The present invention relates to a stereo camera that is arranged in the vicinity of the windshield of a vehicle and mounted in a car to obtain surrounding environmental data during running.
In recent years, there has been proposed a drive assistance system or the like in which an imaging device is mounted on a vehicle, information for safety running is provided to a driver on the basis of surrounding environmental data during running of the vehicle acquired by the imaging device, or vehicle control is automatically performed on the basis of the information.
As the aforementioned imaging device, for example, a vehicular camera is known that adopts a technology in which, for example, a distance to an imaging subject is measured by a pair of image sensors arranged right and left to avoid collision with a front vehicle or the like.
As disclosed, for example, in PTL 1, the vehicular camera is often arranged in the vicinity of the windshield of a vehicle such that the temperature tends to increase due to sunlight, heat generated inside the device, or the like.
When the temperature of an inside component exceeds an upper limit temperature, there is a concern that a malfunction occurs, the lifetime of the component is shortened, or the like. Therefore, PTL 1 proposes a structure in which the vehicular camera is covered with a cover member with a clearance and the cover member has a vent hole for venting air-conditioning air such that the temperature around the vehicular camera can quickly be returned to normal temperature even at a time of high temperature in summer seasons or at a time of low temperature in winter seasons.
In addition, for example, PTL 2 discloses an imaging unit including a plurality of monocular cameras, a casing for supporting the monocular cameras, and a circuit board, e.g., a camera imaging element substrate and an image processing substrate, within the casing, including a heat dissipating structure including a heat transfer member that is provided in contact with the casing or the circuit board, in which the heat transfer member contacts the windshield such that the heat in the casing and a casing part is transferred to the windshield to reduce the temperature of the inside component.
PTL 1: JP 3148749 B1
PTL 2: JP 2016-14564 A
The conventional technology described in PTL 1 is described to indicate that the vehicular camera is covered with the cover member having the vent hole, there is a clearance between the cover member and the camera, and environmental stresses such as sunlight or heat can be avoided by the vent hole of the cover member and by heat transfer to the chassis.
However, the vehicular camera described in PTL 1 is described to refer to a heat insulating effect of the cover member from external solar radiation heat or a heat transfer effect from the chassis to a front rail of the vehicle body, but is not described to refer to a structure of dissipating the heat amount generated by the component inside the vehicular camera to the outside in an arrangement state other than the above, i.e., arrangement on the windshield, or the like.
In recent years, the vehicular camera has increasingly been used in a drive assistance system or an automatic drive technology for enhanced safety, and has also been increased in penetration rate. Therefore, mounting even on a small-sized car or a light automobile has been increased, and thus a reduction in size and a reduction in cost are issues. However, a reduction in size of the vehicular camera does not reduce power consumption of the camera itself, but reduces the volume of the camera, resulting in a concern that the heat density is increased and the temperature inside the camera is increased.
When the temperature inside the camera is increased, a failure or a reduction in lifetime of an inside component, e.g., a circuit element, tends to occur. In particular, in the case of an imaging element, e.g., CMOS, which is important for a camera, it is often the case that an upper limit temperature is low. When the temperature is exceeded, there is a high possibility that a failure, e.g., normal operation is not provided, occurs.
Accordingly, with the aforementioned structure only, there is a possibility that the operation of the camera during a hot period in summertime cannot be ensured.
In addition, according to the conventional technology described in PTL 2, the heat of the circuit board and the casing part of the imaging unit is transferred by the heat transfer member contacting the windshield to reduce the internal temperature. Meanwhile, there is a concern that when the temperature of the windshield is increased by solar radiation, the heat amount of the glass is transferred to the imaging unit and the temperature is increased. There is a problem that according to the invention of PTL 2, it is difficult to obtain a heat dissipating effect during a hot period in summertime.
The present invention propose a heat dissipating structure that solves the aforementioned problem and, even when the inside heat density is increased by a reduction in size, effectively releases the heat of a component in a stereo camera to the outside to retain the temperature inside the device within a range of an operation assurance temperature.
In order to solve the problem, a stereo camera of the present invention includes: a pair of image sensors that have respective imaging elements disposed at a same height with a space therebetween; image processing elements that are disposed between the image sensors and process image signals captured by the image sensors; a casing that has the image processing elements and the image sensors incorporated therein; in an area between the image sensors, an inclined surface that is inclined from the image sensors downward toward an imaging direction of the image sensors; an airflow path that is defined so as to extend along the inclined surface of the casing toward the imaging direction; and heat dissipating parts that are thermally connected to the respective image processing elements and disposed on the inclined surface so as to face the airflow path.
Furthermore, according to the present invention, the image processing element is disposed on an inner side relative to the image sensors in a direction between the image sensors.
Furthermore, according to the present invention, a heat transfer member is provided at a contact portion between the image processing element and the heat dissipating part.
Furthermore, according to the present invention, the heat dissipating part has a fin structure that is provided along the airflow path.
Furthermore, according to the present invention, airflow that passes the heat dissipating part is separated from airflow that passes over the image sensor.
Furthermore, according to the present invention, the inclined surface on which the heat dissipating part is arranged includes a recessed portion that brings the casing closer to the image processing element.
Furthermore, according to the present invention, the inclined surface is extended to a casing part on a back surface of the image sensor, and the heat dissipating part of the recessed portion is formed across the entire inclined surface.
Furthermore, according to the present invention, the heat dissipating part of the recessed portion is formed to have a width that widens from below to above the inclined surface.
Furthermore, according to the present invention, a heat insulating member that separates a central part of the casing from a surrounding part of right and left image sensors is arranged on the casing.
Furthermore, according to the present invention, the casing is covered with a cover member having an aperture and is disposed in a vicinity of a windshield of a vehicle.
Furthermore, according to the present invention, an airflow path is formed between the inclined surface of the casing and the cover member.
Furthermore, according to the present invention, a light shielding member is formed on a surface of the cover member facing the windshield.
Furthermore, according to the present invention, an airflow path is formed between the stereo camera and the light shielding member and between the light shielding member and the windshield.
Furthermore, according to the present invention, a position adjustment mechanism is arranged on the cover member.
According to the present invention, it is possible to provide a highly reliable stereo camera in which even when the stereo camera is reduced in size, the heat of the image processing substrate and the image processing element can be effectively released to the outside for heat dissipation, and an increase in temperature of the image sensor due to influences of the heat can be suppressed.
Examples are described below according to the drawings.
A first example of a stereo camera 100 of the present invention is described in conjunction with
The stereo camera 100 is closely disposed to be accommodated in a cover member 115 illustrated in
As illustrated in the camera external appearance view of
On an upper part of the image processing-grade element 109 illustrated in
In
Next, the operation of the stereo camera 101 is described on the basis of
The stereo camera 101 that performs the aforementioned series of operations has a tendency to have increased power consumption year by year because of high functionality.
During the operation of the stereo camera 101, the temperature of the image sensor 106 and the image processing-grade element 109 is increased by heat generated depending on individual power consumption. The stereo camera 101 of the present invention has a structure in which air in the car is caused to pass through the fin shape of the heat dissipating part 120 and dissipates the heat of the image processing-grade element 109 to the outside and cools it, and the temperature in the stereo camera 101 is also reduced accordingly such that an increase in temperature of the image sensor 106 is prevented.
Next, a state of airflow in a case where the stereo camera 101 is arranged in the cover member 115 is described.
A further detailed description is given of environmental temperature and flow of airflow around the stereo camera 101 on the basis of
As illustrated in B-B′ cross-section of
Furthermore, on a surface of the windshield 103 near the camera, a black light shielding film 200, which is called black ceramic, is formed on an upper part of the windshield 103 in order to prevent entry of sunlight toward the stereo camera 101. The light shielding film 200 has very high temperatures when heated by solar radiation. Accordingly, the upper surface of the cover member 115 also serves to protect the stereo camera 101 from the heat generated by solar radiation of the light shielding film 200.
For example, when a driver rides a car and the stereo camera 101 is turned on, in air in the cover member 115, internal air is warmed by heat of the stereo camera 101, and an upward airflow 301 is generated by chimney effect. In that case, air 300 in the car enters the cover member 115 as the airflow 301 through the slit 117 of the cover member 115 and passes around the stereo camera 101 to move to an upper back side of the cover member 115. When the airflow 301 passes and cools the fin formed on the heat dissipating part 120 illustrated in
In addition, when an automotive air conditioner is activated, the temperature of the air 300 in the car is reduced by wind from the air conditioner. Moreover, when the wind is directed to an arrangement direction of the stereo camera 100 using a defroster or the like, the air 300 in the car becomes the airflow 301 and enters the cover member 115 through the slit 117 of the cover member 115, and passes through the periphery of the stereo camera 101 to move to an upper back side of the cover member 115. As compared with the case of natural air cooling, the rising speed of the airflow 301 is faster. Accordingly, when the airflow 301 passes and cools the fin of the heat dissipating part 120 illustrated in
In addition, the air 300 in the car also inflows as the airflow 302 between the cover member 115 and the windshield 103 so as to be able to reduce the temperature, which has been increased by solar radiation, of an upper part of the cover member 115.
As illustrated in
As illustrated in
The power consumption of the image processing element 109 arranged on the image processing substrate 108 is larger than the power consumption of the image sensor 106, and there is a tendency that the amount of heat generated increases due to high functionality of the stereo camera 101.
In the case of the stereo camera of the present example, the airflow 301 that passes the heat dissipating part 120 is separated from the airflow 303 that passes over the image sensor 106. With the aforementioned structure, the heat from the image processing element 109 is released to the upper surface of the casing 105 through the heat dissipating part 120 and is dissipated to the outside by the airflow 301 in a path not passing the vicinity of the image sensor 106, and it is possible to suppress an increase in temperature of the image sensor 106.
With the structure described above, it is possible to provide the stereo camera 101 in which the image processing element 109 in the stereo camera 101 can effectively be cooled and the influence on an increase in temperature of the image sensor 106 due to the heat of the plurality of image processing elements 109 can be reduced.
When the temperature of the right and left sides of the stereo camera 101 is increased non-uniformly due to the heat of the image processing elements 109 inside, there is a possibility that an optical axis misalignment occurs between the image sensors 106 due to a difference in deformation amount of the right and left sides of the casing because of local expansion of the image processing substrate 108, resulting in inaccuracy of detected image data or the like. Accordingly, when the image processing elements 109 and the heat dissipating parts 120 are bisymmetrically disposed as illustrated in
As illustrated in the perspective view of
As illustrated in D-D′ cross-sectional view of
The heat dissipating part 121 of Example 3 has a structure in which the fin of the heat dissipating part 121 is extended to the back surface of the casing 105 such that the airflow 301 described in Example 1 smoothly flows along the heat dissipating part 121. With the aforementioned structure, the flow path resistance can be reduced and the flow speed of the airflow 301 can be increased. Accordingly, the cooling efficiency of the stereo camera 101 can be increased.
As illustrated in
In the case of the stereo camera 101 of Example 5, similar to Example 1, a pair of image sensors 106 is arranged on the right and left of the casing 105, the image processing substrate 108 is arranged between the image sensors 106, and a plurality of image processing-grade elements 109 is mounted on the substrate 108.
The image processing substrate 108 of Example 5 has a structure such that, as illustrated in E-E′ cross-sectional view of
With the aforementioned structure, it is structured such that the heat of the image processing 109 is transferred to the casing 105 and is dissipated to the airflow 301 even without the heat dissipating part 120 illustrated in Example 1.
In addition, the heat released to the casing 105 and transferred to the image sensor 106 causes an increase in temperature of the image sensor 106. Therefore, as a member that prevents the heat from being transferred to the image sensor 106, a heat insulating member 112, e.g., a heat insulating sheet, that separates a central part of the casing 105 from a surrounding part of the right and left image sensors 106, is arranged on the casing 105 illustrated in
As illustrated in the perspective view of
As described above, when a vehicle is parked under blazing sun in summertime, a part near an upper part of the windshield is measured to have very high temperatures. Under such a situation, it is important to protect the stereo camera 101 from solar radiation heat to ensure normal operation and reliability. Therefore, the cover member 125 of Example 6 includes the light shielding member 127, which is formed of a separate member having a high heat insulation property, and is arranged on an upper surface part of the cover member 125, as illustrated in the cross-sectional view of
Furthermore, when the light shielding member 127 is attached to the cover member 125, a position adjustment mechanism 128 that can adjust a distance between the light shielding member 127 and an upper surface of the casing 105 of the stereo camera 101 is arranged and performs adjustment. Thus, it is possible to set the airflows 301 and 302 that are optimum for cooling, and it is possible to effectively reduce an increase in temperature of the stereo camera 101.
Number | Date | Country | Kind |
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JP2017-000967 | Jan 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2017/045873 | 12/21/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2018/128083 | 7/12/2018 | WO | A |
Number | Name | Date | Kind |
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20050001901 | Eggers | Jan 2005 | A1 |
20120050608 | Makara | Mar 2012 | A1 |
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20160257261 | Kageyama | Sep 2016 | A1 |
20160264056 | Uken | Sep 2016 | A1 |
20170334365 | Ikeno | Nov 2017 | A1 |
Number | Date | Country |
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3148749 | Mar 2001 | JP |
2009-100174 | May 2009 | JP |
2012-49613 | Mar 2012 | JP |
2016-14564 | Jan 2016 | JP |
Entry |
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International Search Report with English translation and Written Opinion issued in corresponding application No. PCT/JP2017/045873 dated Apr. 24, 2018. |
Number | Date | Country | |
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20190320159 A1 | Oct 2019 | US |