CN216209896U - Scanning device for laser radar and laser radar - Google Patents

Abstract

A scanning device for a laser radar, the scanning device comprising a resonant motor and a scanning mirror; the resonance motor comprises a rotor and a stator; the rotor deflects to a preset position around a self-balancing position of a rotating shaft; the stator includes: a return assembly adapted to return the rotor to the equilibrium position about the axis of rotation; the scanning mirror is suitable for reflecting light beams to perform optical scanning; the scanning mirror is connected with the resonant motor to realize the reciprocating swing of the scanning mirror. The scanning device can realize the reciprocating swing of the scanning mirror with higher frequency and larger amplitude with relatively smaller driving power, is favorable for realizing the reciprocating swing of the scanning mirror with low power consumption and large angle under certain frequency, and is favorable for overcoming the problem of limited scanning field range of the laser radar caused by undersize of the scanning mirror.

Description

Scanning device for laser radar and laser radar

Technical Field

The utility model relates to the field of laser radars, in particular to a scanning device for the laser radar and the laser radar.

Background

Laser radar is a range finding sensor commonly used, has characteristics such as detection range is far away, resolution ratio is high, receive environmental disturbance little, and the wide application is in fields such as unmanned driving, intelligent robot, unmanned aerial vehicle. In recent years, the automatic driving technology has been rapidly developed, and the laser radar has become indispensable as a core sensor for distance sensing.

In the laser radar, a light beam is reflected by a reflection surface of a scanning device, thereby forming a light beam for scanning. One type of scanning device for a laser radar employs a galvanometer, and scanning is achieved by reciprocating movement of a reflecting surface of the galvanometer. In order to obtain higher scanning frequency, the scanning device in the laser radar often adopts a MEMS galvanometer.

Due to the limitation of the manufacturing process, the driving force of the MEMS galvanometer is limited, and the area of the reflecting surface which can be driven is relatively small, so that the scanning field of view which can be achieved by a single MEMS galvanometer is often not enough to meet the field angle requirement of the laser radar, and the arrangement of a plurality of MEMS galvanometers also provides quite high requirements for the manufacturing precision and the assembling precision of the galvanometers.

On the other hand, the voice coil motor is a direct drive motor, which can directly convert electric energy into mechanical energy for linear motion without any intermediate conversion mechanism. Voice coil motors are well suited for reciprocating motion and are relatively simple in design. The voice coil motor is used for driving a small-inertia load, performs reciprocating swing in a limited corner, has the advantages of small size, light weight, convenience in installation, high control precision and the like, and is widely applied to the fields of disk drivers and the like.

However, due to the principle and characteristics of the driver, when the reciprocating frequency of the scanning mirror is increased (not lower than 10Hz) and the reciprocating amplitude is increased (the scanning angle is greater than 20 degrees), the voice coil motor often needs higher driving power, which affects the application of the voice coil motor in the laser radar.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a scanning device for a laser radar and the laser radar, so as to realize the driving of the scanning mirror with low power consumption and large-angle reciprocating swing and enlarge the area of the scanning mirror.

In order to solve the above problems, the present invention provides a scanning device for a laser radar, comprising a resonant motor and a scanning mirror; the resonance motor comprises a rotor and a stator; the rotor deflects to a preset position around a self-balancing position of a rotating shaft; the stator includes: a return assembly adapted to return the rotor to the equilibrium position about the axis of rotation; the scanning mirror is suitable for reflecting light beams to perform optical scanning; the scanning mirror is connected with the resonant motor to realize the reciprocating swing of the scanning mirror.

Optionally, the resonant motor includes: the magnetic ring comprises a plurality of pairs of magnets which are distributed along the circumferential direction; the coil assembly comprises a plurality of winding coils which are distributed along the circumferential direction of the magnetic ring.

Optionally, a plurality of winding coils of the coil assembly are located on the outer periphery of the magnetic ring and distributed around the magnetic ring.

Optionally, the restoring assembly is located on a side of the coil assembly away from the magnetic ring.

Optionally, a plurality of winding coils of the coil assembly are located on an inner circumference of the magnetic ring, and the magnetic ring surrounds the plurality of winding coils.

Optionally, the restoring assembly is located on a side of the magnetic ring away from the coil assembly.

Optionally, the rotor includes the magnetic ring, and the stator includes the coil assembly.

Optionally, the rotor is driven by a first action to deflect around the rotating shaft from the equilibrium position to the preset position, where the first action is an interaction between a current transmitted in a winding coil in the coil group and a magnetic field of the magnetic ring.

Optionally, the reply component includes: at least one magnetic part; the rotor is driven to return to the equilibrium position around the rotating shaft at least under a second action, wherein the second action comprises interaction between a magnetic field of the magnetic part and a magnetic field of the magnetic ring.

Optionally, the magnet corresponding to the magnetic portion and the magnetic portion attract each other, so that the magnetic ring is kept at the equilibrium position.

Optionally, when the rotor deflects to a preset position, the current transmitted in the winding coil in the coil assembly is cut off, and the rotor is driven by the second action to return to the equilibrium position.

Optionally, when the rotor deflects to a preset position, the current transmitted in the winding coils in the coil assembly is cut off and a reverse current is input to the winding coils in the coil assembly, and the rotor is driven by the first action and the second action together to return to the equilibrium position.

Optionally, the reply assembly further includes: an excitation coil adapted to adjust a magnetic field of the corresponding magnetic portion such that the restoring assembly forms a predetermined effective magnetic field.

Optionally, the method further includes: a detection unit adapted to detect an effective magnetic field of the return assembly; and the adjusting unit is used for controlling the exciting coil to adjust the magnetic field of the magnetic part based on the detection result of the detecting unit so as to enable the restoring assembly to form a preset effective magnetic field.

Optionally, the method further includes: the counterweight is positioned on one side of the rotor, which is far away from the scanning mirror, so that the center of gravity of the rotor, the scanning mirror and the counterweight is positioned at the position of the rotating shaft.

Optionally, the number of the scanning mirrors is one or more, and the one or more scanning mirrors are arranged opposite to the counterweight.

Optionally, the number of the scanning mirrors is two; the mirror surfaces of the two scanning mirrors form a preset angle.

Correspondingly, the utility model also provides a laser radar, comprising: a light emitting device adapted to generate probe light; the scanning device is the laser radar of the utility model; the scanning device reflects the detection light to a three-dimensional space and reflects echo light formed by a target in the three-dimensional space reflecting the detection light; a light receiving device adapted to detect the echo light.

Compared with the prior art, the technical scheme of the utility model has the following advantages:

in the technical scheme of the utility model, the scanning mirror is driven by the resonant motor, and the driving capability of the resonant motor is stronger, so that the limitation of the driving force on the area of the scanning mirror can be broken through, namely the area of the scanning mirror is larger, and the expansion of a scanning field angle is facilitated; and the resonant motor comprises a restoring component, and the restoring component is used for restoring the rotor to the balance position around the rotating shaft. The return assembly is added, so that the scanning mirror can swing back and forth with higher frequency and larger amplitude with relatively smaller driving power, the scanning mirror can swing back and forth with low power consumption and large angle under certain frequency, and the problem that the scanning field range of the laser radar is limited due to the undersize of the scanning mirror can be solved.

In an alternative scheme of the utility model, the resonant motor comprises a magnetic ring and a coil assembly, a rotor of the resonant motor comprises the magnetic ring, and a stator of the resonant motor comprises the coil assembly. The coil group is fixedly arranged, so that the coil group can be effectively prevented from being repeatedly wound, and the stability of the resonant motor can be effectively improved; and the way of fixedly setting up coil group also is favorable to the coil heat dissipation, can effectively improve scanning device's heat dissipation problem.

In an alternative scheme of the utility model, a plurality of winding coils of the coil group are positioned on the periphery of the magnetic ring and distributed around the magnetic ring, namely the winding coils are arranged between the magnetic ring and the restoring assembly, so that compact arrangement under a smaller load can be realized, and the volume of the scanning device can be controlled. The rotor of the resonant motor comprises the magnetic ring, and the stator of the resonant motor comprises the coil assembly. The magnetic ring forming the rotor is provided with the inner ring, the radius of the rotor is smaller, the rotational inertia of the rotor can be reduced to the greatest extent, the requirement for driving force is favorably reduced, the sizes of other parts of the resonant motor are favorably reduced, and the compactness of the resonant motor is favorably improved.

In an alternative of the present invention, the plurality of winding coils of the coil assembly are located on an inner periphery of the magnetic ring, and the magnetic ring surrounds the plurality of winding coils, that is, the magnetic ring is disposed between the winding coils and the restoring assembly. The magnetic ring and the distance between the recovery assemblies are closer, so that larger driving force can be provided, the driving force of the resonant motor can be improved, and the arrangement of a scanning mirror with a larger area can be facilitated.

In an alternative aspect of the present invention, the scanning device further includes: a counterweight member. The counterweight is positioned on one side of the rotor, which is far away from the scanning mirror, so that the center of gravity of the rotor, the scanning mirror and the counterweight is positioned at the position of the rotating shaft. The arrangement of the counterweight can effectively improve the rotating stability of the scanning mirror, and is favorable for improving the precision and stability of a scanning light path.

In an alternative aspect of the present invention, in the scanning device, the number of the scanning mirrors is plural, and the plural scanning mirrors are arranged at a preset angle therebetween. Because scanning device realizes the drive through resonant motor, therefore the driving force is stronger, can drive a plurality of scanning mirrors simultaneously, makes a plurality of scanning mirrors do the reciprocating motion of same frequency, same range simply conveniently, can effectively expand the space of laser radar light path design.

In an alternative aspect of the utility model, the scanning device further comprises an excitation coil. On one hand, the exciting coil can adjust the magnetic field of the corresponding magnetic part to eliminate the consistency difference of different magnetic parts or the magnetic field difference caused by temperature difference; on the other hand, the magnetic part can be magnetized, so that the stability of the scanning frequency and the scanning amplitude is ensured, and the stability of the scanning device is improved.

Drawings

FIG. 1 is a schematic cross-sectional view of a scanning device for lidar according to an embodiment of the present invention;

FIG. 2 is a cross-sectional view of a resonant motor in an embodiment of the scanning apparatus shown in FIG. 1;

FIG. 3 is a schematic view of the magnetic field regions corresponding to the magnets in the magnetic ring of the resonant motor in the embodiment of the scanning apparatus shown in FIG. 2;

FIG. 4 is a schematic view of the resonant motor of the embodiment of the scanning device shown in FIG. 2 with the rotor in a predetermined position in a first direction;

FIG. 5 is a schematic view of the resonant motor of the embodiment of the scanning device shown in FIG. 2 with the rotor in a predetermined position in a second direction;

FIG. 6 is a schematic cross-sectional view of another embodiment of a scanning apparatus for lidar in accordance with the present invention;

FIG. 7 is a schematic view of the resonant motor in the embodiment of the scanning device shown in FIG. 6;

FIG. 8 is a schematic cross-sectional view of another embodiment of a scanning apparatus for lidar in accordance with the present invention;

FIG. 9 is a schematic diagram of an optical path structure of a laser radar according to an embodiment of the present invention employing a coaxial transceiver system;

FIG. 10 is a schematic diagram of an optical path structure of an embodiment of a paraxial transceiving system for a lidar according to the present invention;

fig. 11 is a flowchart illustrating a method for controlling a scanning device for lidar according to an embodiment of the present invention.

Detailed Description

It is known from the background art that the voice coil motor in the prior art has a problem of too high driving power when increasing the frequency and amplitude.

The mechanical model of the voice coil motor can be simplified into a 'mass-damping' second-order system, so that the mechanical transfer function can be written as follows:

where J is the moment of inertia, c is the damping, s is the operating frequency, X is the displacement, and F is the driving force.

Under the condition of low damping (the damping of a common motor is reduced as much as possible), the gain of the transfer function is inversely proportional to the square of the frequency, namely, as the frequency s increases, the dynamic gain X (s)/F(s) of the voice coil motor rapidly decreases, once the scanning frequency is increased or the scanning angle is increased, the requirement of the driving force is greatly increased, and the driving power of the voice coil motor in the scanning device is greatly increased.

In order to solve the technical problem, the utility model provides a scanning device for a laser radar, which comprises a resonant motor and a scanning mirror; the resonance motor comprises a rotor and a stator; the rotor deflects to a preset position around a self-balancing position of a rotating shaft; the stator includes: a return assembly adapted to return the rotor to the equilibrium position about the axis of rotation; the scanning mirror is suitable for reflecting light beams to perform optical scanning; the scanning mirror is connected with the resonant motor to realize the reciprocating swing of the scanning mirror.

In the technical scheme of the utility model, the scanning mirror is driven by the resonant motor, and the driving capability of the resonant motor is stronger, so that the limit of the driving force on the area of the scanning mirror can be broken through, namely the area of the scanning mirror is larger, and the expansion of the scanning field angle of the laser radar is facilitated; and the resonant motor comprises a restoring component, and the restoring component is used for restoring the rotor to the balance position around the rotating shaft. The return assembly is added, so that the scanning mirror can swing back and forth with higher frequency and larger amplitude with relatively smaller driving power, the scanning mirror can swing back and forth with low power consumption and large angle under certain frequency, and the problem that the scanning field range of the laser radar is limited due to the undersize of the scanning mirror can be solved.

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

Referring to fig. 1, a schematic cross-sectional structure of an embodiment of a scanning apparatus for lidar according to the present invention is shown.

The scanning device includes: a resonant motor 110.

The resonant motor 110 is adapted to provide a driving force to drive the attached scan mirror 120 to reciprocate for scanning. The movable part of the resonant motor 110 is the rotor, and the immovable part is the stator.

Referring to fig. 2, a schematic cross-sectional view of a resonant motor in an embodiment of the scanning apparatus shown in fig. 1 is shown.

In some embodiments of the present invention, the resonant motor 110 includes: the magnetic ring 111 comprises a plurality of pairs of magnets 111n or 111s, wherein the magnets 111n and 111s have opposite magnetism, preferably, the magnets 111n are magnetic north poles, and the magnets 111s are magnetic south poles. The plurality of pairs of magnets 111n or 111s are distributed along the circumferential direction 111 a; a coil assembly 112, wherein the coil assembly 112 includes a plurality of winding coils 112c, and the plurality of winding coils 112c are distributed along a circumferential direction 111a of the magnetic ring.

In the embodiment shown in fig. 2, the resonant motor 110 is an 8-pole 8-phase motor, and the magnetic ring 111 of the resonant motor includes 4 pairs of magnets 111n or 111 s. The coil assembly 112 includes 8 winding coils 112 c.

The magnetic ring 111 and the coil assembly 112 are coaxially arranged, that is, a central point connecting line of the cross section of the magnetic ring 111 is the rotating shaft 110a, the coil assembly 112 is distributed around the same rotating shaft 110a, and the distance from each winding coil 112c to the rotating shaft 110a is equal.

In some embodiments of the present invention, the plurality of winding coils 112c of the coil assembly 112 are located at the periphery of the magnetic ring 111 and distributed around the magnetic ring 111, that is, the winding coils 112c are disposed at the periphery of the magnetic ring 111, so that the winding coils 112c are prevented from being limited by space, which is beneficial to optimizing the design and heat dissipation of the coil assembly 112.

It should be noted that, in some embodiments of the present invention, the rotor of the resonant electric machine 110 includes the magnetic ring 111, and the stator of the resonant electric machine 110 includes the coil assembly 112, that is, the magnetic ring 111 can rotate around the rotating shaft 110 a; the position of the coil assembly 112 is fixed.

Because the coil assembly 112 needs to be powered to generate driving force/torque, that is, each winding coil 112c in the coil assembly 112 needs to be connected with at least an external power supply, the coil assembly 112 serves as a stator, which can effectively avoid repeated bending of the winding coil 112c in the coil assembly 112, and is beneficial to improving the stability of the resonant motor; and the fixed arrangement is also beneficial to the heat dissipation of the winding coil 112c, and the heat dissipation problem of the scanning device can be effectively improved.

And the magnetic ring 111 as the rotor is arranged in the coil assembly 112, so that the rotation radius of the rotor can be effectively limited, the rotation inertia of the rotor can be reduced to a greater extent, the requirement for driving force is reduced, the volumes of other parts of the motor are reduced, and the compactness of the motor is improved.

The return assembly is adapted to return the rotor to the equilibrium position.

The rotor is restored to the balance position through the restoring assembly so as to realize the reciprocating motion of the rotor, and therefore the power consumption of the resonant motor can be effectively controlled; in addition, the return component can also enable the reciprocating motion frequency of the rotor to be positioned at the resonant frequency point with the largest gain, the driving power of the resonant motor can be utilized to the maximum extent, namely, a larger scanning angle can be obtained with smaller driving power, and the realization of the consideration of a large scanning angle and low power is facilitated.

It should be noted that the balance position is a position where the stator and the rotor are in a stable state when the resonant motor is not powered, that is, when the resonant motor is not powered, the rotor is in a stable balance state.

As shown in fig. 2, in some embodiments of the present invention, the restoring elements (not labeled) are located on a side of the coil assembly 112 away from the magnetic ring 111, that is, the winding coils 112c are distributed around the magnetic ring 111, and the restoring elements are located on a periphery of the winding coils 112 c.

In some embodiments of the utility model, the reply assembly comprises: at least one magnetic portion 113 a. The rotor is driven to return to the equilibrium position around the rotation axis 110a at least under a second action, which comprises an interaction between the magnetic field of the magnetic part 113a and the magnetic field of the magnetic ring 111.

As shown in fig. 2, the restoring assembly includes 2 magnetic portions 113a, the 2 magnetic portions 113a are coplanar with the rotating shaft 110a, and a connecting line between the 2 magnetic portions 113a is orthogonal to the rotating shaft 110 a.

It should be noted that in the embodiment shown in fig. 2, the purpose of the restoring assembly including 2 magnetic portions 113a is to facilitate the mirror to swing. However, the method of setting the number of the magnetic portions 113a to 2 in the restoring assembly is only an example. In other embodiments of the present invention, the number of the magnetic portions may be set to 1 or more, and may be set according to a magnetic field distribution.

As mentioned above, in some embodiments of the utility model, the rotor of the resonant electric machine comprises the magnetic ring, so the second effect between the magnetic part 113a and the magnetic ring 111 is independent of whether or not current is transmitted in the coil assembly 112. Therefore, in the equilibrium position, the magnetic portion 113a and the partial magnetic ring 111 corresponding to the magnetic portion 113a are attracted to each other, that is, the magnetic portion 113a and the partial magnetic ring 111 facing the magnetic portion 113a are attracted to each other on the side close to the magnetic ring 111, that is, when the magnetic portion 111 facing the magnetic portion 111a is the S-pole, the N-pole of the magnetic portion 113a is close to the magnetic ring 111; when the magnetic ring 111 facing the magnetic portion 113a is an N-pole, the S-pole of the magnetic portion 113a is close to the magnetic ring 1111.

In some embodiments of the present invention, the rotor is driven by a first action to deflect around the rotating shaft 100a from the equilibrium position to the preset position, wherein the first action is an interaction between a current transmitted in a winding coil of the coil assembly 112 and a magnetic field of the magnetic ring 111.

When the rotor is in a balanced position, a first current is input to the plurality of winding coils 112c in the coil group 112, and based on the principle that a current conductor is stressed in a magnetic field, the interaction between the first current transmitted in the winding coils 112c in the coil group 112 and the magnetic field of the magnetic ring 111 causes the magnetic ring 111 and the coil group 112 to rotate relative to each other around the rotating shaft 110 a.

As shown in fig. 2, in the equilibrium position, a part of the winding coil 112c corresponds to one magnet 111s, and the other part extends to correspond to the adjacent magnet 111 n.

It should be noted that the plurality of pairs of magnets 111n or 111s constituting the magnetic ring 111 divide the space around the magnetic ring 111 into respective sector regions, each of the divided sector regions corresponds to one of the magnets 111n or 111s and is a magnetic field region of the corresponding magnet 111n or 111s, and as shown in fig. 3, the space 111nb is a magnetic field region of the magnet 111 n. Therefore, a portion of the winding coil 112c corresponds to one magnet 111s, and another portion extends to correspond to the adjacent magnet 111n, meaning that: a part of the winding coil 112c is located within the magnetic field region of one magnet 111s, and another part extends into the magnetic field region of the adjacent magnet 111n, i.e., the winding coil 112c crosses the magnetic field region of a pair of adjacent magnets 111n or 111 s.

In some embodiments of the present invention, the directions of currents transmitted in the winding coils 112c corresponding to the same magnet 111n or 111s are the same, so as to ensure that the directions of the interaction between the winding coils 112 and the magnetic ring 111 are the same. Specifically, the first current transmitted in the winding coil 112c corresponding to the same magnet 111n or 111s has the same direction.

As shown in fig. 2, the winding coil 112ca is partially located in the magnetic field region of the magnet 111s, and the winding coil 112cb adjacent to the winding coil 112ca is partially located in the magnetic field region of the magnet 111s, and the first current direction transmitted by the portion of the winding coil 112ca located in the magnetic field region of the magnet 111s is the same as the first current direction transmitted by the portion of the winding coil 112cb located in the magnetic field region of the magnet 111s, for example, both are out of the plane of the vertical paper (as shown in the circle 112cc in fig. 2), so the first current direction transmitted by the winding coil 112ca and the first current direction transmitted by the winding coil 112cb are opposite, that is, in the embodiment shown in fig. 2, the first current direction of the adjacent winding coil 112c in the coil group 112 is opposite.

Specifically, as shown in fig. 2, when the rotor including the magnetic ring 111 is in the equilibrium position, a first current is input to the plurality of winding coils 112c in the stator inner coil assembly 112, so that the rotor rotates around the rotating shaft 110a in a first direction (e.g., counterclockwise).

In some embodiments of the present invention, when the rotor is deflected to a preset position, the current transmitted in the coil assembly 111 is cut off, and the rotor is driven by the second action to return to the equilibrium position.

Since the rotor is deflected to a predetermined position by the first action, when the current transmitted in the winding coil 112c of the coil assembly 111 is cut off at the predetermined position, the first action for driving the rotor to deflect is also lost, and only the second action between the magnetic portion 113a and the magnetic ring 111 exists between the rotor and the stator, so that the rotor is deflected to the equilibrium position by the second action, that is, the rotor returns to the equilibrium position.

Specifically, as shown in fig. 4, when the rotor rotates to a preset position in a first direction (e.g., counterclockwise) and cuts off the current transmitted in the coil assembly 111, the rotor is driven by the second action to rotate around the rotating shaft 110a in a second direction (e.g., clockwise) from the preset position in the first direction to the equilibrium position, wherein the second direction is opposite to the first direction.

When the rotor returns to the equilibrium position along a second direction, a second current is input into a winding coil 111c in the coil group 111, the transmission direction of the second current is opposite to the transmission direction of the first current, and based on the principle that an electrified conductor is stressed in a magnetic field, the interaction between the second current transmitted in the winding coil 112c in the coil group 112 and the magnetic field of the magnetic ring 111 also enables the magnetic ring 111 and the coil group 112 to rotate relatively around the rotating shaft 110 a; but since the direction of the second current is opposite to the direction of the first current, the direction of the interaction between the second current and the magnetic field of the magnetic ring is opposite to the direction of the interaction between the first current and the magnetic field of the magnetic ring 111.

Specifically, as shown in fig. 2, when the rotor including the magnetic ring 111 returns to the equilibrium position along the second direction (e.g., clockwise), the second current is input to the plurality of winding coils 112c in the coil assembly 112 in the stator, so that the rotor continuously deflects to the preset position along the second direction (e.g., clockwise) around the rotating shaft 110 a.

It should be noted that, in some embodiments of the present invention, the directions of currents transmitted in the winding coils 112c corresponding to the same magnet 111n or 111s are the same, so as to ensure that the directions of the interactions between the winding coils 112 and the magnetic ring 111 are the same. Therefore, similar to the first current, the second current transmitted in the partial winding coil 112c corresponding to the same magnet 111n or 111s has the same direction.

Specifically, as shown in fig. 2, the direction of the second current transmitted in the winding coil 112ca and the winding coil 112cb is opposite, that is, in the embodiment shown in fig. 2, the direction of the second current transmitted in the adjacent winding coil 112c in the coil assembly 112 is opposite.

As shown in fig. 5, when the rotor is deflected to the preset position in the second direction, the current transmitted in the coil assembly 111 is cut off again, and the rotor is driven by the second action to return to the equilibrium position again.

It follows that the rotor of the resonant electric machine reciprocates back and forth between a rest position, a preset position in a first direction and a preset position in a second direction. The mechanical model of the resonant motor can therefore be approximated to a certain extent by spring elements. For a spring element, the potential energy developed during the deviation from the equilibrium position is converted into the strain capacity of the elastic material; in the case of the resonant motor, the potential energy formed during the process of deviating from the equilibrium position is stored in the magnetic ring 111 and the magnetic portion 113a, so that the mechanical model of the resonant motor can be approximately understood as a simple harmonic motion system.

Specifically, for the resonant motor, the stiffness coefficient k of the reciprocating motion of the rotor can be expressed as: k ═ J (2 pi f)₀)²Or K ═ m (2 pi f)₀)²Wherein f is₀Representing the operating frequency of the resonant motor, J representing the moment of inertia of the load, and m representing the mass of the load.

It should be noted that the stiffness coefficient K is used to characterize the magnitude of the force required to produce a unit displacement of the load. Thus the smaller the stiffness factor, the less driving force that needs to be applied, i.e. easier to drive, to reduce energy consumption, and the larger the stiffness factor, the greater the driving force generated, the more massive the load can be driven.

Furthermore, there is an interaction between the magnetic field of each magnetic portion 113a and the magnetic field of the magnetic ring 111, that is, a simple harmonic motion system can be formed between each magnetic portion 113a and the magnetic ring 111. As shown in fig. 2, in the embodiment, the restoring assembly includes 2 magnetic portions 113a respectively located at two sides of the magnetic ring 111, that is, the magnetic ring 111 is located between the two magnetic portions 113 a.

Therefore, in the embodiment shown in fig. 1 to 5, the simple harmonic motion system between the rotor and the stator of the resonant motor is equivalent to the interaction of each magnetic portion 113a and a single simple harmonic motion system between the magnetic rings 111, that is, the stiffness coefficient of the simple harmonic motion system between the rotor and the stator of the resonant motor is the sum of the interactions between all the magnetic portions 113a in the restoring assembly and the magnetic rings 111. Specifically, the stiffness coefficient of the simple harmonic motion system between the rotor and the stator of the resonant motor is expressed as: k ═ n ═ K₀(x, s (magnet)), where n represents the number of simple harmonic motion systems, k₀The stiffness function of a simple harmonic motion system is shown, x represents the clearance inside the simple harmonic motion system, and s represents the geometric parameter of the simple harmonic motion system.

According to the rigidity coefficient of the simple harmonic motion system between the rotor and the stator of the resonant motor, the rigidity coefficient of the simple harmonic motion system between the rotor and the stator of the resonant motor can be adjusted by setting the number of the magnetic parts. Specifically, the number of the magnetic parts is increased, and the rigidity coefficient K of a simple harmonic motion system between a rotor and a stator of the resonant motor is increased.

It should be noted that the gap inside the simple harmonic motion system refers to a gap between two magnets in the simple harmonic motion system. In the embodiment shown in fig. 1 to 5, the gap inside the simple harmonic motion system is the distance between the magnetic part 113a and the magnetic ring 111.

In addition, when the rotor is rotated to a preset position in the first direction or the second direction, at least part of the magnets 111n or 111s corresponding to the winding coil 112c are not changed, so that the rotor is ensured to oscillate near the equilibrium position. The preset position is related to the spatial frequency of the magnetic ring 111, that is, the stroke of the rotor is related to the spatial frequency of the magnetic ring 111, and the maximum stroke of the rotor can be adjusted by changing the number of pairs of magnets in the magnetic ring 111.

Specifically, as shown in fig. 1 to 5, the magnetic ring 111 includes n pairs of magnets 111s and 111n, and the preset position is a position where the rotor rotates from the equilibrium position by an angle α, where α is not greater than 360/(2n × 2). In the embodiment shown in fig. 2, the magnetic ring 111 includes 4 pairs of magnets 111s and 111n, and the angle between the preset position and the equilibrium position is 22.5 °.

It should be noted that the spatial frequency of the magnetic ring 111 can only influence the maximum stroke of the rotor, i.e. the possible position of the predetermined position. In actual operation, the stroke of the rotor is affected by the energizing time of the winding coils 112c in the coil assembly 112, in addition to the spatial frequency limit of the magnetic ring 111.

With continued reference to fig. 1, the scanning apparatus further comprises: a scan mirror 120.

The scanning mirror 120 is adapted to reflect the light beam for optical scanning; the scan mirror 120 is connected to the resonant motor 110 to effect reciprocal oscillation of the scan mirror.

As described above, the rotor of the resonant motor reciprocates back and forth between the equilibrium position, the preset position in the first direction, and the preset position in the second direction, and the scanning mirror 120 is connected to the rotor of the resonant motor and can oscillate back and forth along with the rotor to change the propagation direction of the reflected light beam and achieve scanning.

When the rotor rotates to a certain position, the detection beam reflected by the scanning mirror corresponds to a space field angle for detection, the preset positions in the first direction and the second direction respectively correspond to the maximum field angle in the horizontal field of view of the laser radar, for example, the preset position in the first direction corresponds to a field angle of +60 degrees, the preset position in the second direction corresponds to a field angle of-60 degrees, the balance position corresponds to a field angle of 0 degree, the reciprocating motion of the rotor among the balance position, the preset position in the first direction and the preset position in the second direction is realized to realize the reciprocating swing of the scanning mirror, and the laser radar detects in the space within the field range of the field of view, wherein the detection beam can be generated by a laser or a two-dimensional array arranged laser, the one-dimensional linear array can be arranged along the vertical direction, and in addition, the scanning device can also scan the vertical field of view.

As shown in fig. 1, in some embodiments of the present invention, the scanning apparatus further includes: further comprising: and the counterweight 130 is positioned on one side of the rotor, which is far away from the scanning mirror 120, so that the gravity center of the whole of the rotor, the scanning mirror 120 and the counterweight 130 is positioned at the position of the rotating shaft. Through the setting of counterweight, make the rotor the scanning mirror 120 with the holistic focus of counterweight 130 is located pivot position department makes the whole barycenter of scanning device moving part can effectively improve scanning device pivoted stability at centre of revolution, effectively guarantees the scanning mirror and realizes the stability of beam scanning. Specifically, in the embodiment shown in FIG. 1, the counterweight 130 is disposed opposite the scan mirror 120 to adjust the overall centroid position.

It should be noted that, in the embodiment shown in fig. 1 to 5, the winding coil 112c is disposed on the periphery of the magnetic ring 111, when the rotor deflects to a preset position, the current transmitted in the coil group 111 is cut off, and the rotor is driven to return to the equilibrium position only under the second action. However, this arrangement is merely an example, and in other embodiments of the present invention, when the winding coils are disposed on the periphery of the magnetic ring and the rotor is deflected to a preset position, the current transmitted in the winding coils in the coil group may be cut off and a reverse current may be input to the winding coils in the coil group, and the rotor is driven by the first action and the second action together to return to the equilibrium position.

Referring to fig. 6 and 7, fig. 6 is a schematic cross-sectional view showing another embodiment of the scanning apparatus for lidar according to the present invention, and fig. 7 is a schematic structural view showing a resonant motor in the embodiment of the scanning apparatus shown in fig. 6.

The scanning device includes: a resonant motor 210, and a scanning mirror 220 and a counterweight 230 connected with the rotor of the resonant motor 210. The utility model is not described herein in detail except for the same aspects as described in the previous embodiments. Different from the previous embodiment, as shown in fig. 7, in some embodiments of the present invention, the plurality of winding coils 212c of the coil group 212 are located on an inner circumference of the magnetic ring 211, and the magnetic ring 211 surrounds the plurality of winding coils 212c, that is, the plurality of winding coils 212c in the coil group 212 are all located inside the magnetic ring 211 and distributed along a circumferential direction of the magnetic ring 211.

In addition, as shown in fig. 7, in some embodiments of the present invention, the restoring component is located on a side of the magnetic ring 211 away from the coil assembly 212. As mentioned before, the mechanical model of the resonant motor can be understood approximately as a simple harmonic motion system. The stiffness coefficient of a single simple harmonic motion system is related to the gap inside the simple harmonic motion system, i.e. to the distance between the magnetic part 213a and the magnetic ring 211.

The arrangement mode that the winding coil 212c is located in the magnetic ring 211 and the magnetic part 213a is located outside the magnetic ring 211 can reduce the distance between the magnetic part 213a and the magnetic ring 211 as much as possible, increase the rigidity coefficient of a simple harmonic motion system, and is beneficial to increase the load mass and the load rotational inertia, so that the drive of a large-size scanning mirror can be realized on the premise of not increasing the energy consumption, or the energy consumption can be effectively reduced on the premise of driving the scanning mirror with the same size.

As described in the foregoing embodiment, when the rotor is in the equilibrium position, a first current is input to the plurality of winding coils 212c in the coil assembly 212, and the rotor is driven by a first action to deflect around the rotating shaft in a first direction (e.g., counterclockwise) from the equilibrium position to a preset position in the first direction.

In some embodiments of the present invention, when the rotor is deflected to a predetermined position, the rotor is driven by the first action and the second action to return to the equilibrium position by cutting off the current transmitted in the winding coil 212c of the coil assembly 212 and inputting a reverse current to the winding coil 212c of the coil assembly 212.

Specifically, as shown in fig. 6 and 7, when the rotor rotates to a preset position in a first direction, a first current transmitted in the coil assembly 211 is cut off, and a second current is input into the winding coil 212c in the coil assembly 211, where the direction of the second current is opposite to the direction of the first current.

Based on the principle that the energized conductor is stressed in the magnetic field, the interaction between the second current transmitted in the winding coil 212c in the coil group 212 and the magnetic field of the magnetic ring 211 also causes the magnetic ring 211 and the coil group 212 to rotate relatively around the rotating shaft; however, since the direction of the second current is opposite to the direction of the first current, the direction of the first action between the second current and the magnetic field of the magnetic ring 211 is opposite to the direction of the first action between the first current and the magnetic field of the magnetic ring 211, which is the direction of the rotor deflecting to the equilibrium position, that is, the direction of the first action between the second current and the magnetic field of the magnetic ring 211 is the same as the direction of the second action between the magnetic field of the magnetic portion 213a and the magnetic field of the magnetic ring 211 at the preset position of the first direction.

Specifically, as shown in fig. 6 and 7, when the rotor rotates to a preset position in a first direction along a first direction, cuts off the first current, and inputs a second current, the rotor rotates around the rotating shaft from the preset position in the first direction to the equilibrium position along a second direction (for example, a clockwise direction) along a second direction (opposite to the first direction) under the driving of a first action between the second current and the magnetic field of the magnetic ring 211 and a second action between the magnetic field of the magnetic portion 213a and the magnetic field of the magnetic ring 211.

When the rotor returns to the equilibrium position along the second direction, a third current is input into the winding coil 211c in the coil group 211, and the transmission direction of the third current is the same as the transmission direction of the second current, i.e., opposite to the transmission direction of the first current. The direction of the first interaction between the third current and the magnetic field of the magnetic ring 111 is therefore the same as the direction of the first interaction between the second current and the magnetic field of the magnetic ring 111.

Specifically, as shown in fig. 6 and 7, when the rotor returns to the equilibrium position along the second direction, a third current is input to the plurality of winding coils 212c in the coil assembly 212, so that the rotor continuously deflects around the rotation axis along the second direction (e.g., clockwise) to a preset position along the second direction.

When the rotor deflects to a preset position in the second direction, the third current transmitted in the coil set 111 is cut off, and a fourth current is input to the winding coil 212c in the coil set 212, and the direction of the fourth current is opposite to the direction of the third current.

Since the direction of the fourth current is opposite to the direction of the third current, the direction of the first action between the fourth current and the magnetic field of the magnetic ring 211 is opposite to the direction of the first action between the third current and the magnetic field of the magnetic ring 211, that is, the direction of the first action between the fourth current and the magnetic field of the magnetic ring 211 is the same as the direction of the second action between the magnetic field of the magnetic portion 213a and the magnetic field of the magnetic ring 211 at a preset position in the second direction.

Specifically, as shown in fig. 6 and 7, when the rotor rotates to the preset position in the second direction along the second direction, cuts off the third current, and inputs the fourth current, the rotor returns from the preset position in the second direction to the equilibrium position along the first direction (for example, clockwise) around the rotating shaft under the driving of the first action between the fourth current and the magnetic field of the magnetic ring 211 and the second action between the magnetic field of the magnetic portion 213a and the magnetic field of the magnetic ring 211.

It follows that the return of the rotor of the resonant electric machine from the preset position to the equilibrium position is not only driven by the second action, but also by the first action. As mentioned before, the mechanical model of a resonant motor can be understood approximately as a simple harmonic motion system.

When the return of the rotor of the resonant motor is driven by the first action and the second action, the mechanical model of the resonant motor can be seen as having two types of simple harmonic motion systems — the first type of simple harmonic motion system is formed between the magnetic part 213a and the magnetic ring 211, and the second type of simple harmonic motion system is formed between the magnetic ring 211 and the plurality of winding coils 212c in the coil group 212 for transmitting currents in different directions.

When the mechanical model of the resonant motor is regarded as two types of simple harmonic motion systems, the mechanical model can be regarded as a second-order resonant system approximately, the two types of simple harmonic motion systems can generate resonance phenomena at a resonant frequency point, the maximum gain can be generated, and the maximum motion displacement can be generated by using the minimum driving force. Therefore, low power consumption and large-angle driving can be realized.

And the frequency corresponding to the maximum gain generated when the resonance phenomenon occurs is a resonance frequency point. As mentioned above, the stiffness coefficient K of the simple harmonic motion system between the stator and the rotor and the operating frequency f of the resonant electric machine₀Stiffness coefficient k of related, but single simple harmonic motion system₀Influenced by the magnetic fields and the positional relationship between the magnetic part 213a and the magnetic ring 211; therefore, the working frequency of the resonant motor is the resonant frequency point and the gain is maximized through the reasonable arrangement of the resonant motor, the scanning mirror, the counterweight and other components.

In addition, it is different from the previous embodiments in that, in some embodiments of the present invention, the restoring assembly further includes: an excitation coil 214, wherein the excitation coil 214 is adapted to adjust the magnetic field of the corresponding magnetic portion 213a such that the restoring assembly forms a predetermined effective magnetic field.

The exciting coil 214 can adjust the magnetic field of the corresponding magnetic part 213a to eliminate the consistency difference of different magnetic parts 213a or the magnetic field difference caused by the temperature difference; on the other hand, the magnetic part 213a can be magnetized, so that the stability of the scanning frequency and the scanning amplitude is ensured, and the stability of the scanning device is improved.

In the embodiment shown in fig. 6 and 7, the excitation coil 214 surrounds the corresponding magnetic portion 213a with the connecting line between the magnetic ring 211 and the magnetic portion 213a as the axis. The fact that the excitation coils 214 correspond to the magnetic parts 213a means that the number of the excitation coils 214 is equal to the number of the magnetic parts 213a, and the excitation coils and the magnetic parts are in one-to-one correspondence.

In some embodiments of the utility model, the resonance unit further comprises: a current unit 215, wherein the current unit 215 is adapted to input a current to the excitation coil 214 to cause the restoring assembly to form a predetermined effective magnetic field. Specifically, as shown in fig. 6 and 7, after the current is input to the excitation coil 214, the magnetic field formed by the current transmitted in the excitation coil 214 is superimposed with the magnetic field of the corresponding magnetic portion 213a to form the effective magnetic field of the restoring assembly.

Due to the problem of production consistency, different magnets have difference of magnetic field intensity, so that different magnetic parts in the same scanning device and different magnetic parts in different scanning devices have difference of magnetic field intensity, and the difference of magnetic field intensity affects the rigidity coefficient of a simple harmonic motion system, and further affects the scanning frequency, the scanning amplitude and the like of the scanning device. Therefore, the magnetic field formed by the current transmitted in the excitation coil 214 can be adjusted by adjusting the current transmitted in the excitation coil 214 to eliminate the difference in the stiffness coefficient of the simple harmonic motion system caused by the difference in consistency, so that the effective magnetic field formed after superposition is kept stable, and the stability of the stiffness coefficient of the simple harmonic motion system is further ensured, that is, the stiffness coefficient of the simple harmonic motion system is ensured to be a set value.

In addition, the magnets have a temperature effect. Generally, as the temperature increases, the magnetic properties of the magnet decrease. Therefore, at different temperatures, the magnetic field of the same magnet also changes, and therefore, when the temperature changes, the magnetic field formed by the current transmitted in the excitation coil 214 can be adjusted by adjusting the current transmitted in the excitation coil 214, so as to eliminate the difference of the stiffness coefficient of the simple harmonic motion system caused by the temperature change, so that the effective magnetic field formed after superposition is kept stable, and further, the stability of the stiffness coefficient of the simple harmonic motion system is ensured.

In addition, the magnet has a time effect, that is, the magnetic property of the magnet is attenuated in the life cycle, so that the stiffness coefficient of the simple harmonic motion system is also attenuated as the service time is prolonged, and therefore, the excitation coil 214 can magnetize the magnetic part 213a at a proper time point in the life cycle to recover the magnetic property of the magnetic part 213a, so as to achieve the purpose of restoring the stiffness coefficient of the simple harmonic motion system.

With continued reference to fig. 6, in some embodiments of the present invention, the scanning apparatus further comprises: a detection unit 240, said detection unit 240 adapted to detect an effective magnetic field of said recovery assembly; the adjusting unit 250 is adapted to control the exciting coil to adjust the magnetic field of the magnetic part based on the detection result of the detecting unit 240, so that the restoring assembly forms a predetermined effective magnetic field.

Specifically, in some embodiments of the present invention, during the power-on self-test process, the detection unit 240 detects an effective magnetic field of the recovery assembly; the adjusting unit 250 includes: the first controller 251 is adapted to control the excitation coil to form an adjusting magnetic field based on a detection result of the detection unit 240 during the power-on self-test, and the adjusting magnetic field is matched with the magnetic field of the corresponding magnetic portion to form a preset effective magnetic field.

In addition, in some embodiments of the present invention, the detecting unit 240 detects the magnetic field of the magnetic part in real time; the adjusting unit 250 includes: a second controller 252, wherein based on the real-time detection result of the detection unit 240, the second controller 252 is adapted to control the excitation coil to form a real-time adjusting magnetic field, and the real-time adjusting magnetic field and the magnetic field of the corresponding magnetic portion cooperate to form a predetermined effective magnetic field.

In addition, in some embodiments of the present invention, the adjusting unit 250 further includes: a third controller 253, wherein under a preset condition, the third controller 253 is adapted to control the excitation coil to charge the magnetic part. The preset condition includes at least one of a time condition and a magnetic field condition, the time condition is when the usage time meets a preset time length, and the magnetic field condition is when the detection unit 240 detects that the effective magnetic field of the reply assembly is lower than a preset value.

Referring to fig. 8, there is shown a schematic cross-sectional view of another embodiment of the scanning apparatus for lidar of the present invention,

the same points as the previous embodiments are omitted for the description of the present invention. The difference between the previous embodiments is that in some embodiments of the present invention, the number of the scanning mirrors is one or more, and the one or more scanning mirrors are disposed opposite to the weight.

Because resonant motor can be with less drive power, realize the reciprocating swing of the scanning mirror bigger movement frequency, bigger motion amplitude, that is to say, drive motor can obtain bigger driving force with less drive power, so resonant motor's setting can provide probably for the setting of a plurality of scanning mirrors or bigger size scanning mirror, can effectively enlarge the scanning visual field.

Specifically, as shown in fig. 8, in the embodiment, the number of the scanning mirrors is 2, which are the scanning mirror 321 and the scanning mirror 322, the 2 scanning mirrors are located on one side of the rotating shaft, and the weight 330 is located on the other side of the rotating shaft, so as to adjust the position of the center of gravity of the whole of the rotor, the scanning mirror and the weight.

In addition, in some embodiments of the present invention, when the number of the scanning mirrors is plural, the mirror surfaces of the plural scanning mirrors have a predetermined angle therebetween. Specifically, as shown in fig. 8, the number of the scanning mirrors is two, and the two scanning mirrors are respectively a scanning mirror 321 and a scanning mirror 322, and a preset angle, for example, 90 °, is formed between the mirror surfaces of the scanning mirror 321 and the scanning mirror 322.

It should be noted that, in some embodiments of the present invention, the lidar employing the scanning apparatus has two sets of transceiver systems, where the two sets of transceiver systems may be a coaxial transceiver system or a paraxial transceiver system. The two sets of transceiving systems respectively correspond to different mirror surfaces of the scanning mirror, that is, the light beams emitted by one set of transceiving system and the received light beams are reflected by the scanning mirror 321, and the light beams emitted by the other set of transceiving system and the received light beams are reflected by the scanning mirror 322, so as to achieve the purpose of expanding the field of view. The paraxial transceiving system is formed by arranging a light emitting device and a light receiving device along a direction vertical to a horizontal plane.

In other embodiments of the present invention, the lidar employing the scanning device only has one set of transceiver system, the transceiver system is a paraxial transceiver system, the transceiver system respectively transmits and receives light beams through 2 scanning mirrors, that is, the light beam generated by the light emitting device in the transceiver system is reflected by one of the scanning mirror 321 and the scanning mirror 322 to realize light beam emission, and the light beam received by the light receiving device in the transceiver system is reflected by the other of the scanning mirror 321 and the scanning mirror 322 to realize light beam reception.

Because 2 scanning mirrors link to each other with same resonant motor, consequently 2 scanning mirror's scanning frequency and scanning amplitude are strict unanimous, can effectively avoid the light path deviation that technology uniformity problem arouses, can effectively guarantee the stability of light beam scanning, effectively reduce the assembly process degree of difficulty.

Correspondingly, the utility model also provides a laser radar, which specifically comprises: a light emitting device 411 adapted to generate detection light; a scanning device 412, which is the scanning device of the present invention, and which reflects the probe light to a three-dimensional space and receives and reflects echo light formed by the probe light reflected by a target in the three-dimensional space; a light receiving device 413 adapted to detect the echo light.

The scanning device 412 is the scanning device of the present invention. The specific technical solution of the scanning device refers to the description of the aforementioned embodiment of the scanning device, and the present invention is not repeated herein.

The scanning device can realize the reciprocating swing of the scanning mirror with higher frequency and larger amplitude with relatively smaller driving power, is favorable for realizing the reciprocating swing of the scanning mirror with low power consumption and large angle under certain frequency, and is favorable for overcoming the problem of limited scanning field range of the laser radar caused by undersize of the scanning mirror.

In some embodiments of the present invention, the lidar may be a lidar employing a coaxial transceiver system (as shown in fig. 9). In other embodiments of the present invention, however, the lidar may be a lidar employing a paraxial transceiver system (as shown in fig. 10). As shown in fig. 10, in the laser radar using the paraxial transceiving system, the light emitting device and the light receiving device may be disposed in a direction perpendicular to a horizontal plane, so that both the emitted light beam and the received light beam are reflected by the same scanning mirror.

In addition, the utility model also provides a control method of the scanning device for the laser radar.

Referring to fig. 6, 7 and 11, fig. 6 is a schematic cross-sectional structural diagram of a scanning device for lidar used in the control method, fig. 7 is a schematic cross-sectional structural diagram of a resonant motor in the scanning device for lidar shown in fig. 6, and fig. 11 is a schematic flow chart of an embodiment of the control method of the scanning device for lidar according to the present invention.

The scanning device comprises a resonant motor 210 and a scanning mirror 220; the resonant motor 210 comprises a rotor and a stator; the rotor deflects to a preset position around a self-balancing position of a rotating shaft; the stator includes: a return assembly adapted to return the rotor to the equilibrium position about the axis of rotation; the scanning mirror 220 is adapted to reflect the light beam for optical scanning; the scanning mirror 220 is connected with the resonant motor to realize the reciprocating swing of the scanning mirror 220; the reply assembly comprises: an excitation coil 214 and a magnetic portion 213a, the excitation coil 214 surrounding the corresponding magnetic portion 213 a.

The control method comprises the following steps: the magnetic field of the corresponding magnetic part 213a is adjusted by the exciting coil 214, so that the restoring component forms a preset effective magnetic field.

The excitation coil 214 adjusts the magnetic field of the corresponding magnetic part 213a to form an effective magnetic field, so that on one hand, the magnetic field of the corresponding magnetic part 213a can be adjusted to eliminate the consistency difference of different magnetic parts 213a or the magnetic field difference caused by temperature difference; on the other hand, the magnetic part 213a can be magnetized, so that the stability of the scanning frequency and the scanning amplitude is ensured, and the stability of the scanning device is improved.

As shown in fig. 11, in some embodiments of the present invention, before adjusting the magnetic field of the corresponding magnetic portion, the method further includes: executing step S11a, detecting an effective magnetic field of the restoring component; when the magnetic field of the corresponding magnetic part is adjusted, step S11b is executed, and based on the detection result of the detection unit, the excitation coil is controlled to adjust the magnetic field of the magnetic part, so that the restoring component forms a preset effective magnetic field.

The effective magnetic field of the recovery assembly is detected through the detection unit, the magnetic field formed by the exciting coil is adjusted based on the detection result, the adjustment accuracy is improved, and the stability of the finally formed effective magnetic field is improved.

Aiming at the magnetic field intensity difference caused by the production consistency problem, because the magnetic field intensity difference is caused by production, the magnetic field intensity difference caused by the production consistency problem is fixed for each magnetic part, and the specific situation of the magnetic field intensity difference caused by the production consistency problem can be obtained only through one-time detection. Therefore, in some embodiments of the present invention, during the power-on self-test, the effective magnetic field of the recovery assembly is detected.

For the magnetic field intensity difference caused by temperature change, since the temperature changes along with the use of the laser radar, the magnetic field intensity difference caused by the temperature change changes along with the temperature change for each magnetic part, namely, the specific situation of the magnetic field intensity difference caused by the temperature change can be changed in real time. Therefore, in some embodiments of the present invention, the magnetic field of the magnetic part is detected in real time during the scanning process of the scanning device.

In addition, the magnet has a time effect, that is, the magnetic property of the magnet is attenuated in the life cycle, so that the stiffness coefficient of the simple harmonic motion system is also attenuated as the service time is prolonged, and therefore, the excitation coil 214 can be used for punching the magnetic part 213a at a proper time point in the life cycle to recover the magnetic property of the magnetic part 213a, so as to achieve the purpose of restoring the stiffness coefficient of the simple harmonic motion system.

Specifically, in some embodiments of the present invention, under a preset condition, the excitation coil is controlled to charge the magnetic portion. The preset condition comprises at least one of a time condition and a magnetic field condition, wherein the time condition refers to that when the using time meets a preset time length, the magnetic field condition refers to that the effective magnetic field of the reply assembly is detected to be lower than a preset value.

In summary, in the technical solution of the present invention, the scanning mirror is driven by the resonant motor, and the driving capability of the resonant motor is stronger, so that the limitation of the driving force on the area of the scanning mirror can be broken through, that is, the area of the scanning mirror is larger, which is beneficial to the expansion of the scanning field angle; and the resonant motor comprises a restoring component, and the restoring component is used for restoring the rotor to the balance position around the rotating shaft. Due to the addition of the reply assembly, the scanning device can realize the reciprocating swing of the scanning mirror with higher frequency and larger amplitude with relatively smaller driving power, is favorable for realizing the reciprocating swing of the scanning mirror with low power consumption and large angle under certain frequency, and is favorable for overcoming the problem that the scanning field range of the laser radar is limited due to the undersize of the scanning mirror.

In an alternative aspect of the present invention, the resonant motor includes a magnetic ring and a coil assembly, the rotor of the resonant motor includes the magnetic ring, and the stator of the resonant motor includes the coil assembly. The coil group is fixedly arranged, so that the coil group can be effectively prevented from being repeatedly wound, and the stability of the resonant motor can be effectively improved; and the way of fixedly setting up coil group also is favorable to the coil heat dissipation, can effectively improve scanning device's heat dissipation problem.

In addition, in an alternative scheme of the utility model, a plurality of winding coils of the coil group are positioned on the periphery of the magnetic ring and distributed around the magnetic ring, namely the winding coils are arranged between the magnetic ring and the restoring assembly, so that compact arrangement under a smaller load can be realized, and the volume of the scanning device can be controlled. The rotor of the resonant motor comprises the magnetic ring, and the stator of the resonant motor comprises the coil assembly. The magnetic ring forming the rotor is provided with the inner ring, the radius of the rotor is smaller, the rotational inertia of the rotor can be reduced to the greatest extent, the requirement for driving force is favorably reduced, the sizes of other parts of the resonant motor are favorably reduced, and the compactness of equipment is favorably improved.

In addition, in an alternative of the present invention, the plurality of winding coils of the coil group are located on an inner circumference of the magnetic ring, and the magnetic ring surrounds the plurality of winding coils, that is, the magnetic ring is disposed between the winding coils and the restoring assembly. The magnetic ring with the distance between the components that reply is according to, can have the drive power that provides bigger, is favorable to improving resonance motor's drive power, is favorable to the setting of larger tracts of land scanning mirror.

Further, in an alternative aspect of the present invention, the scanning device further includes: a counterweight member. The counterweight is positioned on one side of the rotor, which is far away from the scanning mirror, so that the center of gravity of the rotor, the scanning mirror and the counterweight is positioned at the position of the rotating shaft. The arrangement of the counterweight can effectively improve the rotating stability of the scanning mirror, and is favorable for improving the precision and stability of a scanning light path.

Still further, in an alternative of the present invention, in the scanning device, the number of the scanning mirrors is plural, and the plural scanning mirrors are disposed at a predetermined angle therebetween. Because scanning device realizes the drive through resonant motor, therefore the driving force is stronger, can drive a plurality of scanning mirrors simultaneously, can make a plurality of scanning mirrors do the reciprocating motion of same frequency, same range simply conveniently, can effectively expand the space of laser radar light path design.

Furthermore, in an alternative aspect of the utility model, the scanning device further comprises an excitation coil. On one hand, the exciting coil can adjust the magnetic field of the corresponding magnetic part to eliminate the consistency difference of different magnetic parts or the magnetic field difference caused by temperature difference; on the other hand, the magnetic part can be magnetized, so that the stability of the scanning frequency and the scanning amplitude is ensured, and the stability of the scanning device is improved.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the utility model as defined in the appended claims.

Claims (18)

1. A scanning device for laser radar is characterized by comprising a resonant motor and a scanning mirror;

the resonance motor comprises a rotor and a stator;

the rotor deflects to a preset position around a self-balancing position of a rotating shaft;

the stator includes: a return assembly adapted to return the rotor to the equilibrium position about the axis of rotation;

the scanning mirror is suitable for reflecting light beams to perform optical scanning;

the scanning mirror is connected with the resonant motor to realize the reciprocating swing of the scanning mirror.

2. The scanning device of claim 1, wherein the resonant motor comprises: the magnetic ring comprises a plurality of pairs of magnets which are distributed along the circumferential direction; the coil assembly comprises a plurality of winding coils which are distributed along the circumferential direction of the magnetic ring.

3. The scanning device as recited in claim 2, wherein a plurality of winding coils of the coil assembly are positioned at an outer periphery of the magnetic loop and distributed around the magnetic loop.

4. The scanning device as claimed in claim 3, wherein said restoring member is located on a side of said coil assembly remote from said magnetic ring.

5. The scanning device as recited in claim 2, wherein a plurality of winding coils of the coil assembly are located on an inner circumference of the magnetic loop, the magnetic loop surrounding the plurality of winding coils.

6. The scanning device as claimed in claim 5, wherein said restoring member is located on a side of said magnetic ring away from said coil assembly.

7. A scanning device as claimed in any one of claims 2 to 6, characterized in that the rotor comprises the magnetic ring and the stator comprises the coil assembly.

8. The scanning device as claimed in claim 7, wherein the rotor is deflected about the rotational axis from the equilibrium position to the predetermined position by a first action, wherein the first action is an interaction between a current carried in a winding coil of the coil assembly and a magnetic field of the magnetic loop.

9. The scanning device of claim 7, wherein the reply assembly comprises: at least one magnetic part;

the rotor is driven to return to the equilibrium position around the rotating shaft at least under a second action, wherein the second action comprises interaction between a magnetic field of the magnetic part and a magnetic field of the magnetic ring.

10. The scanning device as claimed in claim 9, wherein the magnet corresponding to the magnetic portion and the magnetic portion are attracted to each other to maintain the magnetic ring in the equilibrium position.

11. The scanning device according to claim 9, wherein when said rotor is deflected to a predetermined position, current flow through winding coils in said coil assembly is interrupted, and said rotor is driven by said second action to return to said equilibrium position.

12. The scanning device according to claim 9, wherein when the rotor is deflected to a predetermined position, the rotor is driven by the first and second effects to return to the equilibrium position by cutting off the current transmitted in the winding coils of the coil assembly and inputting a reverse current to the winding coils of the coil assembly.

13. The scanning device of claim 9, wherein the reply assembly further comprises: an excitation coil adapted to adjust a magnetic field of the corresponding magnetic portion such that the restoring assembly forms a predetermined effective magnetic field.

14. The scanning device of claim 13, further comprising: a detection unit adapted to detect an effective magnetic field of the return assembly;

and the adjusting unit is used for controlling the exciting coil to adjust the magnetic field of the magnetic part based on the detection result of the detecting unit so as to enable the restoring assembly to form a preset effective magnetic field.

15. The scanning device of claim 1, further comprising: the counterweight is positioned on one side of the rotor, which is far away from the scanning mirror, so that the center of gravity of the rotor, the scanning mirror and the counterweight is positioned at the position of the rotating shaft.

16. The scanning device according to claim 15, wherein the number of the scanning mirrors is one or more, and the one or more scanning mirrors are disposed opposite to the weight member.

17. The scanning device according to claim 16, wherein the number of said scanning mirrors is two; the mirror surfaces of the two scanning mirrors form a preset angle.

18. A lidar, comprising:

a light emitting device adapted to generate probe light;

a scanning device according to any one of claims 1 to 17,

the scanning device reflects the detection light to a three-dimensional space and reflects echo light formed by a target in the three-dimensional space reflecting the detection light;

a light receiving device adapted to detect the echo light.

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