Patent Application
20230229059
The present disclosure relates to the technical field of cameras, and in particular, to an autofocus device based on a movable sensor driven by an SMA wire.
With the development of portable electronic devices such as mobile phones or tablet computers, the requirements for accompanying camera functions have been relatively increased.
The existing camera includes a camera lens module and a driving device. The camera lens module is disposed inside a predetermined mounting member and is located on an optical axis, and is movable toward an approaching object in a sliding or spirally rotatable manner. The driving device is configured to drive the camera lens to move along the optical axis. The existing camera is driven mainly by a magnet and coil structure, which makes the mechanism and the movement manner for the movement of the camera lens module too complicated, is difficult to have a reduced size, and is unable to meet the requirements for product miniaturization.
The present disclosure provides an autofocus device based on a movable sensor driven by an SMA wire. The autofocus device includes a housing, a lens, a sensor assembly, a driving element, and an elastic element. The housing includes a first mounting groove and a second mounting groove communicating with the first mounting groove. The lens is fixed inside the first mounting groove. The sensor assembly is provided inside the second mounting groove and reciprocally movable along a direction of an optical axis of the lens. The driving element includes the SMA wire having two end portions fixed on the housing and a middle portion connected to the sensor assembly, the middle portion is further away from the lens than the two end portions, and the SMA wire is configured to drive the sensor assembly to move towards the lens under an actuation force generated by thermal shrinking of the SMA wire. The elastic element is connected to the sensor assembly and configured to provide the sensor assembly with a restoring force in a direction away from the lens when the SMA wire is cooled to expand and return to an initial length, so that the sensor assembly returns to an initial position.
As an improvement, the driving element further includes a protrusion that has an end fixed to a side of the sensor assembly facing away from the lens and another end recessed to form an actuation groove. A groove surface of the actuation groove includes a first position end and second position ends, and the first position end is farther from the sensor assembly than each of the second position ends. The SMA wire is bridged in the actuation groove and attached to the groove surface of the actuation groove.
As an improvement, the first position end is located at a middle of the groove surface of the actuation groove, and the second position ends are located at two opposite sides of the groove surface of the actuation groove.
As an improvement, the first position end is located on an extension line of the optical axis of the lens.
As an improvement, the SMA wire has two opposite ends and a middle movable end located between the two opposite ends, the two opposite ends of the SMA wire are fixed to the housing, and the middle movable end of the SMA wire is tightly suspended in the actuation groove.
As an improvement, the two opposite ends of the SMA wire are fixed by clamping, bonding, or welding.
As an improvement, the autofocus device further includes a metal element provided on the housing at a position close to an opening of the second mounting groove, and configured to fix the two end positions of the SMA wire.
As an improvement, the elastic element includes at least one elastic sheet provided between the sensor assembly and a bottom surface of the second mounting groove. Each of the at least one elastic sheet includes an elastic portion and a fixed portion, the fixed portion is provided at an end of the sensor assembly extending into the second mounting groove, and the elastic portion is connected to the fixed portion and extends in a direction away from the sensor assembly.
As an improvement, the elastic element includes at least two elastic sheets that are symmetrically arranged.
As an improvement, the lens is fixed inside the first mounting groove by a screw connection.
Description of reference signs:
The embodiments of the present invention will be described in details hereinafter. Examples of the embodiments are shown in the accompanying drawings, in which the same or similar reference signs indicate the same or similar elements or elements with the same or similar functions. The embodiments described in the following with reference to the drawings are exemplary and merely used for explaining the present disclosure, and are not intended to limit the present disclosure thereto.
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The housing 10 is configured to accommodate the lens 20 and the sensor assembly 30, and a first mounting groove 11 and a second mounting groove 12 communicating with each other are provided inside the housing 10. Each of the first mounting groove 11 and the second mounting groove 12 forms openings at two opposite ends of the housing 10, and the lens 20 and the sensor assembly 30 are mounted in the housing 10 through the respective openings.
The lens 20 is fixed in the first mounting groove 11, and an inner contour surface of the first mounting groove 11 matches an outer contour surface of the lens 20. In some embodiments, the lens 20 is a cylindrical structure and thus the first mounting groove 11 is a cylindrical groove. In this embodiment, the lens 20 is fixed in the first mounting groove 11, and is unable to move during a focus process. In some embodiments, the lens 20 is fixed in the first mounting groove 11 in a threaded manner. The outer contour surface of the lens 20 is formed with an external thread, and the inner contour surface of the first mounting groove 11 is formed with an internal thread matching the external thread, so that the lens 20 can be screwed into the first mounting groove 11. When the lens 20 is required to be detached, the lens 20 is merely required to be rotated in a reverse direction, thereby conveniently and quickly disassembling the lens.
The sensor assembly 30 is disposed inside the second mounting groove 12 and is reciprocally movable along a direction of an optical axis of the lens 20. An inner contour surface of the second mounting groove 12 matches an outer contour surface of the sensor assembly 30. In this embodiment, the sensor assembly 30 is a cubic structure and thus the second mounting groove 12 is a cubic groove. In this embodiment, the sensor assembly 30 is disposed in the second mounting groove 12 and is slidable along the direction of the optical axis of the lens 20. The second mounting groove 12 may be provided with a guiding and limiting device therein, which is conventional means of sliding pairs and will not be further described herein.
The driving element includes a SMA wire 40 and an actuation mechanism. The number of the SMA wire may be one or more, as long as the driving function can be achieved, which is not limited herein. The SMA wire 40, such as nickel-titanium memory alloy wire, is a martensite structure at room temperature. When the temperature is raised, the SMA wire 40 will undergo a phase change transforming from a martensite structure to an austenite structure, and the SMA wire will decrease both in length and electrical resistance. When the temperature is decreased, the SMA wire 40 will undergo a phase change transforming from an austenite structure to a martensite structure, and the wire will increase both in length and electrical resistance. The two processes may be repeated. During the phase change, linearity between the temperature and strain of the SMA wire 40 is poor, but the resistance and strain of the SMA wire 40 have a linear relationship within a certain temperature range. Therefore, the length of the SMA wire 40 can be accurately controlled by controlling the electrical resistance of the SMA wire 40, and a position and a movement distance of the driving element is calculated based on the electrical resistance of the SMA wire 40.
An end of the actuation mechanism is connected to the sensor assembly 30, and another end of the actuation mechanism is connected to the SMA wire 40. The actuation mechanism may be integrally formed with the sensor assembly 30 into one piece or separately formed as individual structures, which is not limited herein. The actuation mechanism is provided with a convex surface facing away from the sensor assembly 30, and the SMA wire 40 is tightly attached to the convex surface, such that the SMA wire 40 is bent toward a side facing away from the sensor assembly 30. The SMA wire 40 is heated by a control system to shrink due to the heat, and thus the length of the SMA wire 40 becomes smaller. As a result, the bent shape of the SMA wire is straightened to generate an actuation force that is transferred to the sensor assembly 30 through the actuation mechanism, such that the sensor assembly 30 moves toward the lens 20, thereby achieving autofocusing. When the SMA wire 40 is powered off, the temperature of the SMA wire 40 is decreased and the length thereof becomes larger, and the sensor assembly 30 returns to its initial position.
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The working principle of the autofocus device according to the present disclosure is described thereinafter.
The SMA wire 40 is heated by the control system to shrink due to the heat, such that the length of the SMA wire 40 is shortened and the SMA wire 40 is straightened from a bended shape. In this way, the generated actuation force is transferred to the sensor assembly 30 through the protrusion 50 such that the sensor assembly 30 moves toward the lens 20, thereby achieving autofocusing. At this time, the elastic portion 601 of the elastic sheet 60 is compressed under a force to accumulate the elastic restoring force. When the SMA wire 40 is powered off, the temperature of the SMA wire 40 is decreased, the length of the SMA wire 40 is elongated, and the elastic restoring force of the elastic sheet 60 is released to provide the sensor assembly 30 with a force in the direction away from the lens 20, thereby returning the sensor assembly 30 to the initial position.
The structures, features, and effects of the present invention are described above in details based on the embodiments shown in the drawings. The above descriptions are merely some of the embodiments of the present disclosure, and the scope of the present disclosure will not be limited by the embodiments of the accompanying drawings. Any changes or modified equivalent embodiments with equivalent changes that are made in accordance with a concept of the present disclosure do not exceed the scope defined by the specification and drawings, shall fall within the scope of the present disclosure.
