystal panel 41 can display various images 70 on the display surface 42 in color by controlling the light transmittance of the sub-pixels. In the following description, the image 70 formed on the display surface 42 is particularly referred to as an “intermediate image 70b”.

  The projection light source 43 includes a plurality of LEDs that emit white light source light, and a prism that guides light emitted from each LED to the liquid crystal panel 41. The light emitted from each LED is guided to the back side of the display surface 42 to transmit and illuminate the intermediate image 70b formed on the display surface 42. The light that has passed through the display surface 42 is projected onto the selected projection surface portion 30s in the projection range PA1.

  The housing 50 is a housing of the HUD device 100 that is formed in a box shape from a resin material. The housing 50 accommodates the display 40, the control circuit 80 (see FIG. 5), and the like. The housing 50 is accommodated in the instrument panel 11 so that it is difficult for the driver D to visually recognize the housing 50. The upper surface of the housing 50 is aligned with the color of the instrument panel 11 and the texture so that the upper surface of the instrument panel 11 can be viewed integrally. The housing 50 is provided with a projection opening 51 and a combiner support portion 53.

  The projection opening 51 is a through-opening formed in an irradiation range of light emitted from the display surface 42 toward the selective projection surface portion 30 s among the plurality of wall portions constituting the housing 50. The projection opening 51 is fitted with a lid member 52 formed in a plate shape by a translucent resin material. The lid member 52 prevents dust and dust from entering the housing 50 by physically closing the projection opening 51 while allowing the light of the image 70 to pass therethrough.

  The combiner support portion 53 is a bearing portion formed on the wall portion of the housing 50. The combiner support portion 53 supports both ends of the rotation support portion 25 in the axial direction in a posture in which the rotation axis RA of the combiner 20 is along the front-rear direction of the vehicle A. The combiner 20 can be rotationally displaced with respect to the housing 50 by the support of the rotation support portion 25 by the combiner support portion 53. As a result, among the plurality of projection surface portions 30, at least a part of each projection surface portion (hereinafter referred to as a retracted projection surface portion) 30r at a position retracted from the projection range PA1 is accommodated in the housing 50.

  The rotation mechanism 90 is a mechanism that rotates and displaces the combiner 20 around the rotation axis RA. The rotation mechanism 90 can switch the selected projection plane unit 30 s arranged in the projection range PA <b> 1 among the plurality of projection plane units 30 by rotating the combiner 20. In addition, the rotation mechanism 90 can increase / decrease the number of the projection plane parts 30 arrange | positioned in projection range PA1 by rotationally displacing the combiner 20. FIG. The rotation mechanism 90 includes a stepping motor 91, a reduction gear unit 92, and the like.

  The stepping motor 91 is a permanent magnet type motor, for example, and outputs a rotational force for displacing the combiner 20 from the output shaft. The reduction gear unit 92 has a configuration in which one or a plurality of transmission gears are engaged. The reduction gear unit 92 transmits the rotation to the rotation support unit 25 while reducing the rotation of the stepping motor 91. The rotation mechanism 90 rotates and displaces the combiner 20 by 90 degrees by the rotation of the output shaft of the stepping motor 91, and sequentially switches between the first display mode and the second display mode.

  As shown in FIGS. 5 and 2, the control circuit 80 is a circuit that controls display by the HUD device 100. The control circuit 80 is mainly configured by a microcontroller 81 having a processor, a RAM, a storage medium, and the like. The control circuit 80 is connected to a display control device 88 mounted on the vehicle A in addition to the liquid crystal panel 41, the projection light source 43, and the stepping motor 91.

  The display control device 88 is connected to a communication bus 89 mounted on the vehicle A. Information on the vehicle A based on the detection results of various mounted sensors is output to the communication bus 89. The display control device 88 acquires information on the vehicle A through the communication bus 89. The display control device 88 selects the image 70 for notifying the driver D of the acquired information on the vehicle A. In addition, the display control device 88 uses the first display mode and the second display mode so that the projection plane 30 suitable for the projection of the selected image 70 is arranged in the projection range PA1 based on the acquired information characteristic of the vehicle A. Set which one to use. The display control device 88 outputs a control signal for projecting the selected image 70 onto the selected projection surface unit 30 to the control circuit 80.

  The control circuit 80 performs display control of the liquid crystal panel 41 and light emission control of the projection light source 43 according to the control signal output from the display control device 88. In addition, the control circuit 80 performs rotation control of the combiner 20 by the rotation mechanism 90. Accordingly, the rotation mechanism 90 selects the selected projection plane unit 30s associated with the image 70 projected by the display device 40, and controls the operation of the stepping motor 91 so that the selected projection plane unit 30s is arranged in the projection range PA1. To do.

  Based on the control by the control circuit 80 and the display control device 88 described above, details of the virtual image 60 displayed by the HUD device 100 will be further described.

  As shown in FIG. 3, when at least one of the urgency level and the importance level is high and there is information that the driver D (see FIG. 2) wants to recognize immediately, the HUD device 100 is set to the second display mode. Then, the image 70 for notifying information with high urgency or importance is displayed as the far virtual image 61. For example, the image 70 relating to the road guidance display and the preventive safety display is associated with the far projection plane 31 and is projected onto the far projection plane 31. Specifically, a turn-by-turn image 71 or the like that notifies a point to turn left or right is displayed as a distant virtual image 61 on the road guidance display. Further, an AEB (Autonomous Emergency Braking) indicator image for notifying the operation of the collision damage reduction (automatic) brake mounted on the vehicle A is displayed as the far virtual image 61 of the preventive safety display. These images 70 are temporarily displayed only during a period in which the information to be notified is valid, and are extinguished when the valid period expires. When the display of the far virtual image 61 is thus completed, the HUD device 100 is returned to the first display mode.

  On the other hand, when there is no information with high urgency or importance, the HUD device 100 is set to the first display mode. Then, in both the first display mode and the second display mode shown in FIGS. 1 and 3, an image 70 that mainly notifies the state of the vehicle A is displayed as the neighborhood virtual image 62. For example, a vehicle speed image 72 indicating the traveling speed of the vehicle A, an eco-drive indicator image based on the instantaneous fuel consumption of the vehicle A, and the like are associated with the vicinity projection surface unit 32, and are displayed on the vicinity projection surface unit 32 arranged in the projection range PA1. Projected.

  The combiner 20 of the first embodiment described so far is provided with a plurality of projection surface portions 30 having different magnifications. Therefore, if the selected projection plane 30s arranged in the projection range PA1 is changed by the rotational displacement of the combiner 20 by the rotation mechanism 90, the imaging position of the virtual image 60 is clearly changed by changing the magnification ratio of the virtual image 60. obtain.

  With such a HUD device 100, an image formation position at which the light of the image 70 is imaged as a virtual image 60 by changing the projection surface unit 30 is determined according to the characteristics of information notified to the occupant by the image 70. It is possible to switch. Therefore, the HUD device 100 can display a virtual image of the image 70 for notifying information so as to be accurately noticed by the occupant.

  In addition, in the first embodiment, at least a part of the retracting projection surface portion 30 r on which the light of the image 70 is not projected is accommodated in the housing 50. According to the above, the retracted projection surface portion 30r that is not used for virtual image display is less noticeable, so that the appearance can be prevented from deteriorating even when the plurality of projection surface portions 30 are defined in the combiner 20.

  Moreover, the HUD device 100 of the first embodiment can additionally arrange the far projection surface portion 31 in the projection range PA1 by switching to the second display mode when notifying information of high urgency or importance. is there. The HUD device 100 having such a configuration can attract the attention of the driver D and accurately convey the information to the driver D by displaying the distant virtual image 61 in the central visual field of the driver D or in the vicinity thereof.

  Furthermore, in the first embodiment, the rotation mechanism 90 realizes the change of the magnification ratio of the virtual image 60 and the image formation position of the virtual image 60 only by a simple movement of rotating the combiner 20. As described above, if the plurality of projection surface portions 30 are arranged around the rotation axis RA and rotated by the rotation mechanism 90, the HUD device 100 can be accurately noticed by the driver D while avoiding complication of the configuration. Such virtual image display can be performed.

  In addition, in the first embodiment, since the various images 70 and the respective projection surface portions 30 are associated with each other, the imaging position of each image 70 that notifies the driver D of information is used to notify the information. It can be a suitable position. Therefore, the HUD device 100 can display the image 70 for notifying information so as to be noticed accurately by the driver.

  In the first embodiment, the combiner 20 corresponds to the “projection member”, the rotation mechanism 90 corresponds to the “displacement mechanism”, the vehicle A corresponds to the “moving body”, and the driver D becomes the “occupant”. Equivalent to.

(Second embodiment)
The HUD device 200 of the second embodiment shown in FIGS. 6 to 8 is a modification of the first embodiment. The HUD device 200 according to the second embodiment includes a combiner 220, a display 240, a housing 250, an elevating mechanism 290, a control circuit 80 (see FIG. 5) that is substantially the same as that of the first embodiment, and the like. The combiner 220, the display device 240, the housing 250, and the lifting mechanism 290 have a configuration corresponding to each element 20, 40, 50, 90 (see FIG. 2) of the first embodiment.

  The combiner 220 is formed in a shape in which three ellipses are joined in the major axis direction. Each elliptical portion is curved in a concave shape. The combiner 220 is provided with a slide fitting portion 225 and a plurality (three) of projection surface portions 230. The slide fitting portion 225 is attached to the housing 250 so as to be slidable along the vertical direction of the vehicle A. The combiner 220 can change the amount of protrusion upward from the housing 250 and the instrument panel 11.

  The plurality of projection planes 230 include a front projection plane 231, a left projection plane 232, and a right projection plane 233. The front projection surface portion 231 is formed in the central elliptical portion having the largest area among the three elliptical portions arranged in the width direction of the vehicle A. The left projection surface portion 232 is formed in an elliptical plate-like portion located on the left side of the front projection surface portion 231 when viewed from the driver D. The right projection surface portion 233 is formed in an elliptical plate-like portion located on the right side of the front projection surface portion 231 when viewed from the driver D. The areas of the left projection surface portion 232 and the right projection surface portion 233 are substantially the same as each other, and are smaller than the area of the front projection surface portion 231. Each center of the left projection surface portion 232 and the right projection surface portion 233 is located below the center of the front projection surface portion 231.

  The front projection surface portion 231, the left projection surface portion 232, and the right projection surface portion 233 are curved in a concave shape with different curvatures, and function as concave mirrors having different magnifications. In the second embodiment, the enlargement factor of the front projection surface portion 231 is set to a value larger than the enlargement factors of the left projection surface portion 232 and the right projection surface portion 233. On the other hand, the left projection surface portion 232 and the right projection surface portion 233 are curved in a concave shape with substantially the same curvature, and have substantially the same magnification.

  The combiner 220 changes the selected projection plane part 230s to be arranged in the projection range PA1 and increases / decreases the area of the front projection plane part 231 located in the projection range PA1 by sliding displacement in the vertical direction with respect to the housing 250. Specifically, when the combiner 220 is lowered downward (see FIG. 6), only the front projection surface portion 231 among the three projection surface portions 230 is arranged in the projection range PA1 as the selected projection surface portion 230s. In this case, the left projection surface portion 232 and the right projection surface portion 233 are accommodated in the housing 250 as the retracted projection surface portion 230r. In addition, the front projection surface portion 231 projects only the upper region upward from the housing 250, and the lower region located outside the projection range PA1 is accommodated in the housing 250 as the retreat region 231r. .

  In the first display mode as described above, the light of the image 70 projected on the front projection surface portion 231 is formed as a front virtual image 261, for example, about 1.5 meters ahead of the front projection surface portion 231. For example, an image 70 notifying the state of the vehicle A such as the vehicle speed image 72 is displayed as the front virtual image 261.

  On the other hand, when the combiner 220 is raised most upward (see FIG. 7), all of the front projection surface portion 231, the left projection surface portion 232, and the right projection surface portion 233 are arranged in the projection range PA1 as the selection projection surface portion 230s. ing. In addition, substantially the entire front projection surface portion 231 protrudes upward from the housing 250 and is disposed within the projection range PA1.

  In the second display mode as described above, the area in which the front virtual image 261 can be displayed in the space in front of the windshield 13 is expanded upward due to the increase in the area of the front projection surface portion 231. As a result, the number of images 70 displayed simultaneously as the front virtual image 261 can be increased, or the size of the image 70 displayed as the front virtual image 261 can be increased. For example, in addition to the vehicle speed image 72, a turn-by-turn image 71 and the like are displayed as the front virtual image 261.

  Moreover, the light of the image 70 projected on the left projection surface unit 232 and the right projection surface unit 233 is formed as a left virtual image 263 and a right virtual image 264, respectively. The left virtual image 263 is formed at a position shifted leftward from the front of the driver D and at a position of about 0.7 meters from the left projection surface portion 232 with a front and rear depth. The right virtual image 264 is formed at a position shifted from the front of the driver D in the right direction and at a position of about 0.7 meters from the right projection surface portion 233 with a depth of front and rear.

  As the left virtual image 263 and the right virtual image 264, for example, a lane marking indicator image 74a indicating whether or not the lane marking is correctly recognized by the driving support system is displayed. In addition, a pedestrian warning image 74b for notifying a pedestrian approaching from the front side, a blind spot monitor (BSM) image 74c for notifying the approach of a subsequent vehicle traveling in the adjacent lane, the left virtual image 263 and the right side It is displayed as a virtual image 264.

  The display 240 can irradiate the light of the image 70 at a wider angle in the width direction than the display 40 (see FIG. 1) of the first embodiment. With such a configuration, in the second display mode, in addition to the front projection surface portion 231, the display 240 also displays the left projection surface portion 232 and the right projection surface portion 233 protruding upward from the instrument panel 11 of the image 70. It is possible to irradiate light.

  A projection opening 251 and a slide support portion 253 are formed in the housing 250. The projection opening 251 is a through-hole formed in the wall portion of the housing 250 so that the light emitted from the display device 240 is irradiated to the left projection surface portion 232 and the right projection surface portion 233 protruding from the instrument panel 11. It is an opening. The projection opening 251 is closed by a translucent lid member 252.

  The slide support part 253 supports the combiner 220 so that it can be displaced along the vertical direction. The slide support portion 253 is formed with a pair of guide grooves 254 extending along the vertical direction. One guide groove 254 is provided on each side wall of the housing 250 located on both sides of the combiner 220 in the width direction. The combiner 220 can be moved up and down along the guide groove 254.

  The elevating mechanism 290 is a mechanism that realizes the change of the projection plane unit 230 arranged in the projection range PA1 and the increase / decrease of the area of the front projection plane unit 231 arranged in the projection range PA1 by raising and lowering the combiner 220 in the vertical direction. is there. In accordance with an output signal from the control circuit 80 (see FIG. 5), the elevating mechanism 290 sets the combiner 220 so that the selected projection plane unit 230s associated with the image 70 projected by the display unit 240 is disposed in the projection range PA1. Slide it up and down. In addition, the elevating mechanism 290 slides and moves the combiner 220 in the vertical direction so that the area associated with the image 70 projected by the display device 240 is located within the projection range PA1.

  The elevating mechanism 290 includes, for example, a set of screw shafts and screw nuts, a motor 291 and the like. The screw shaft extends in the vertical direction along the guide groove 254. The screw nut is screwed to the screw shaft and is fixed to the combiner 220. The screw nut can move integrally with the combiner 220 along the rotating screw shaft. The motor 291 is a servo motor or a stepping motor, and can transmit rotation to the screw shaft. The elevating mechanism 290 enables the slide displacement of the combiner 220 along the guide groove 254 by rotating the screw shaft by the motor 291.

  Also in the second embodiment described so far, since the selected projection plane part 230s is changed by the slide displacement of the combiner 220 by the lifting mechanism 290, the imaging position of the virtual image 60 is clearly changed as in the first embodiment. obtain. Therefore, the HUD device 200 can display a virtual image of the image 70 for notifying information so that the occupant can accurately recognize the image 70.

  In addition, in the second embodiment, the area of the front projection surface portion 231 arranged in the projection range PA1 is increased or decreased by the slide displacement of the combiner 220 by the lifting mechanism 290. According to the enlargement / reduction of the area of the front projection surface portion 231, the size of the range in which the virtual image 60 can be displayed can be clearly changed. With such a HUD device 200, the size or display position of the image 70 formed as the virtual image 60 can be changed according to the characteristics of the information notified to the occupant by the image 70. . Therefore, the HUD device 200 can display a virtual image of the image 70 for notifying information so that the occupant can accurately recognize the image 70.

  In the second embodiment, the retreat area 231 r where the light of the image 70 is not projected in the front projection surface portion 231 is accommodated in the housing 250. According to the above, the evacuation area 231r that is not used for virtual image display is less noticeable. Therefore, even if it is the structure which increases / decreases the area of the front projection surface part 231 arrange | positioned in projection range PA1, the deterioration of an appearance can be prevented. In the second embodiment, the combiner 220 corresponds to a “projection member”, and the lifting mechanism 290 corresponds to a “displacement mechanism”.

(Third embodiment)
The HUD device 300 of the third embodiment shown in FIGS. 9 and 10 is another modification of the first embodiment. The HUD device 300 according to the third embodiment includes a combiner 320 formed in a disk shape as a configuration corresponding to the combiner 20 (see FIG. 1) of the first embodiment. The combiner 320 includes a rotation support unit 25 that is supported by the housing 50 so as to be capable of rotational displacement, and a plurality (four) of projection surface units 330.

  The plurality of projection planes 330 include two far projection planes 331 and two close projection planes 332. The far projection surface portion 331 and the near projection surface portion 332 are alternately arranged in the circumferential direction around the rotation axis RA defined by the rotation support portion 25. The far projection surface portion 331 and the near projection surface portion 332 are defined so as not to overlap each other. The areas of the far projection surface portion 331 and the near projection surface portion 332 are substantially the same. The far projection surface portion 331 and the near projection surface portion 332 are concavely curved with different curvatures, and function as concave mirrors having different magnifications.

  The rotation mechanism 90 can sequentially switch between the first display mode and the second display mode by rotating the combiner 320 by 90 degrees so that the center of each projection plane 330 is positioned immediately above the rotation axis RA. Therefore, one of the four projection planes 330 positioned immediately above the rotation axis RA is positioned as the selected projection plane 330s in the projection range PA1, and the other one positioned immediately below the rotation axis RA is the retraction projection plane 330r. It will be in the state accommodated in the housing 50. FIG. In the first display mode, the near virtual image 62 is displayed by projecting the light of the image 70 onto the near projection surface portion 332 set as the selected projection surface portion 330s. In the second display mode, the far virtual image 61 is displayed by projecting the light of the image 70 onto the far projection surface portion 331 that is the selected projection surface portion 330s.

  Further, the rotation mechanism 90 realizes a third display mode in which the combiner 320 is continuously rotated. In the third display mode, the display device 40 irradiates the light of the image 70 toward the projection range PA1 in accordance with the rotation of the combiner 320 based on the output signal of the control circuit 80 (see FIG. 5). Specifically, the display 40 projects the projection located in the projection range PA1 by causing the projection light source 43 to emit light at a timing at which the centers of the far projection plane portion 331 and the near projection plane portion 332 are located immediately above the rotation axis RA. The light of the image 70 is projected onto the surface portion 330. The light of the image 70 is alternately projected onto the far projection surface portion 331 and the near projection surface portion 332 having different magnifications. As a result, one image 70 is alternately displayed as the far virtual image 61 and the near virtual image 62. Based on such a principle, in the third display mode, display of the virtual image 60 whose imaging position changes periodically is realized. As the virtual image 60 in which the imaging position changes, an image 70 related to preventive safety such as an AEB (Autonomous Emergency Braking) indicator image 71a for notifying or notifying the operation of the collision damage reduction (automatic) brake mounted on the vehicle A is displayed. Is done.

  Also in the third embodiment described so far, the selected projection plane part 330s is changed by the rotational displacement of the combiner 320, so that the imaging position of the virtual image 60 can be clearly changed as in the first embodiment. Accordingly, the HUD device 300 can display a virtual image of the image 70 for notifying information so that the passenger can be accurately noticed.

  In addition, in the third display mode of the third embodiment, the virtual image 60 moves in the depth direction on the appearance of the driver D. According to such a movement of the virtual image 60, the HUD device 300 can draw attention of the driver D and surely make the driver D aware of highly urgent information. In the third embodiment, the combiner 320 corresponds to a “projection member”.

(Fourth embodiment)
The HUD device 400 of the fourth embodiment shown in FIGS. 11 to 13 is a modification of the second embodiment. The HUD device 400 according to the fourth embodiment is provided with a plurality (three) of combiners 421 to 423. In addition, the HUD device 400 includes an elevating mechanism 490 that individually raises and lowers the combiners 421 to 423 and a housing 450 that accommodates the combiners 421 to 423 and the elevating mechanism 490. Each combiner 421-423, the raising / lowering mechanism 490, and the housing 450 are the structures corresponded to the combiner 220, the raising / lowering mechanism 290, and the housing 250 (refer FIG. 8) of 2nd embodiment, respectively.

  The center combiner 421, the side combiner 422, and the side combiner 423 are half mirrors each having a projection surface portion 430. The curvatures of the projection surface portions 430 are substantially the same. Therefore, each projection surface portion 430 functions as a concave mirror having substantially the same magnification. The combiners 421 to 423 are arranged in the width direction of the vehicle A along the upper edge of the instrument panel 11 in a posture in which the projection surface portions 430 face the driver's seat. Each combiner 421-423 is attached to the housing 450 in a state where it can be raised and lowered individually.

  The center combiner 421 is disposed between the two side combiners 422 and 423, and is located in front of the driver D (see FIG. 8). In the center combiner 421, a front projection surface portion 431 is defined as a projection surface portion 430. The light of the image 70 projected on the front projection surface portion 431 is imaged in front of the front projection surface portion 431 as a front virtual image 461.

  One side combiner 422, 423 is arranged on each side of the center combiner 421 in the width direction of the vehicle A. In the side combiner 422 located on the left side of the center combiner 421 when viewed from the driver D (see FIG. 8), a left projection surface portion 432 is defined as the projection surface portion 430. On the side combiner 423 located on the right side of the center combiner 421 when viewed from the driver D, a right projection surface portion 433 is defined as the projection surface portion 430. The light of the image 70 projected on the left projection surface unit 432 and the right projection surface unit 433 is formed at positions shifted left and right from the front virtual image 461 as a left virtual image 463 and a right virtual image 464, respectively.

  The elevating mechanism 490 increases or decreases the total sum of the areas of the projection surface portions 430 protruding from the housing 450 and positioned within the projection range PA1 by individually slidably moving the combiners 421 to 423 in the vertical direction. The retreat area 430r at a position outside the projection range PA1 in each projection surface portion 430 is accommodated in the housing 450 by the elevation by the elevation mechanism 490. The elevating mechanism 490 has three sets of screw mechanism parts configured by, for example, a screw shaft, a screw nut, motors 491a to 491c, and the like. Each screw mechanism unit can slide and displace one of the three combiners 421 to 423 by the rotation of the motors 491a to 491c.

  The elevating mechanism 490 elevates and lowers the center combiner 421 based on the output signal from the control circuit 80, and increases or decreases the area of the front projection surface portion 431 disposed in the projection range PA1. As described above, the front projection surface portion 431 positions the area associated with the image 70 projected by the display device 240 within the projection range PA1. For example, the light of the vehicle speed image 472 is projected onto the front projection surface portion 431.

  The vehicle speed image 472 is an image 70 that shows the current traveling speed of the vehicle A in comparison with the speed limit of the road that is traveling. When the vehicle speed image 472 is displayed, the area of the front projection surface portion 431 located within the projection range PA1 is associated with the traveling speed of the vehicle A. Therefore, the elevating mechanism 490 continuously increases or decreases the amount of protrusion of the front projection surface portion 431 from the instrument panel 11 according to the traveling speed of the vehicle A. The vehicle speed image 472 includes a pair of bar image portions 472a and 472b extending upward according to the traveling speed. Since the front projection surface portion 431 is expanded upward as the traveling speed increases, the size of the range in which the front virtual image 461 can be displayed is also expanded upward in the space. Therefore, the virtual image display of the bar image portions 472a and 472b extending upward according to the traveling speed becomes possible.

  In addition, when the left virtual image 463 and the right virtual image 464 are displayed, the elevating mechanism 490 operates to raise each side combiner 422, 423, and the left projection surface portion 432 and the right projection surface portion 433 are projected in the projection range PA1. Located within. According to the above operation, since the projection surface portion 430 is expanded to the left and right along the width direction, the size of the range in which the virtual image 60 can be displayed is also expanded to the left and right in the space. As a result, for example, when turning right and left at an intersection and changing lanes, a pedestrian warning image 74b, a BSM image 74c, and the like can be displayed as a left virtual image 463 or a right virtual image 464.

  Also in the fourth embodiment described so far, the projection surface portion 430 is expanded and contracted by the slide displacement of the combiners 421 to 423 by the elevating mechanism 490, so that the image 70 formed as the virtual image 60 is similar to the second embodiment. The size or display position can be clearly changed. Accordingly, the HUD device 400 can display a virtual image of the image 70 for notifying information so that the passenger can be accurately noticed.

  In addition, the HUD device 400 of the fourth embodiment can cause the increase / decrease of the area of the projection plane part 430 located in the projection range PA1 by making the plurality of combiners 421 to 423 slide. Therefore, the HUD device 400 can further display the virtual image 60 so as to be accurately noticed by the passenger.

  Further, in the fourth embodiment, the front virtual image 461 is enlarged toward the range of the central visual field of the driver D, so that the driver D is easily aware of the excess speed. In this way, if the vehicle speed image 472 is expanded and contracted in the vertical direction according to the traveling speed of the vehicle A, the driver D can be encouraged to be ready. In the fourth embodiment, the combiners 421 to 423 each correspond to a “projection member”, and the elevating mechanism 490 corresponds to a “displacement mechanism”.

(Fifth embodiment)
The HUD device 500 of the fifth embodiment shown in FIGS. 14 to 16 is a modification of the fourth embodiment. In the HUD device 500 according to the fifth embodiment, configurations corresponding to the side combiners 422 and 423 (see FIG. 12) of the fourth embodiment are omitted. In the HUD device 500, the center combiner 520 is moved up and down by the lifting mechanism 590, whereby the first display mode in which the center combiner 520 is lowered (see FIG. 14) and the second display mode in which the center combiner 520 is lifted (see FIG. 15). To see).

  The control circuit 80 (see FIG. 13) of the HUD device 500 switches between the first display mode and the second display mode according to the shift position of the vehicle A based on the control signal from the display control device 88 (see FIG. 13). Switch. Specifically, when the shift position is in the parking “P” position, HUD device 500 is set to the first display mode. In the first display mode, the area below the projection surface portion 530 is accommodated in the housing 550 as a retreat area 530r. And the light of the shift position image 571 projected on the area | region which protruded from the instrument panel 11 among the projection surface parts 530 is imaged on the front of the driver | operator D as the front virtual image 561. FIG.

  When the shift position is changed to the drive “D” position, the HUD device 500 switches from the first display mode to the second display mode. At this time, when the center combiner 520 is lifted by the lifting mechanism 590, the projection surface portion 530 positioned in the projection range PA1 is expanded upward. Then, instead of the shift position image 571, a vehicle speed image 572 having a size larger than that of the image 571 is formed as a front virtual image 561.

  Even in the fifth embodiment described so far, the same effects as those in the fourth embodiment can be obtained by the expansion and contraction of the projection surface portion 530. Therefore, the HUD device 500 can display a virtual image of the image 70 for notifying information so as to be accurately noticed by the occupant.

  In addition, in the fifth embodiment, the image 70 displayed as the front virtual image 561 changes clearly by changing the shift position. Therefore, the HUD device 500 can make the driver D aware of the erroneous shift operation. In the fifth embodiment, the center combiner 520 corresponds to a “projection member”, and the lifting mechanism 590 corresponds to a “displacement mechanism”.

(Other embodiments)
Although a plurality of embodiments have been described above, the present disclosure is not construed as being limited to the above-described embodiments, and can be applied to various embodiments and combinations without departing from the scope of the present disclosure. it can.

  In the above-described embodiment, the retracted projection surface portion and the retracted area that are not used for displaying the virtual image 60 are accommodated in the housing so as not to be visually recognized by the occupant. However, the region of the combiner where the image light is not projected may be exposed outside the housing. Moreover, in the said embodiment, the housing was a different body from the instrument panel, and was accommodated in the instrument panel. However, the instrument panel and the housing may be integrally configured, and the configuration of the display, the control circuit, and the like may be accommodated in a housing portion provided in the instrument panel.

  The curvature of each projection plane part of the above embodiment is based on, for example, the curvature of the center of each projection plane part. The curvature of the entire projection surface portion may be constant at the center curvature, or may gradually change as the distance from the center increases. The magnification of each projection plane is also defined based on the curvature of each center. Note that the center of each projection plane is the center of gravity of the projection plane for convenience. Moreover, the combiner may form the projection surface part by the concave surface of the Fresnel lens shape by which the curved surface divided | segmented into plurality was shifted and arrange | positioned in the plate | board thickness direction.

  In the above embodiment, a projector that combines a liquid crystal panel and a projection light source is used as a display that emits light of an image. However, the configuration of the display can be changed as appropriate. For example, a DLP (Digital Light Processing (registered trademark)) projector having a digital micro device (DMD) having a large number of micromirrors and a projection light source for projecting light toward the DMD can be used as the display. . Furthermore, a laser scanner having a MEMS (Micro Electro Mechanical Systems) mirror and a laser light source that projects light toward the MEMS mirror can be used as the display.

  In the above embodiment, the light of the image emitted from the virtual image display device is directly incident on each projection plane. However, in order to increase the optical path distance from the display surface to each projection surface, an optical system including one or a plurality of concave mirrors or plane mirrors, lenses, or the like that refracts the light of the image in the housing may be provided. Good.

  The function of the display control device 88 in the above embodiment may be incorporated in the control circuit 80 of the HUD device. Or the control circuit of the other vehicle equipment mounted in the vehicle A may also serve as the function of the display control device 88. For example, a control circuit provided in the combination meter can control the virtual image display of the HUD device together with the display of the meter. Alternatively, an HCU (Human Machine Interface) control unit (HMI) that integrally controls the presentation of information to the driver may also serve as the function of the display control device 88. Furthermore, the control circuit of the portable terminal brought into the passenger compartment by the driver may also serve as the function of the display control device 88.

  In the vehicle A as in the above-described embodiment, eyelips can be set for each of the right eye and the left eye based on an eye range that statistically represents the distribution of the position of the driver's eyes. It is desirable for the HUD device to display each virtual image so that the driver can visually recognize the left and right eyes within the eyelips. In addition, the characteristic structure of this indication is applicable also to the HUD apparatus mounted in various moving bodies (transport equipment), such as ships other than a vehicle, and an aircraft.

A vehicle (moving body), D driver (occupant), PA1 projection range, RA rotation axis, 20, 220, 320 combiner (projection member), 421, 520 center combiner (projection member), 422, 423 side combiner (projection) Member), 30, 230, 330, 430, 530, projection surface part, 30r, 230r, 330r retraction projection surface part, 231r, 430r, 530r retraction area, 40, 240 display, 50, 250, 450, 550 housing, 60 virtual image , 70 images, 90 rotating mechanism (displacement mechanism), 290, 490, 590 lifting mechanism (displacement mechanism), 100, 200, 300, 400, 500 HUD device (head-up display device)

Claims (10)

A head-up display device that is mounted on a moving body (A) and displays a virtual image (60) that is visible by an occupant (D) of the moving body,
A display (40, 240) for emitting light of an image (70) formed as the virtual image;
Projection members having a plurality of projection surface portions (30, 230, 330) for displaying the virtual image obtained by enlarging the image projected by being formed in a concave shape, and the magnification ratios of the projection surface portions being different from each other ( 20, 220, 320),
A head-up display device comprising: a displacement mechanism (90, 290) that changes the projection plane portion arranged in the projection range (PA1) in which the light emitted from the display device is projected by displacing the projection member. . A housing (50, 250) for displacably supporting the projection member;
2. The head-up display device according to claim 1, wherein a retracted projection surface portion (30 r, 230 r, 330 r) at a position retracted from the projection range among the plurality of projection surface portions is accommodated in the housing.   The head-up display device according to claim 1, wherein the displacement mechanism increases or decreases the number of the projection surface units arranged in the projection range by displacing the projection member. The projection member (20, 320) is rotatably supported by the housing (50),
The head-up display device according to claim 2, wherein the plurality of projection surface portions (30, 330) are arranged in a circumferential direction around a virtual rotation axis (RA) defined by the projection member. The displacement mechanism (90) continuously rotates the projection member,
The display (40) projects the light of the image on the projection planes (330) having different magnifications in order in accordance with the rotation of the projection member, thereby changing the imaging position of the virtual image. The head-up display device according to claim 4 to display.   The said displacement mechanism displaces the said projection member so that the said projection surface part linked | related with the said image projected by the said display device may be arrange | positioned in the said projection range. Head-up display device. A head-up display device that is mounted on a moving body (A) and displays a virtual image (60) that is visible by an occupant (D) of the moving body,
A display (240) for emitting light of an image (70) formed as the virtual image;
A projection member (220, 421 to 423, 520) having a projection surface (230, 430, 530) on which light of the image is projected, and displaying the virtual image of the image;
A displacement mechanism (290, 490, 590) that increases or decreases the area of the projection surface portion located in the projection range (PA1) in which the light emitted from the display device is projected by displacing the projection member. Head-up display device. A housing (250, 450, 550) supporting the projection member in a displaceable manner;
8. The head-up display device according to claim 7, wherein a retreat area (231 r, 430 r, 530 r) that is out of the projection range in the projection surface is housed in the housing. A plurality of the projection members (421 to 423) are provided,
9. The head-up display according to claim 7, wherein the displacement mechanism (490) increases or decreases the total area of the projection surface portions located in the projection range by individually displacing the plurality of projection members. apparatus.   The head according to any one of claims 7 to 9, wherein the displacement mechanism displaces the projection member so that an area associated with the image projected by the display unit is located within the projection range. Up display device.

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