CN215494127U - Obstacle detection device and intelligent robot - Google Patents

Obstacle detection device and intelligent robot Download PDF

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Publication number
CN215494127U
CN215494127U CN202121448946.6U CN202121448946U CN215494127U CN 215494127 U CN215494127 U CN 215494127U CN 202121448946 U CN202121448946 U CN 202121448946U CN 215494127 U CN215494127 U CN 215494127U
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China
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camera
cameras
detection device
laser emitting
mounting
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CN202121448946.6U
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Chinese (zh)
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李军
袁健
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Shenzhen Silver Star Intelligent Group Co Ltd
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Shenzhen Silver Star Intelligent Technology Co Ltd
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Abstract

The utility model discloses an obstacle detection device and an intelligent robot, wherein the obstacle detection device comprises a camera module, a laser emission device and a control mainboard; the camera module comprises at least three cameras, the at least three cameras are distributed along the circumferential direction of the laser emitting device, and the light incident surfaces of two adjacent cameras form an included angle which is larger than 90 degrees and smaller than 180 degrees in the horizontal direction; the laser emitting device is positioned above or below the at least three cameras; the control mainboard is all connected with laser emission device and at least three camera electricity. So set up, can increase obstacle detection device's detection zone, reduce the detection blind area to be convenient for be equipped with this obstacle detection device's intelligent robot's walking.

Description

Obstacle detection device and intelligent robot
Technical Field
The utility model relates to the technical field of detection, in particular to an obstacle detection device and an intelligent robot.
Background
The intelligent robot is a machine capable of walking on the ground and completing a series of actions, in particular to a cleaning robot, which can replace human beings to remove dust and mop the ground.
The existing intelligent robot is generally configured with an obstacle detection device to detect whether an obstacle exists, however, the range of obstacle detection that can be performed by the existing obstacle detection device is small.
SUMMERY OF THE UTILITY MODEL
The utility model mainly aims to provide an obstacle detection device, and aims to solve the problem that the range of obstacle detection which can be performed by the conventional obstacle detection device is small.
In order to achieve the above object, the utility model provides an obstacle detection device applied to an intelligent robot, which comprises a camera module, a laser emission device and a control main board; wherein,
the camera module comprises at least three cameras, the at least three cameras are distributed along the circumferential direction of the laser emitting device, and the light incident surfaces of two adjacent cameras form an included angle which is larger than 90 degrees and smaller than 180 degrees in the horizontal direction;
the laser emitting device is positioned above or below the at least three cameras;
the control mainboard is electrically connected with the laser emitting device and at least three cameras.
In some embodiments of the present invention, a sum of angles of the cameras receiving the light source in the horizontal direction is greater than or equal to an angle of the laser emitting device emitting the light source in the horizontal direction, and an angle of the cameras receiving the light source in the vertical direction is greater than or equal to an angle of the laser emitting device emitting the light source in the vertical direction.
In some embodiments of the present invention, the obstacle detection device further includes a mounting bracket, the mounting bracket has at least three mounting planes distributed along a circumferential direction of the mounting bracket, an included angle between two adjacent mounting planes is greater than 90 degrees and less than 180 degrees, each camera is exposed from the corresponding mounting plane, and the laser emitting device is exposed from a middle position of the at least three mounting planes.
In some embodiments of the present invention, the camera has an abutting surface disposed opposite to the light incident surface, the abutting surface of the camera is disposed parallel to the light incident surface of the camera, and the abutting surface of the camera abuts against the mounting plane.
In some embodiments of the present invention, the mounting bracket has a connection plane, the connection plane is used for connecting two mounting planes at two ends of at least three mounting planes, and each mounting plane is concavely provided with a yielding through hole penetrating through the connection plane;
the obstacle detection device further comprises a base, wherein the base is connected with the mounting bracket and abutted against the connecting plane;
one end of each camera is limited between the base and the connecting plane, and the other end of each camera extends out of the corresponding yielding through hole.
In some embodiments of the present invention, the camera includes a fixing plate and a lens, a plate surface of the fixing plate is larger than a cross section of the abdicating through hole, the fixing plate is limited between the base and the connecting plane, one end of the lens is fixedly connected to the fixing plate, and the other end of the lens extends out of the abdicating through hole.
In some embodiments of the utility model, the connecting plane is concavely provided with an avoiding groove for accommodating the base;
the fixed plate of each camera is located between the base and the groove wall of the avoiding groove, and the lens of each camera extends out of the corresponding avoiding through hole.
In some embodiments of the present invention, the base has a plurality of positioning protrusions protruding from a periphery thereof, the connection plane has a plurality of positioning grooves recessed therein and communicating with the avoiding groove, and each of the positioning grooves is engaged with a corresponding positioning protrusion.
In some embodiments of the present invention, the base has at least three abutting planes arranged along a circumferential direction thereof, the at least three abutting planes and the at least three mounting planes are arranged in a one-to-one correspondence manner, so that the abutting planes and the mounting planes at corresponding positions are arranged in parallel, the shape of the avoiding groove is adapted to the shape of the base, and the fixing plate of the camera is installed between the abutting planes and the groove walls at corresponding positions of the avoiding groove.
In some embodiments of the present invention, the mounting bracket is provided with a line passing channel communicated with the avoiding groove, the camera module further includes a flexible circuit board, the flexible circuit board is electrically connected with the lens of the camera, and the flexible circuit board further passes through the line passing channel and extends out of the avoiding groove.
In some embodiments of the present invention, a surface of the base adjacent to the fixing plate is provided with a limiting portion, and the limiting portion extends along a periphery of the base.
In some embodiments of the present invention, the connection plane is provided with a plurality of hooks, the control main board is correspondingly provided with a plurality of fastening holes, and each fastening hole is fastened to a corresponding fastening hook, so that the control main board is abutted to the connection plane and covers the avoiding groove.
In some embodiments of the present invention, the center line of the laser emitting device is disposed obliquely.
In some embodiments of the present invention, the laser emitting device is provided with stop protrusions at both ends in a length direction thereof, and the stop protrusions abut against a surface of the mounting bracket.
The utility model also provides an intelligent robot, which comprises a robot body and an obstacle detection device, wherein the obstacle detection device is arranged on the robot body and comprises a camera module, a laser emission device and a control main board; wherein,
the camera module comprises at least three cameras, the at least three cameras are distributed along the circumferential direction of the laser emitting device, and the light incident surfaces of two adjacent cameras form an included angle which is larger than 90 degrees and smaller than 180 degrees in the horizontal direction;
the laser emitting device is positioned above or below the at least three cameras;
the control mainboard is electrically connected with the laser emitting device and at least three cameras.
Obstacle detection device in this application is through installing laser emitter and at least three camera on installing support, the circumference distribution of installing support is followed to at least three camera, the income plain noodles of two adjacent cameras is being greater than 90 degrees and is less than 180 degrees contained angles setting on the horizontal direction, so that two adjacent cameras can cover the region of certain limit on the horizontal direction, the setting of a plurality of cameras makes this obstacle detection device can detect the region of wider, so can carry out detection on a large scale to the obstacle through an obstacle detection device, intelligent robot's manufacturing cost has been reduced. In addition, the intelligent robot provided with the obstacle detection device can better avoid obstacles in the process of traveling, and is convenient for the intelligent robot to realize accurate image building according to the detection result of the obstacle detection device.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.
FIG. 1 is a schematic structural diagram of an obstacle detection apparatus according to an embodiment of the present invention;
fig. 2 is a schematic view of an embodiment of a camera arrangement of the camera module in fig. 1;
FIG. 3 is a schematic view of another embodiment of a camera arrangement of the camera module of FIG. 1;
FIG. 4 is a schematic structural view of one embodiment of the mounting bracket of FIG. 1;
FIG. 5 is a cross-sectional view of the obstruction detection device of FIG. 1;
FIG. 6 is a schematic structural diagram of an embodiment of the base shown in FIG. 5;
FIG. 7 is a schematic structural diagram of an embodiment of the camera module shown in FIG. 5;
FIG. 8 is a schematic structural diagram of an embodiment of the control motherboard in FIG. 5;
fig. 9 is a schematic structural diagram of an embodiment of the laser emitting device in fig. 5.
The reference numbers illustrate:
reference numerals Name (R) Reference numerals Name (R)
100 Obstacle detection device 141 Mounting plane
110 Camera module 142 Connection plane
111 Camera head 143 Abdication through hole
1111 Fixing plate 144 Avoiding groove
1112 Lens barrel 145 Locating slot
112 Flexible circuit board 146 Wire passage
120 Laser emitting device 147 Buckle hook
121 Stop bulge 148 Mounting hole
130 Control mainboard 150 Base seat
131 Buckle hole 151 Positioning projection
132 Avoiding hole 152 Abutting plane
140 Mounting bracket 153 Limiting part
The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.
In addition, the descriptions related to "first", "second", etc. in the present invention are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should be considered to be absent and not within the protection scope of the present invention.
The application provides an obstacle detection device, this obstacle detection device can be applied to intelligent robot, like the robot of sweeping the floor, drag the robot that cleans the floor, drag and sweep integrative robot etc. this obstacle detection device can detect the barrier more comprehensively, accurately.
Referring to fig. 1, the obstacle detection apparatus 100 includes a camera module 110, a laser emitting device 120, and a control main board 130.
Referring to fig. 2, the camera module 110 includes at least three cameras 111, and the at least three cameras 111 are distributed along the circumference of the laser emitting device 120. At least three cameras 111 can be uniformly distributed along the circumferential direction of the laser emitting device 120, that is, the intervals between two adjacent cameras 111 are equal; the at least three cameras 111 may also be non-uniformly distributed along the circumferential direction of the laser emitting device 120, that is, the intervals between two adjacent cameras 111 are not equal.
By way of example and not limitation, when the at least three cameras 111 are distributed along the circumferential direction of the laser emitting device 120, the heights of the at least three cameras 111 in the up-down direction are equivalent, that is, the heights of the at least three cameras 111 in the up-down direction are the same or within an allowable size range, and the size error may be within 1 mm, within 2 mm, within 3 mm, and the like, which is not specifically limited herein.
It should be noted that each camera 111 has a certain angle for receiving light in the up-down direction. By way of example and not limitation, each camera 111 can cover the height of the intelligent robot at the angle of receiving light in the up-down direction, a large size error is allowed if the angle of receiving light in the up-down direction of the camera 111 is relatively large, and the size error can be set to be smaller if the angle of receiving light in the up-down direction of the camera 111 is relatively small.
Referring to fig. 2 and fig. 3, each camera 111 has a certain angle for receiving light in the horizontal direction, and because the angle for receiving light in the horizontal direction of each camera 111 is limited, the light incident surfaces of two adjacent cameras 111 are arranged at an included angle greater than 90 degrees and less than 180 degrees, that is, the light incident surfaces of two adjacent cameras 111 can be arranged at angles of 100 degrees, 110 degrees, 120 degrees, 130 degrees, 140 degrees, 150 degrees, 160 degrees, 170 degrees and other angles.
Because the light incident surfaces of the two adjacent cameras 111 form an included angle, the two adjacent cameras 111 can receive light from different directions, and further the angle of the at least three cameras 111 receiving light in the horizontal direction can be the sum of the angles of the three cameras 111 receiving light in the horizontal direction, so that the at least three cameras 111 can cover a relatively large area.
It is worth noting that the larger the included angle between the light incident surfaces of the two adjacent cameras 111 is, the more the overlapping regions of the two adjacent cameras 111 receiving light in the horizontal direction are, so that the regions of the two adjacent cameras 111 receiving light in the horizontal direction are smaller, and thus, the blind area existing in the two adjacent cameras 111 is smaller, and even no blind area exists. On the contrary, the smaller the included angle between the light incident surfaces of two adjacent cameras 111 is, the less the overlapping of the areas of the two adjacent cameras 111 receiving light in the horizontal direction is, the larger the area covered by the two adjacent cameras 111 in the horizontal direction is, but the blind area existing in the two adjacent cameras 111 is larger.
In some embodiments, each camera 111 can cover the height of the intelligent robot in the up-down direction receiving area, and therefore, the number of the cameras 111 is mainly set according to the angle of each camera 111 receiving light in the horizontal direction, and the number of the cameras 111 may be three, four, five or even more cameras 111.
In some embodiments, two adjacent cameras 111 are arranged in a staggered manner in the up-down direction, the camera 111 located above can be arranged in an upward inclined manner, and the camera 111 located below can be arranged in the downward direction, so that the area where two adjacent cameras 111 receive light in the up-down direction is larger, and the area where two adjacent cameras 111 receive light in the up-down direction can cover the height of the intelligent robot.
In some embodiments, the angle of the light received by each camera 111 in the horizontal direction is to cover the width of the intelligent robot in the horizontal direction, so as to ensure that the obstacle detection device 100 can detect the obstacle in the traveling direction of the intelligent robot.
There are various ways in which the camera 111 is fixedly mounted on the mounting bracket 140, and the camera 111 may be mounted on the mounting bracket 140 by a connector such as a screw, a clip, or a buckle, and how to fixedly mount the camera 111 on the mounting bracket 140 is not limited herein.
The laser emitting device 120 may be mounted on the intelligent robot or an adapter for carrying the laser emitting device 120 through a connector such as a screw, a clip, a buckle, etc., and the manner how the laser emitting device 120 is fixed on the intelligent robot or the adapter is not particularly limited herein.
The light emitted by the laser emitting device 120 is radial, that is, the light emitted by the laser emitting device 120 has a certain angle in the horizontal direction and also has a certain angle in the vertical direction, in some embodiments, the width covered by the light emitted by the laser emitting device 120 in the horizontal direction is greater than or equal to the width of the intelligent robot, and the height covered by the light emitted by the laser emitting device 120 in the vertical direction is greater than or equal to the height of the intelligent robot.
The laser emitting device 120 may be installed above the plurality of cameras 111, and the laser emitting device 120 may also be installed below the plurality of cameras 111, which is not limited herein.
The laser emitting device 120 is located above a midpoint position of a connecting line of the at least three cameras 111 along the horizontal direction, that is, the laser emitting device 120 is located at a midpoint position of a connecting line of the light incident surfaces of the at least three cameras 111 along the horizontal direction, and the connecting line of the light incident surfaces of the at least three cameras 111 along the horizontal direction refers to a connecting line formed by sequentially connecting the light incident surfaces of the at least three cameras 111 in the first place according to the arrangement sequence, please refer to fig. 2 and fig. 3, and the light incident surfaces of the cameras 111 are connected by straight lines to form a broken line segment close to a U shape. Of course, if the light incident surface of each camera 111 is an arc surface, the light incident surfaces of the cameras 111 are connected by an arc, that is, the light incident surfaces of the cameras 111 are connected to form an arc segment.
The laser emitting device 120 is located above the middle point of the connecting line of the at least three cameras 111 along the horizontal direction, that is, the projection of the laser emitting device 120 from top to bottom is located at the middle point of the connecting line of the at least three cameras 111, the laser emitting device 120 may be located directly above the cameras 111, the laser emitting device may also be located above the position between two adjacent cameras 111, and the laser emitting device 120 may also be slightly offset from the position directly above the middle point of the connecting line of the at least three cameras 111.
Preferably, the number of the cameras 111 is (2N +1), N is a positive integer greater than 0, and when the (2N +1) cameras 111 are uniformly arranged, the (2N +1) cameras 111 are numbered sequentially from head to tail, and at this time, the laser emitting device 120 is located above the (N +1) camera 111.
Similarly, when the number of the cameras 111 is (2N +4), N is a positive integer greater than 0, and when the (2N +4) cameras 111 are uniformly arranged, (2N +4) cameras 111 are numbered sequentially from head to tail, and at this time, the laser emitting device 120 is located above a position between the (N +2) camera 111 and the (N +3) camera 111.
This control mainboard 130 is connected with each camera 111 and laser emission device 120 electricity, and this control mainboard 130 can pass through the wire with camera 111 and laser emission device 120 and be connected, and this control mainboard 130 can also be connected through wireless communication module with camera 111 and laser emission device 120, like bluetooth, WIFI etc..
Preferably, the control main board 130 is electrically connected with the camera 111 and the laser emitting device 120 through wires, so that the camera 111 and the laser emitting device 120 can be powered through the control main board 130, which is beneficial to simplifying the structures of the camera 111 and the laser emitting device 120.
There are many ways to fix the control main board 130 to the mounting bracket 140, the control main board 130 may be locked to the mounting bracket 140 by screws, the control main board 130 may be fixed to the mounting bracket 140 by a snap connection, and the control main board 130 may be fixed to the mounting bracket 140 by other ways, which are not limited herein.
When the obstacle detection device 100 is equipped to an intelligent robot, the control main board 130 of the obstacle detection device 100 controls the laser emitting device 120 to work to emit laser towards a specified direction, each camera 111 of the obstacle detection device 100 is used for receiving the laser reflected by an obstacle in the specified direction, the camera 111 receives the reflected laser, namely, the camera 111 represents that an obstacle is located at a position where the camera 111 is located, the camera 111 does not receive the reflected laser, namely, the camera 111 represents that no obstacle is located at the position where the camera 111 is located, and each camera 111 sends information corresponding to the received laser to the control main board 130, so that the obstacle detection device can realize obstacle detection.
In the obstacle detection device 100 of the present application, the laser emitting device 120 and the at least three cameras 111 are mounted on the mounting bracket 140, the at least three cameras 111 are distributed along the circumferential direction of the mounting bracket 140, the light incident surfaces of two adjacent cameras 111 are arranged at an included angle larger than 90 degrees and smaller than 180 degrees in the horizontal direction, so that two adjacent cameras 111 can cover a certain range of area in the horizontal direction, the arrangement of the multiple cameras 111 can reduce the blind area of obstacle detection, even avoid the blind area of obstacle detection, i.e., the obstacle detecting device 100 can detect a wider area, so that an obstacle can be detected by one obstacle detecting device 100, in addition, the intelligent robot provided with the obstacle detection device 100 can better avoid obstacles in the advancing process, and is convenient for the intelligent robot to realize accurate image building according to the detection result of the obstacle detection device 100.
In some embodiments of the present invention, considering that the laser emitting device 120 has a certain light emitting angle in the horizontal direction, the laser emitting device 120 has a certain light emitting angle in the up-down direction, the areas of the cameras 111 receiving light in the up-down direction may be independent of each other, and the areas of the cameras 111 receiving light in the horizontal direction may be overlapped. If the angle of the light received by each camera 111 in the up-down direction is smaller than the light emitting angle of the laser emitting device in the up-down direction, the camera 111 may not receive the light reflected by the obstacle; if the sum of the angles of the light received by the cameras 111 in the horizontal direction is smaller than the light emitting angle of the laser emitting device in the horizontal direction, the cameras 111 may not receive the light reflected by the obstacle.
In view of the above, the sum of the angles at which the at least three cameras 111 receive light in the horizontal direction is set to be greater than or equal to the light emission angle of the laser emission device 120 in the horizontal direction, and the angle at which each camera 111 receives light in the up-down direction is set to be greater than or equal to the light emission angle of the laser emission device 120 in the up-down direction. So set up, can reduce or even eliminate the detection blind area of obstacle detection device 100 to can ensure to be received by the camera 111 of the corresponding position by the light homoenergetic that the barrier reflected back, and then be favorable to guaranteeing this obstacle detection device 100's detection precision.
By way of example and not limitation, referring to fig. 2 and 3, the light emitting angle of the laser emitting device in the horizontal direction is 120 degrees, the light emitting angle of the laser emitting device 120 in the up-down direction is 30 degrees, the number of the cameras 111 is three, the angles of the three cameras 111 receiving light in the up-down direction are greater than 30 degrees, and the sum of the angles of the three cameras 111 receiving light in the horizontal direction is greater than 120 degrees.
The angles of the three cameras 111 receiving light in the up-down direction may all be 40 degrees, 50 degrees and other angles, the angles of the three cameras 111 receiving light in the up-down direction may be equal, and the angles of the three cameras 111 receiving light in the up-down direction may also be different, which is not limited specifically herein.
The angles of the three cameras 111 receiving the light in the horizontal direction may all be 45 degrees, 50 degrees, and other angles, the angles of the three cameras 111 receiving the light in the horizontal direction may be equal, and the angles of the three cameras 111 receiving the light in the horizontal direction may also be different, which is not specifically limited herein.
In order to facilitate the fixed installation of the plurality of cameras 111, in some embodiments of the present invention, referring to fig. 1 and 4, the obstacle detection apparatus 100 further includes a mounting bracket 140, where the mounting bracket 140 provides a mounting position for the plurality of cameras 111, so that only the mounting bracket 140 needs to be fixedly installed on the intelligent robot.
The shape of the mounting bracket 140 is various, and the mounting bracket 140 may have a cylindrical shape, a spherical shape, and other shapes, and is not particularly limited herein. Considering that the mounting bracket 140 is used for mounting the camera module 110 and the laser emitting device 120, preferably, the mounting bracket 140 is arranged in a polygonal column shape, and the side surfaces of the mounting bracket 140 are flat, so as to facilitate the mounting of the camera module 110 and the laser emitting device 120.
The mounting bracket 140 can be made of various materials, and the mounting bracket 140 can be made of metal, plastic or other high-strength materials. Preferably, the mounting bracket 140 is made of a metal material, especially metal aluminum, metal copper, etc. with good heat dissipation performance, so as to facilitate heat dissipation of the camera module 110, the laser emitting device 120 and the main control board mounted on the mounting bracket 140.
In consideration of the fact that after the cameras 111 are mounted on the mounting bracket 140, it is necessary to ensure that the light incident surfaces of two adjacent cameras 111 form an included angle greater than 90 degrees and less than 180 degrees, that is, after the cameras 111 are mounted on the mounting bracket 140, the included angle between the light incident surfaces of two adjacent cameras 111 needs to be debugged, which results in a complex mounting procedure of the cameras 111. In view of the above problem, in some embodiments of the present invention, referring to fig. 4, the mounting bracket 140 has at least three mounting planes 141 distributed along a circumferential direction thereof, two adjacent mounting planes 141 are disposed at an included angle greater than 90 degrees and less than 180 degrees, each camera 111 is exposed from the corresponding mounting plane 141, and the mounting plane 141 located at a middle position of the laser emitting device 120 located in the at least three mounting planes 141 is exposed.
When the cameras 111 are installed, only the light incident surface of each camera 111 needs to be adjusted to be parallel to the corresponding installation plane 141, so that each camera 111 is exposed from the installation plane 141 corresponding to the corresponding position, and the included angle between the light incident surfaces of two adjacent cameras 111 can be ensured to be larger than 90 degrees and smaller than 180 degrees, so that each camera 111 is conveniently installed on the installation support 140.
When the laser emitting device 120 is mounted, if the number of the mounting planes 141 is (2N +1), (2N +1) mounting planes 141 are sequentially numbered, and at this time, the laser emitting device 120 is mounted on the mounting plane 141 numbered N +1, and if the number of the mounting planes 141 is (2N +4), (2N +4) mounting planes 141 are sequentially numbered, and at this time, the laser emitting device 120 is mounted at a junction between the mounting plane 141 numbered (N +2), or the mounting plane 141 numbered (N +3), or the mounting plane 141 numbered (N +2), and the mounting plane 141 numbered (N + 3). This facilitates the mounting of the laser emitting device 120 on the mounting bracket 140.
It should be noted that, in the above embodiments, there are various ways in which the cameras 111 are exposed to the corresponding mounting planes 141, for example, the cameras 111 are directly and fixedly mounted on the corresponding mounting planes 141, and further, for example, each mounting plane 141 is concavely provided with a groove for accommodating the camera 111, so that the camera 111 mounted in the groove can be exposed to the mounting plane 141, and for example, each camera 111 passes through the mounting bracket 140 and is exposed from the corresponding mounting plane 141, what way the camera 111 is exposed to the corresponding mounting plane 141 is not listed here.
In some embodiments of the present invention, each camera 111 is fixedly mounted on a corresponding mounting plane 141. Specifically, each camera 111 has an abutting surface disposed opposite to the light incident surface, and the abutting surface is disposed parallel to the light incident surface. When each camera 111 is mounted, only the abutting surface of each camera 111 needs to be attached to the corresponding mounting plane 141, which further facilitates the mounting of each camera 111 and is beneficial to improving the assembly efficiency of the camera 111 and the mounting bracket 140.
Further, the cameras 111 are connected through soldering of the bonding pads, the bonding pads can connect the cameras 111 in series, the bonding pads can connect the cameras 111 in parallel, the bonding pads are not specifically limited, the bonding pads connecting the two adjacent cameras 111 are tightly attached to the mounting plane 141, and therefore the situation that the surfaces of the obstacle detection devices 100 are scattered and are used for connecting wires of the cameras 111 can be avoided, and the surfaces of the obstacle detection devices 100 are tidier.
Further, the mounting bracket 140 further has a connecting plane 142, the connecting plane 142 is used for connecting two mounting planes 141 located at both ends of the mounting bracket 140 in the circumferential direction, among the at least three mounting planes 141, and the control master is mounted on the mounting bracket 140 and abuts against the connecting plane 142.
Preferably, the panel surface of the control main board 130 is larger than the connecting plane 142, so that two opposite sides of the control main board 130 can protrude from the corresponding sides of the connecting plane 142, and two cameras 111 located at two ends of the mounting bracket 140 in the circumferential direction of the at least three cameras 111 are electrically connected to the control main board 130 through soldering pads, so that the cameras 111 are electrically connected to the control main board 130, and the whole obstacle detecting device 100 is more compact in structure.
In some embodiments of the present invention, each camera 111 passes through the mounting bracket 140 and emerges from the corresponding sub-mounting surface. Specifically, referring to fig. 4 to 6, the mounting bracket 140 further has a connecting plane 142, the connecting plane 142 is used for connecting two mounting planes 141 located at two ends of the mounting bracket 140 in the circumferential direction of the mounting bracket, each sub-mounting surface is recessed with an abdicating through hole 143 penetrating through the connecting plane 142, the obstacle detection apparatus 100 further includes a base 150, the base 150 is connected with the mounting bracket 140 and abuts against the connecting plane 142, one end of each camera 111 is limited between the base 150 and the connecting plane 142, and the other end of each camera 111 extends out of the corresponding abdicating through hole 143.
It should be noted that there are many ways of connecting the base 150 and the mounting bracket 140. For example, the base 150 and the mounting bracket 140 are bonded by glue, and the process of glue bonding is simple, so that the assembly efficiency between the base 150 and the mounting bracket 140 can be improved. For another example, the base 150 and the mounting bracket 140 are connected by a snap, and the snap connection has the advantages of being convenient and fast to disassemble and assemble, so that the assembling efficiency between the base 150 and the mounting bracket 140 can be improved, and the base 150 and the mounting bracket 140 can be disassembled conveniently, thereby being beneficial to maintaining or replacing the camera 111. It is understood that the base 150 and the mounting bracket 140 may be connected and fixed in other manners, which should not be construed as an example.
Further, referring to fig. 7, the camera 111 includes a fixing plate 1111 and a lens 1112 fixedly connected to the fixing plate 1111, and the fixing plate 1111 may be a plate structure made of steel plate, copper plate, or other materials, which is not limited herein. The lens 1112 and the fixing plate 1111 may be directly connected by screws, rivets and other connectors, the area of the plate surface of the fixing plate 1111 is larger than the abdicating through hole 143, when the fixing plate 1111 is disposed between the base 150 and the connecting plane 142, the fixing plate 1111 abuts against the periphery of the abdicating through hole 143, and the lens 1112 may extend through the abdicating through hole 143 and be exposed from the corresponding sub-mounting surface. By the arrangement, the cameras 111 can be conveniently positioned and installed.
Furthermore, the connection plane 142 is concavely provided with an avoiding groove 144, the avoiding groove 144 is used for accommodating the base 150, at this time, the fixing plate 1111 of each camera 111 is limited between the base 150 and the groove bottom of the avoiding groove 144, and one end of each lens 1112 far away from the fixing plate 1111 extends out of the corresponding abdicating through hole 143. So set up for fixed plate 1111 all receives the restraint in all directions, thereby makes things convenient for fixed plate 1111 fixed, and then has the fixed mounting of the camera 111 of being convenient for. In addition, the lens 1112 and the fixing plate 1111 are hidden inside the mounting bracket 140, so that the interference of external factors on the operation of each camera 111 can be avoided.
In order to facilitate the positioning between the base 150 and the avoiding groove 144, please refer to fig. 4 and 5 together, the base 150 is convexly provided with a plurality of positioning protrusions 151, the plurality of positioning protrusions 151 are distributed along the periphery of the base 150, the plurality of positioning protrusions 151 can be uniformly distributed along the periphery of the base 150, the plurality of positioning protrusions 151 can also be only arranged on two sides of the base 150 which are oppositely arranged, the connecting plane 142 is concavely provided with a plurality of positioning grooves 145 communicated with the avoiding groove 144, the positions of the plurality of positioning grooves 145 and the positions of the plurality of positioning protrusions 151 are arranged in a one-to-one correspondence manner, and each positioning groove 145 is matched with the positioning protrusion 151 at the corresponding position. So set up, on the one hand can play the effect of preventing staying when base 150 assembles with installing support 140, on the other hand still makes the equipment location of base 150 and installing support 140 more swift.
Further, at least two positioning protrusions 151 in the positioning protrusions 151 have different shapes, and the shape of the positioning groove 145 corresponding to the position is matched with the shape of the positioning protrusion 151 corresponding to the position, so that the fool-proof effect can be further achieved, and the base 150 can be conveniently matched with the avoiding groove 144.
It should be noted that when the lens 1112 extends out of the corresponding abdicating through hole 143 and is exposed from the corresponding mounting plane 141, the light incident surface of the lens 1112 is parallel to the mounting plane 141 at the corresponding position, in order to simplify the mounting process of the camera 111, the base 150 has at least three abutting planes 152 arranged along the circumference thereof, each abutting plane 152 on the base 150 is arranged parallel to the mounting plane 141 at the corresponding position on the mounting bracket 140, and the shape of the avoiding groove 144 is adapted to the shape of the base 150, that is, a plurality of groove walls of the avoiding groove 144 facing the base 150 are respectively arranged parallel to the abutting planes 152 at the corresponding position. So when installing camera 111, only need guarantee the butt plane 152 butt on the face base 150 of fixed plate 1111, another face of fixed plate 1111 with dodge the cell wall butt that recess 144 corresponds the position can, this just makes camera 111 fixed mounting back, just need not to adjust each camera lens 1112 for camera lens 1112 and the direct equipment of installation are simpler, swift.
Further, referring to fig. 5, the mounting bracket 140 is further provided with a line passing channel 146 communicated with the avoiding groove 144, the camera module 110 further includes a flexible circuit board, the flexible circuit board 112(FPC) is used for electrically connecting the lenses 1112 of the cameras 111, the flexible circuit board further extends out of the avoiding groove 144 through the line passing channel 146, so that the dispersed cameras 111 can be integrated into a whole through the flexible circuit board, and meanwhile, the flexible circuit board 112 is electrically connected with the lenses 1112 of the cameras 111, which is also convenient for electrically connecting the flexible circuit board with the control main board 130.
It should be noted that the flexible circuit board 112 generally has a certain width, and therefore the width of the wire channel 146 is at least equal to the width of the flexible circuit board 112, which affects the position limitation of the fixing plate 1111 of the camera 111 adjacent to the wire channel 146, and in view of this, referring to fig. 6, a position limitation portion 153 is convexly disposed on the surface of the base 150 facing the fixing plate 1111, and the position limitation portion 153 extends along the edge of the base 150, so as to limit the side of the fixing plate 1111 adjacent to the wire channel 146, thereby preventing the fixing plate 1111 from falling off from the wire channel 146.
In order to make the structure of the obstacle detecting device 100 more compact, please refer to fig. 4 and 8, the connecting plane 142 is further provided with a plurality of hooks 147, the plurality of hooks 147 may be arranged along the periphery of the connecting plane 142, and the plurality of hooks 147 may also be arranged on two opposite sides of the connecting plane 142, which is not limited herein. The control main board 130 is correspondingly provided with a plurality of fastening holes 131, and each fastening hole 131 is fastened and matched with the fastening hook 147 at a corresponding position, so that the control main board 130 is abutted against the connecting plane 142 and covers the avoiding groove 144. With such an arrangement, on the one hand, the obstacle detection device 100 is compact, and on the other hand, the base 150 can be further limited, so that the base 150 is fixed more firmly.
Further, the surface of the base 150 facing the control main board 130 is concavely provided with a clearance groove, the clearance groove not only reduces the contact area between the base 150 and the control main board 130, which is beneficial to the heat dissipation of the main control board, but also can accommodate electronic components on the control main board 130, thereby being beneficial to the main control board to be mounted on the mounting bracket 140.
In some embodiments, the laser emitting device 120 is configured to emit a light toward the front end of the intelligent robot in the traveling direction, the light emitted by the laser emitting device 120 needs to cover the ground in the traveling direction of the intelligent robot and also needs to cover an area higher than the intelligent robot, because the laser emitting device 120 has a certain light emitting angle in the up-down direction, if the center line of the light emitted by the laser emitting device 120 propagates in the horizontal direction, a part of the light above the center line is wasted, in view of this, referring to fig. 1, the laser emitting device 120 is tilted in the up-down direction, i.e. the center line of the laser emitting device 120 can be set up upward or downward, the center line of the laser emitting device 120 is set up upward or downward depending on the application scenario of the obstacle detecting device 100, if the obstacle detecting device 100 is mainly used for detecting an obstacle above the intelligent robot, the center line of the laser emitting device 120 is disposed upward, and if the obstacle detecting device 100 is mainly used for detecting an obstacle under the intelligent robot, the center line of the laser emitting device 120 is disposed downward.
The laser emitting device 120 is disposed in an inclined manner in the up-down direction, that is, an included angle is formed between the center line of the laser emitting device 120 and the horizontal plane, preferably, the center line of the laser emitting device 120 and the horizontal plane is disposed at an angle of 0-30 degrees, and the center line of the laser emitting device 120 and the horizontal plane can be disposed at an angle of 0 degree, 5 degrees, 10 degrees, 15 degrees, 20 degrees, 25 degrees, 30 degrees or other angles, so that the light emitted by the laser emitting device 120 can be transmitted to the ground in the traveling direction of the intelligent robot and the area higher than the intelligent robot as much as possible, and thus, an obstacle located in the traveling direction of the intelligent robot can reflect more light to the camera 111, thereby facilitating improvement of the detection accuracy of the obstacle detecting device 100.
Further, referring to fig. 1, 4 and 9, the laser emitting device 120 is disposed in a long strip shape, the mounting bracket 140 is provided with a mounting hole 148 through which the laser emitting device 120 is fitted, an axis of the mounting hole 148 is inclined from top to bottom, the axis of the mounting hole 148 is disposed at an angle of 0-30 degrees with respect to a horizontal plane, and an included angle between the axis of the mounting hole 148 and the horizontal plane is determined by an included angle between a center line of the laser emitting device and the horizontal plane. With such an arrangement, the included angle between the central line of the laser emitting device 120 and the horizontal plane can be determined only by fixedly installing the laser emitting device 120 in the installation hole 148, so that the inclination angle of the laser emitting device 120 does not need to be adjusted, and the installation efficiency of the laser emitting device 120 is further improved.
Further, considering that the obstacle detection apparatus 100 may be installed on an intelligent robot, if the laser emitting apparatus 120 is disposed in a cylindrical shape and the installation hole 148 is correspondingly formed in a circular hole, the laser emitting apparatus 120 may rotate relative to the installation bracket 140 when the intelligent robot bumps, which may affect the operation of the laser emitting apparatus 120, in view of this, referring to fig. 3, the cross section of the installation hole 148 is disposed in a non-circular shape, such as an oval shape, a waist shape, a quadrilateral shape, etc., and the shape of the cross section of the laser emitting apparatus 120 is adapted to the shape of the installation hole 148, so that the laser emitting apparatus 120 may be prevented from rotating relative to the installation bracket 140.
Further, referring to fig. 5 and 9, the laser emitting device 120 is provided with stop protrusions 121 at both ends in the length direction, and the stop protrusions 121 are respectively abutted against the outer edges of the corresponding ends of the mounting hole 148, so that the laser emitting device 120 can be prevented from falling off from the mounting hole 148.
Further, referring to fig. 9, the main control board is provided with an avoiding hole 132 for the laser emitting device 120 to pass through, so that the main control board is prevented from affecting the installation of the laser emitting device 120, and the assembly of the obstacle detecting device 100 is facilitated.
The utility model provides an intelligent robot, which comprises a robot body and an intelligent detection device, wherein the robot body comprises a shell, a controller, a driving motor, a driving wheel and other components, the robot body can walk on the ground, the obstacle detection device 100 is installed on the shell and is electrically connected with the controller, the specific structure of the obstacle detection device 100 refers to the above embodiments, and as the intelligent robot adopts all the technical schemes of all the above embodiments, the intelligent robot at least has all the beneficial effects brought by the technical schemes of the above embodiments, and the detailed description is omitted.
The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the technical solutions of the present invention, which are made by using the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (15)

1. The obstacle detection device is characterized by comprising a camera module, a laser emitting device and a control main board; wherein,
the camera module comprises at least three cameras, the at least three cameras are distributed along the circumferential direction of the laser emitting device, and the light incident surfaces of two adjacent cameras form an included angle which is larger than 90 degrees and smaller than 180 degrees in the horizontal direction;
the laser emitting device is positioned above or below the at least three cameras;
the control mainboard is electrically connected with the laser emitting device and at least three cameras.
2. The obstruction detection device of claim 1, wherein a sum of angles at which each of the cameras receives the light source in the horizontal direction is greater than or equal to an angle at which the laser emission device emits the light source in the horizontal direction, and an angle at which the camera receives the light source in the vertical direction is greater than or equal to an angle at which the laser emission device emits the light source in the vertical direction.
3. The obstruction detection device according to claim 1, further comprising a mounting bracket having at least three mounting planes distributed along a circumferential direction thereof, wherein an included angle between two adjacent mounting planes is greater than 90 degrees and less than 180 degrees, each camera is exposed from the corresponding mounting plane, and the laser emitting device is exposed from a middle position of the at least three mounting planes.
4. The obstruction detection device according to claim 3, wherein the camera has an abutment surface disposed opposite to the light incident surface, the abutment surface of the camera is disposed parallel to the light incident surface of the camera, and the abutment surface of the camera abuts against the mounting plane.
5. The obstruction detection device of claim 3, wherein the mounting bracket has a connection plane for connecting two of the at least three mounting planes at opposite ends, each mounting plane being recessed with an abdicating through-hole passing through the connection plane;
the obstacle detection device further comprises a base, wherein the base is connected with the mounting bracket and abutted against the connecting plane;
one end of each camera is limited between the base and the connecting plane, and the other end of each camera extends out of the corresponding yielding through hole.
6. The obstacle detection device according to claim 5, wherein the camera includes a fixing plate and a lens, a plate surface of the fixing plate is larger than a cross section of the abdicating through hole, the fixing plate is limited between the base and the connection plane, one end of the lens is fixedly connected with the fixing plate, and the other end of the lens extends out of the abdicating through hole.
7. An obstacle detecting apparatus according to claim 6, wherein the connecting plane is recessed with an escape groove for accommodating the base;
the fixed plate of each camera is located between the base and the groove wall of the avoiding groove, and the lens of each camera extends out of the corresponding avoiding through hole.
8. The obstruction detection device according to claim 7, wherein a plurality of positioning protrusions are protruded from a periphery of the base, a plurality of positioning grooves communicating with the escape groove are concavely provided in the connection plane, and each of the positioning grooves is engaged with a positioning protrusion at a corresponding position.
9. The obstacle detecting device according to claim 7, wherein the base has at least three abutting planes arranged along a circumferential direction thereof, at least three abutting planes are provided in one-to-one correspondence with at least three mounting planes, so that the abutting planes and the mounting planes at corresponding positions are arranged in parallel with each other, the shape of the avoiding groove is adapted to the shape of the base, and the fixing plate of the camera is installed between the abutting planes and the groove walls at corresponding positions of the avoiding groove.
10. The obstacle detecting device according to claim 7, wherein the mounting bracket is provided with a line passing channel communicating with the avoiding groove, the camera module further includes a flexible circuit board electrically connected to a lens of the camera, and the flexible circuit board further protrudes out of the avoiding groove through the line passing channel.
11. The obstruction detection device of claim 10, wherein a surface of the base adjacent to the fixation plate is provided with a limit portion, the limit portion extending along a periphery of the base.
12. The obstacle detection device according to claim 7, wherein the connection plane is provided with a plurality of hooks, the control main board is correspondingly provided with a plurality of hook holes, and each of the hook holes is fastened with the corresponding hook, so that the control main board is abutted against the connection plane and covers the avoiding groove.
13. The obstruction detection device according to claim 1, wherein a center line of the laser emitting device is disposed obliquely.
14. An obstacle detecting apparatus according to claim 3, wherein both ends of the laser emitting apparatus in the longitudinal direction thereof are provided with stopper projections which abut against the surface of the mounting bracket.
15. An intelligent robot comprising a machine body and an obstacle detection device according to any one of claims 1 to 14, the obstacle detection device being mounted to the machine body.
CN202121448946.6U 2021-06-28 2021-06-28 Obstacle detection device and intelligent robot Active CN215494127U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113325426A (en) * 2021-06-28 2021-08-31 深圳市银星智能科技股份有限公司 Obstacle detection device and intelligent robot

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113325426A (en) * 2021-06-28 2021-08-31 深圳市银星智能科技股份有限公司 Obstacle detection device and intelligent robot

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