阅读说明：本技术 一种基于压电驱动的叶片式快速机械光开关 (Vane type rapid mechanical optical switch based on piezoelectric drive ) 是由 王立勇 赵显� 李志强 于 2020-11-23 设计创作，主要内容包括：本发明涉及一种基于压电驱动的叶片式快速机械光开关,主要包括孔径光阑和压电陶瓷堆栈,所述孔径光阑安装在金属外壳的内部,所述孔径光阑的叶片控制杆的两侧分别设有压电陶瓷堆栈和回位弹簧,所述孔径光阑的通光孔到其固定螺丝的距离大于压电陶瓷堆栈到孔径光阑的的主固定螺丝间的距离,所述压电陶瓷堆栈与外部电源连接。其优点在于,克服了以往机械光开关响应速度慢的问题,且透射光光功率没有损耗,光路也不发生改变,这极大地简化了光路,节省了人力和物力成本,提高了激光的使用效率,由此能够满足目前精密测量物理和量子光学实验等对机械开关响应速度有极高要求领域的使用需求。(The invention relates to a piezoelectric-drive-based blade-type rapid mechanical optical switch which mainly comprises an aperture diaphragm and a piezoelectric ceramic stack, wherein the aperture diaphragm is arranged inside a metal shell, the piezoelectric ceramic stack and a return spring are respectively arranged on two sides of a blade control rod of the aperture diaphragm, the distance from a light through hole of the aperture diaphragm to a fixing screw of the aperture diaphragm is greater than the distance from the piezoelectric ceramic stack to a main fixing screw of the aperture diaphragm, and the piezoelectric ceramic stack is connected with an external power supply. The laser has the advantages that the problem of low response speed of the traditional mechanical optical switch is solved, the optical power of transmitted light is not lost, and the optical path is not changed, so that the optical path is greatly simplified, the labor and material cost is saved, and the use efficiency of laser is improved, thereby meeting the use requirements of the fields with high requirements on the response speed of the mechanical switch, such as the current precision measurement physics and quantum optical experiments.)

1. The utility model provides a quick mechanical photoswitch of vane type based on piezoelectricity drive which characterized in that, includes aperture diaphragm and piezoceramics stack, aperture diaphragm installs the inside at metal casing, the both sides of the blade control lever of aperture diaphragm are equipped with piezoceramics stack and return spring respectively, the distance that leads to the unthreaded hole of aperture diaphragm to its set screw is greater than the distance of piezoceramics stack to the main set screw of aperture diaphragm, piezoceramics stack is connected with external power source.

2. The piezoelectric-driven blade-type rapid mechanical optical switch according to claim 1, wherein the piezoelectric ceramic stack is fixed in the metal housing by a fixing bracket and contacts with the blade control rod of the aperture stop.

3. The piezoelectric-driven vane type fast mechanical optical switch as claimed in claim 1, wherein the vane control rod is provided with a through hole, the return spring is sleeved on a fixed rod, one end of the fixed rod is fixed on the metal shell, and the other end of the fixed rod extends into the through hole of the vane control rod, and the vane control rod can be seen to move left and right in the horizontal direction when the mechanical optical switch performs an on/off operation.

4. The piezoelectric-drive-based vane type fast mechanical optical switch as claimed in claim 1, wherein the piezoelectric ceramic stack is a stack of a plurality of ring-shaped piezoelectric ceramic sheets for generating piezoelectric deformation.

5. The piezoelectric-drive-based blade type rapid mechanical optical switch as claimed in claim 1, wherein the metal housing is provided with an electrode interface, and the piezoelectric ceramic stack is connected to an external power source through the electrode interface.

6. The piezoelectric-driven blade-type fast mechanical optical switch as claimed in claim 1, wherein the aperture stop has at least two metal blades.

Technical Field

The application relates to the field of optical switches, in particular to a vane type rapid mechanical optical switch based on piezoelectric driving.

Background

The conventional mechanical optical switch is driven by heat, electricity, magnetism, etc. and the mechanical motion of the object is used to make or block light, so as to realize the on/off operation of light. At present, the mainstream mechanical optical switch has some defects, the switching speed of the more prominent problem is relatively slow, generally more than 10 milliseconds, which is mainly because most mechanical optical switches are driven by electric motors, so that the reason of slow response is caused. In order to realize fast switching of light beams, some mechanical optical switches adopt a thin metal sheet as an action shutter, which is helpful for improving the response speed due to the light weight of the thin metal sheet, but the thin metal sheet cannot bear high-power laser and has a small light-passing hole. The mechanical optical switch also uses one or more rotating motors to perform switching operation, the switching speed can reach the microsecond level, certain vibration is generated when the switching operation is performed, the clear aperture is small, a light beam needs to be focused before the mechanical optical switch is used, more lenses and extremely fine calibration are needed, and in addition, the size of the mechanical optical switch is too large, so that the mechanical optical switch is not suitable for a miniaturized optical path.

Disclosure of Invention

Based on the problems, the optical switch has a small size which can reach about 10 microseconds of ultra-fast response speed, and can meet the requirements of most optical switches on response time. The technical content is as follows:

the utility model provides a quick mechanical photoswitch of vane type based on piezoelectricity drive, includes aperture diaphragm and piezoceramics stack, the inside at metal casing is installed to the aperture diaphragm, the both sides of the blade control lever of aperture diaphragm are equipped with piezoceramics stack and return spring respectively, the distance that leads to the unthreaded hole of aperture diaphragm to its fixed screw is greater than the distance of the main fixed screw of piezoceramics stack to aperture diaphragm, the piezoceramics stack is connected with external power source.

Furthermore, the piezoelectric ceramic stack is fixed in the metal shell through a fixing support and is in contact with a blade control rod of the aperture diaphragm.

Furthermore, a through hole is formed in the blade control rod, the return spring is sleeved on the fixed rod, one end of the fixed rod is fixed on the metal shell, the other end of the fixed rod extends into the through hole of the blade control rod, and the blade control rod can be seen to move left and right in the horizontal direction when the mechanical optical switch performs on/off operation.

Furthermore, the piezoelectric ceramic stack is formed by stacking a plurality of annular piezoelectric ceramic pieces and is used for generating piezoelectric deformation.

Furthermore, an electrode interface is arranged on the metal shell, and the piezoelectric ceramic stack is connected with an external power supply through the electrode interface.

Furthermore, the number of the metal blades of the aperture diaphragm is not less than two.

Advantageous effects

1. The mechanical optical switch is characterized in that piezoelectric driving is adopted, and a plurality of annular piezoelectric ceramic pieces are utilized, so that a piezoelectric ceramic stack is formed, and the maximum displacement stroke of the piezoelectric ceramic is improved. Compared with the traditional mechanical optical switch, the design has sensitive response and lower manufacturing cost.

2. The mechanical optical switch has the innovation points that by means of the lever principle and the design of the aperture diaphragm of the plurality of arc-shaped metal blades, on one hand, the requirement on the displacement stroke of the piezoelectric ceramic stack is greatly reduced, so that the metal blades in the aperture diaphragm can move greatly under the condition of small displacement of the piezoelectric ceramic stack, and the construction volume is saved; on the other hand, through adjusting outside drive voltage, can realize the nimble regulation to a plurality of arc metal blade to make logical unthreaded hole from closed completely, to partly closed or open completely, and then can carry out continuous adjustment to input optical power, realize that input optical power is from 0 to the biggest continuous adjustable, more nimble, convenient in the use, this light path in optical experiment and application is adjusted the aspect, especially precision measurement physics and quantum optics experiment field have very important meaning.

3. When the mechanical optical switch executes on/off operation, the optical power of transmitted light is not lost, and the optical path is not changed, so that the optical path is greatly simplified, the labor and material cost is saved, and the use efficiency of laser is improved.

4. The mechanical optical switch has a large light through hole, can meet the requirements of using when the incident light power and the light spot are large, and laser does not have wavefront distortion and waveform change when passing through the mechanical switch.

5. The mechanical optical switch has wider bandwidth and can be theoretically effective to all wavelength optical fields passing through the light through hole. Compared to acousto-optic modulators (AOMs) or electro-optic modulators (EOMs), the wavelength is not limited. In actual use, different optical wavelengths need to correspond to different AOMs or EOM crystals and different microwave driving sources, and the traditional AOM and EOM are very complex in use and easy to make mistakes.

Drawings

FIG. 1 is a schematic structural diagram of the present application;

FIG. 2 is a schematic diagram of the present application;

wherein in the figure: 1-electrode interface, 2-piezoelectric ceramic stack, 3-fixed bolster, 4-metal casing, 5-metal blade, 6-set screw, 7-fixed snap ring, 8-main set screw, 9-dead lever, 10-return spring, 11-blade control lever, 12-logical unthreaded hole.

A is the length of the piezoelectric ceramic stack, B is the distance between the piezoelectric ceramic stack and the main fixing screw of the aperture diaphragm, C is the distance between the light-passing hole of the aperture diaphragm and the fixing screw (which can also be regarded as the radius of the metal blade), and D is the width of the metal shell.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and examples.

The utility model provides a quick mechanical photoswitch of vane type based on piezoelectricity drive, includes aperture diaphragm and piezoceramics stack 2, and the aperture diaphragm includes eight metal blades 5, metal blades 5 are fixed in fixed snap ring 7, and both are fixed through set screw 6, and 11 one end of blade control lever are fixed on fixed snap ring 7 through main set screw 8, and the other end contacts with piezoceramics stack 2. When the aperture diaphragm is opened, all the metal blades 5 can be scattered around the light through hole to the periphery of the fixed clamping ring 7. The aperture diaphragm is installed in metal casing 4, the both sides of the blade control lever 11 of aperture diaphragm are equipped with piezoceramics stack 2 and return spring 10 respectively, piezoceramics stack 2 is the stack of a plurality of annular piezoceramics piece for produce piezoelectricity and deform. The piezoelectric ceramic stack 2 is fixed in the metal shell 4 through the fixing support 3 and is in contact with the blade control rod 11. The blade control rod 11 is provided with a through hole, the return spring sleeve 10 is arranged on the fixed rod 9, one end of the fixed rod 9 is fixed on the metal shell 4, and one end of the fixed rod extends into the through hole of the blade control rod 11, so that the blade control rod 11 can be regarded as moving left and right in the horizontal direction when the mechanical optical switch performs on/off operation.

The distance from the light through hole 12 of the aperture diaphragm to the fixing screw 6 of the aperture diaphragm is larger than the distance from the piezoelectric ceramic stack 2 to the main fixing screw 8 of the aperture diaphragm, and according to the principle of long and short arms of a lever, the small movement of the piezoelectric ceramic stack 2 can cause the larger displacement of all the metal blades 5 in the aperture diaphragm, so that the larger light through hole 12 is formed.

And the metal shell 4 is provided with an electrode interface 1, and the piezoelectric ceramic stack 2 is connected with an external power supply through the electrode interface 1.

The main components in the present design and their functions are described below:

piezoelectric ceramic stack 2: the piezo-ceramic stack 2 is a linear superposition of several piezo-ceramic plates, which can produce a larger piezo-deformation. The piezoelectric ceramic piece is an information functional ceramic material capable of converting mechanical energy and electric energy into each other. When a certain external driving electric field is applied to the piezoelectric ceramic piece, the positive and negative charge centers inside the piezoelectric ceramic piece generate relative displacement, so that the piezoelectric ceramic piece generates integral deformation, namely geometric deformation. When the electric field is not very strong, the deformation is linear with the strength of the external electric field.

Metal blade 5: the metal blade 5 is made of a metal alloy material and is subjected to a black anodizing treatment, which is very light and thin on the one hand and can withstand a large optical power on the other hand.

Table 1 shows a specific design value of a piezoelectric-driven vane-type fast mechanical optical switch, and the specific value can be optimized and adjusted according to product requirements and applications, and is not meant to limit the embodiments of the present invention. The column "reference number" in the table is numbered according to the size pitch of each component.

TABLE 1

Reference numerals	A	B	C	D
					Length (mm)	2	8	48	110

Through the specific embodiment, the quick mechanical optical switch which is compact in structure, high in response speed, high in adjustment precision, free of power loss and wavefront distortion can be obtained.

Principle of operation

When no external voltage is applied, the blade control rod 11 is at the original point, the return spring 10 is in a normal pressure state, the light through hole 12 in the center of the metal blade 5 is opened at the moment, and the mechanical switch is in an 'open' state; when an external voltage is applied to the piezoelectric ceramic stack 2, the blade control rod 11 is pushed to move rightward, so that the blade control rod deviates from the original point, the return spring 10 is compressed, the metal blade 5 is in a compressed state, the light through hole in the center of the metal blade 5 is completely or partially closed under the combined action of the eight metal blades 5, and the mechanical switch is in a state of complete closing or partial closing. When the applied voltage is turned off, the metal blade 5 will return to the original state and position under the action of the return spring 10, and the mechanical switch is in the "open" state again, so that the controllable mechanical optical on/off operation is realized.

The design mainly utilizes the quick response characteristic of the piezoelectric ceramic stack 2 under the drive of external voltage, so that the mechanical optical switch can quickly respond; another innovation of the design is that a long-arm and short-arm lever with an asymmetric structure is formed by the eight metal blades 5, the piezoelectric ceramic stack 2 and the blade control rod 11, so that the clear aperture and the switching efficiency are greatly increased. In a specific design, the number of the metal blades 5 can be increased or decreased as appropriate to ensure the stability and the adjustment sensitivity of the optical switch.

If C/B is greater than 6, the long-and-short arm lever effect is obvious, in this embodiment, C/B is 8, and the response time is 9 microseconds, which can meet the application of many optical switches with requirements on response time.

The maximum displacement stroke of the piezoelectric ceramic stack 2 can reach 0.33 mm, the displacement amount of the tail end of a single metal blade 5 can be approximately 0.33 × 8-2.64 mm, the design of eight metal blades further improves the clear aperture and the switching efficiency, and the clear holes 12 with the diameter of 1-2 cm can be formed.

The foregoing is only a preferred embodiment of the present invention and is not intended to limit the present invention, and many other embodiments may be made by modifying or adjusting the parameters of the present invention in its structure, and all embodiments need not be listed herein. The scope of the invention is, therefore, indicated by the appended claims.