SUMMERY OF THE UTILITY MODEL
The utility model provides a many cameras module and terminal to among the solution prior art, for a plurality of camera modules of arranging, need open a plurality of holes on the shell at terminal, influence pleasing to the eye and shell intensity problem.
In order to solve the above problems, the present invention provides a multi-camera module, which comprises a bracket, a first lens module, a second lens module, a sensor and a transmission part connected with the bracket; the first lens module and the second lens module are arranged on the support along a first direction, the transmission part is connected with the support and drives the support to move along the first direction, so that the first lens module or the second lens module moves to the position above the sensor, and the sensor is used for achieving different camera shooting functions with the first lens module or the second lens module.
In one possible embodiment, the sensor is a light sensor or an image sensor.
In one possible embodiment, the first lens module is a telephoto lens module, and the second lens module is a wide-angle lens module.
In one possible implementation, the multi-camera module includes a circuit board, the sensor is mounted on the circuit board, and the first lens module or the second lens module is disposed on a side of the sensor away from the circuit board.
In a possible implementation manner, the multiple camera modules further include a base, the base is a base of the first lens module and the second lens module, and the support is connected to the base.
In a possible implementation mode, the transmission part comprises a micro motor and a transmission rod, the transmission rod is a threaded rod, a threaded hole is formed in the support, the support is installed on the transmission rod through the threaded hole, the transmission rod is connected with the micro motor, the micro motor drives the transmission rod to rotate, and the support is pushed to move through the cooperation of the threaded rod and the threaded hole.
In a possible implementation manner, the transmission part includes a micro motor and a transmission rod, the bracket is fixedly mounted on the transmission rod, the transmission rod is connected with the micro motor, and the micro motor drives the transmission rod to extend and retract so as to drive the bracket to move.
In one possible embodiment, the first direction is the same as the length direction of the transmission rod.
In a possible implementation manner, the multiple camera modules further include at least one third lens module, the at least one third lens module and the first lens module are mounted on the bracket in parallel, and the transmission portion can drive the at least one third lens module to move, so that one of the at least one third lens module and the sensor work together.
The utility model also provides a terminal, including body and the many camera modules of the aforesaid, the body includes the shell, be equipped with the lens hole on the shell, many camera modules adorn in this is internal, transmission portion drives first camera lens module or second camera lens module remove, so that the camera lens of first camera lens module or second camera lens module with the sensor with the lens hole is aimed at simultaneously.
To sum up, the utility model provides a pair of many cameras module for in the terminal. A plurality of camera lens modules can remove under the effect of transmission portion to make different camera lens modules aim at the lens hole on the terminal shell as required, a plurality of camera lens modules can share same lens hole, need not to set up many trompils on the shell at terminal, have both guaranteed terminal shell's pleasing to the eye, can not influence the intensity of shell because the trompil is too much again.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.
The utility model provides a many camera modules and include the terminal of many camera modules.
Referring to fig. 1, the present invention provides amulti-camera module 100 including abracket 10, afirst lens module 20A, asecond lens module 20B, asensor 30 and atransmission portion 40 connected to thebracket 10. Thefirst lens module 20A and thesecond lens module 20B are disposed on thebracket 10 along a first direction, thetransmission portion 40 is connected to thebracket 10 and drives thebracket 10 to move along the first direction, so that thefirst lens module 20A or thesecond lens module 20B moves above thesensor 30, and thesensor 30 is used for implementing different camera functions with thefirst lens module 20A or thesecond lens module 20B.
In this embodiment, thetransmission portion 40 is used for driving thebracket 10 to move, so as to drive thefirst lens module 20A or thesecond lens module 20B to move to a position right above thesensor 30, and the lens optical axis of thefirst lens module 20A or thesecond lens module 20B aligned with thesensor 30 is coaxial with thesensor 30, so that thesensor 30 can be ensured to completely receive light and images entering the lens module. Thesensor 30 and thefirst lens module 20A or thesecond lens module 20B are made to work together, which means that thesensor 30 is made to form an image for thefirst lens module 20A or thesecond lens module 20B in work to process the image, and the camera function of the camera module is formed together, and the camera module can also be understood as being formed together. The two lens modules of the embodiment commonly use one sensor, so that the cost of using the sensor is reduced. When themulti-camera module 100 is applied to a terminal, only one lens hole needs to be formed in the housing of the terminal, and thefirst lens module 20A or thesecond lens module 20B is moved and aligned with the lens hole, that is, thefirst lens module 20A and thesecond lens module 20B share one lens hole, and thefirst lens module 20A or thesecond lens module 20B is moved and aligned with the lens hole as required during use. A plurality of lens holes do not need to be formed in the shell of the terminal, so that the attractiveness of equipment is not affected, and the strength of the shell is not affected.
Referring to fig. 1, themulti-camera module 100 includes acircuit board 50, asensor 30 mounted on thecircuit board 50, and afirst lens module 20A or asecond lens module 20B disposed on a side of thesensor 30 away from thecircuit board 50. In this embodiment, thefirst lens module 20A is disposed on a side of thesensor 30 away from thecircuit board 50, and thefirst lens module 20A and thesecond lens module 20B further include a focusing motor electrically connected to thecircuit board 50 to control the lenses of thefirst lens module 20A and thesecond lens module 20B to extend and retract for focusing. Thesensor 30 and thefirst lens module 20A or thesecond lens module 20B work together through the control device on the circuit board, and the camera module can perform the camera shooting function. Thecircuit board 50 may also transmit an electrical signal related to an image or video captured by thefirst lens module 20A or thesecond lens module 20B to a terminal connected to thecircuit board 50.
Further, thesensor 30 is a photo sensor or an image sensor. Specifically, the optical sensor uses a photoelectric element as a detection element, and can convert an optical signal into an electrical signal, and the image sensor can be a CCD sensor or a CMOS sensor. The shape of thesensor 30 is not limited herein as long as it can satisfy that the light entering thefirst lens module 20A or thesecond lens module 20B moved above thesensor 30 can be incident to thesensor 30. In this embodiment, thesensor 30 is an image sensor. Thefirst lens module 20A and thesecond lens module 20B share onesensor 30, which reduces the manufacturing cost of themulti-camera module 100 and the use cost of users.
In this embodiment, thefirst lens module 20A is a telephoto lens module, and thesecond lens module 20B is a wide-angle lens module. When a user needs a telephoto lens, the telephoto lens module is moved above thesensor 30, light passing through the telephoto lens is incident on thesensor 30, and thesensor 30 and the telephoto lens module work together. When a user needs the wide-angle lens, the wide-angle lens module is moved above thesensor 30, light passing through the wide-angle lens is incident on thesensor 30, and thesensor 30 and the wide-angle lens module work together.
In another embodiment, themulti-camera module 100 further includes at least one third lens module (not shown), the at least one third lens module is mounted on thebracket 10 in parallel with thefirst lens module 20A, and thetransmission portion 40 can drive the at least one third lens module to move above thesensor 30, so that one of the at least one third lens module and thesensor 30 work together. Specifically, one third lens module may be provided, or two or more third lens modules may be provided. The third lens module can be a macro lens module or a fisheye lens module. When the number of the third lens modules is multiple, the macro lens module and the fisheye lens module can be combined. The plurality of lens modules can meet different requirements of users, and different lens modules can be called as required to adapt to shooting without scenes. Even if a plurality of lens modules exist at the same time, only one lens hole is needed for the terminal.
Referring to fig. 1 and 2, themulti-camera module 100 further includes abase 60, thebase 60 is a base of thefirst lens module 20A and thesecond lens module 20B, thesupport 10 is connected to thebase 60, and a moving direction of thesupport 10 is the same as an arrangement direction of thefirst lens module 20A and thesecond lens module 20B. Specifically, the moving direction of the bracket is the same as the arrangement direction of thefirst lens module 20A and thesecond lens module 20B, so that thefirst lens module 20A and thesecond lens module 20B can be ensured to correspond to thesensor 30 one by one. Thebase 60 is a rectangular frame, thefirst lens module 20A and thesecond lens module 20B are accommodated in thebase 60, thebracket 10 and thebase 60 are fixedly connected, and the connection mode can be welding, screwing or clamping, and can also be integrated into one piece. Thebase 60 can be used as a lens base for thefirst lens module 20A and thesecond lens module 20B, which can save space. Thetransmission portion 40 drives thebracket 10 to move, so as to drive thebase 60 connected to thebracket 10 to move, and thefirst lens module 20A and thesecond lens module 20B move along with thebase 60, so that thefirst lens module 20A or thesecond lens module 20B moves onto thesensor 30. In this embodiment, thebase 60 is a base on which thefirst lens module 20A and thesecond lens module 20B are mounted on thebase 60, and thesupport 10 only needs to be connected to thebase 60 and does not need to be connected to thefirst lens module 20A or thesecond lens module 20B, so that thefirst lens module 20A and thesecond lens module 20B can be kept stable in the moving process, and meanwhile, the structural space of thesupport 10 can be saved.
Referring to fig. 1, thetransmission portion 40 includes amicro motor 402 and atransmission rod 401, thetransmission rod 40 is a threaded rod, thebracket 10 is provided with a threaded hole, thebracket 10 is mounted on thetransmission rod 401 through the threaded hole, thetransmission rod 401 is connected with themicro motor 402, themicro motor 402 drives thetransmission rod 401 to rotate, and thebracket 10 is pushed to move through the threaded rod and the threaded hole. Specifically, in this embodiment, the connection mode between thebracket 10 and thetransmission rod 401 is that the micro-motor 402 is connected in a threaded transmission manner to control thetransmission rod 401 to rotate, so as to drive thebracket 10 to move along thetransmission rod 401 toward or away from the micro-motor 402, that is, the transmission rod moves in the length direction. In this embodiment, thedriving rod 401 rotates clockwise to drive thebracket 10 to move away from the micro-motor 402; thedriving rod 401 rotates counterclockwise, which drives thebracket 10 to move toward themicro-motor 402. In other embodiments, thedriving rod 401 can rotate clockwise to drive thebracket 10 to move toward the direction close to the micro-motor 402; thedrive link 401 rotates counterclockwise, causing thecarriage 10 to move away from the micro-motor 402. In this embodiment, thedrive rod 401 adopts the threaded rod to make the support drive the lens module and remove more steadily, and the precision is high.
In another embodiment, the transmission rod is connected with a micro motor, and the micro motor drives the transmission rod to stretch and contract relative to the micro motor so as to drive the bracket to move. Specifically, the support can be fixed on the transmission rod through welding, screwing or clamping, the micromotor drives the transmission rod to stretch, and the transmission rod stretches and retracts to drive the support to move towards the direction close to or far away from the micromotor. In this embodiment, support and transfer line fixed connection have increased the stability of support and transfer line relation of being connected, on the one hand for the support can bear higher load, and on the other hand makes the support still can stable connection on the transfer line in the repetitive motion process, increase of service life. In addition, telescopic transfer line simple structure, easily processing and installation, and efficient, the reaction is sensitive, can quick response after receiving the instruction to drive support quick travel to relevant position.
Referring to fig. 2, the first direction is the same as the length direction of thetransmission rod 401. That is, the arrangement direction of thefirst lens module 20A and thesecond lens module 20B is the same as the length direction of thetransmission rod 401. The driving rod of the above embodiment can smoothly drive thefirst lens module 20A and thesecond lens module 20B to move along the first direction, so as to switch thefirst lens module 20A and thesecond lens module 20B.
Referring to fig. 3-4, the present embodiment provides a terminal 200, which includes abody 21 and themulti-camera module 100 of any of the above embodiments. Thebody 21 includes ahousing 211, alens hole 22 is formed in thehousing 211, themulti-camera module 100 is installed in thebody 21, and thetransmission portion 40 drives thefirst lens module 20A or thesecond lens module 20B to move, so that the lens of thefirst lens module 20A or thesecond lens module 20B is aligned with thesensor 30 and thelens hole 22 at the same time.
Specifically, the terminal 200 may be a mobile phone, a tablet computer, a watch, or the like. Themulti-camera module 100 can be used as a front camera or a rear camera, in this embodiment, themulti-camera module 100 is used as a rear camera for example, and themulti-camera module 100 is installed in thebody 21 along the length direction of the terminal. The number of the lens holes 22 is only one, the lens holes 22 are formed at the position aligned with thesensor 30, when thefirst lens module 20A needs to be used, thetransmission portion 40 drives thefirst lens module 20A to move to the position above thesensor 30 and to be aligned with the lens holes 22, light enters thefirst lens module 20A through the lens holes 22, and thefirst lens module 20A and thesensor 30 work together to achieve shooting. When thesecond lens module 20B needs to be used, thetransmission portion 40 drives thesecond lens module 20B to move to a position above thesensor 30 and align with thelens hole 22, the light enters thesecond lens module 20B through thelens hole 22, and thesecond lens module 20B and thesensor 30 work together to realize shooting. In this embodiment, a plurality of camera modules share onesensor 30 and onelens hole 22, so that on one hand, the manufacturing cost of the camera modules and the use cost of users are reduced; on the other hand, the terminal housing does not need to be provided with a plurality of lens holes 22, and the terminal appearance and the mechanical strength of the housing are not affected. In other embodiments, themulti-camera module 100 may also be a front camera, so that only one camera hole is needed, and the screen ratio is increased.
In another embodiment, themulti-camera module 100 is mounted in thebody 21 along the width direction of the terminal 200. Specifically, thefirst lens module 20A and thesecond lens module 20B are arranged along the width direction of the terminal, and the length direction of thetransmission rod 401 is consistent with the width direction of the terminal. The drivingrod 401 drives thebracket 10 to move along the width direction of the terminal 200, so as to drive thefirst lens module 20A or thesecond lens module 20B to move above thesensor 30 and align with thelens hole 22, and the light enters thefirst lens module 20A or thesecond lens module 20B through thelens hole 22 to work together with thesensor 30, thereby realizing shooting. In this embodiment, the specific arrangement positions of themultiple camera modules 100 can be adjusted according to the internal structure of the terminal 200, so that the internal space can be better utilized, and the effect of saving the occupied space is achieved.
The embodiments of the present invention have been described in detail, and the principles and embodiments of the present invention have been explained herein using specific embodiments, and the above description of the embodiments is only used to help understand the method and the core idea of the present invention; meanwhile, for the general technical personnel in the field, according to the idea of the present invention, there are changes in the specific implementation and application scope, to sum up, the content of the present specification should not be understood as the limitation of the present invention.