CN210603796U - Vibration detection device for space multi-solar-panel unfolding structure - Google Patents

Abstract

The utility model discloses a vibration detection device of a space multi-solar-panel unfolding structure, which comprises a solar panel body part, a vibration excitation part, a vibration detection part and a vibration control part; the solar panel body part comprises a central hub, diagonal draw bars and N solar panels, the vibration excitation part comprises a vibration exciter, a signal generator, a power amplifier and a signal generator, the vibration detection part comprises a piezoelectric strain gauge, a charge amplifier, a data acquisition card, a laser displacement sensor, a controller and a computer, and the vibration control part comprises a piezoelectric ceramic actuator and a piezoelectric amplifier. The utility model discloses only need make the change slightly to the device, increase or reduce vibration detection and control device, can realize carrying out vibration detection and control analysis to arbitrary quantity's each direction expansion solar panel structure.

Description

Vibration detection device for space multi-solar-panel unfolding structure

Technical Field

The utility model relates to a vibration measurement field of mechanism can be expanded in space, concretely relates to many solar panel in space expandes vibration detection device of structure.

Background

The solar panel is an important component of the space target aircraft and provides electric energy required by on-orbit stable operation for various space target aircraft. The installation form that earliest solar panel adopted is aircraft surface mounting, and work area is little and unable full power work, along with the increase of space target aircraft operating power, the utility model discloses showing more that body dress formula solar panel's shortcoming, space target aircraft need break through the restriction of star surface area with the area of enlarging solar panel's work area and efficiency urgently, from this, just born folding transmission, the space that expands of entering the rail can unfold solar panel, the application of following the directional technique of counterglow again, can unfold solar cell panel's application becomes the technological mainstream.

The deployable solar panels solve the problems of generating power and efficiency, but also bring new technical problems for space target aircrafts. Unlike the body-mounted star with concentrated mass, the aircraft carrying the deployable solar panels is subject to increased mechanical complexity, distributed mass distribution, increased number of moving parts, and the like. The solar panel with a large area increases the area of receiving the sun and increases the area of receiving the sun, and due to factors such as the fit clearance of movable parts, the situation that the solar panel with a large area is excited to cause vibration during the orbital operation is more common, the vibration has low frequency and small amplitude but has long duration, and if the vibration is not clearly researched and effective vibration suppression measures cannot be taken, the vibration is easy to resonate with other parts of the aircraft, the stability of the target aircraft during the orbital operation is greatly reduced, and even the target aircraft is derailed and fails to cause great loss.

After the general space expandable structure is expanded, the movable joint in the expanding process can be limited and locked. Therefore, the vibration research of the solar panel which is unfolded in one direction can be simplified into a whole flexible plate, the flexible plate is clamped according to the actual mounting support form, and then the vibration test research is carried out.

SUMMERY OF THE UTILITY MODEL

In order to overcome the shortcoming and the not enough that prior art exists, the utility model discloses a primary objective provides a vibration detection device of many solar panel expansion structure in space, the utility model discloses an independent vibration detection system of multiunit has considered the inter-plate vibration coupling or the multi-plate resonance that probably exist under the multi-plate vibration condition simultaneously.

The utility model adopts the following technical scheme:

a vibration detection device of a space multi-solar-panel unfolding structure comprises a solar panel body part, a vibration excitation part, a vibration detection part and a vibration control part;

the solar panel body part comprises a central hub, an odd number of diagonal draw bars and N solar panels, wherein the N solar panels are arranged on the outer circumference of the central hub, one end of each solar panel is connected with the edge of the bottom end of the central hub through a hinge, the end is called a fixed end, the other end of each solar panel is called a free end, one end of each diagonal draw bar is connected with the top end of the central hub, and the other end of each diagonal draw bar is connected with the solar panels;

the vibration exciting part comprises a vibration exciter, a power amplifier and a signal generator, an output ejector rod of the vibration exciter is connected with the central hub, the signal generator generates an alternating current signal, and the signal is amplified by the power amplifier to drive the vibration exciter to generate vibration, so that the solar panel is excited to vibrate;

the vibration detection part comprises a piezoelectric strain gauge, a charge amplifier, a data acquisition card, a laser displacement sensor, a controller and a computer, wherein the piezoelectric strain gauge is adhered to the surface of the solar panel, the laser displacement sensor is positioned below the free end of the solar panel, the piezoelectric strain gauge detects vibration signals of the solar panel, then the vibration signals are input into the charge amplifier and are input into the computer through the data acquisition card, and the laser displacement sensor acquires the vibration displacement signals of the free end of the solar panel and transmits the vibration displacement signals to the computer through the controller;

the vibration control part comprises a piezoelectric ceramic actuator and a piezoelectric amplifier, the piezoelectric ceramic actuator is pasted on the surface of the solar panel, the computer obtains a control signal according to the vibration signal, and the piezoelectric ceramic actuator is driven by the piezoelectric amplifier.

The solar panel body part comprises five solar panels with the same structure size, the five solar panels are arranged on the outer circumference of the central hub, the included angle between the solar panels at the head and the tail is 120 degrees, and the included angle between other adjacent solar panels is 60 degrees.

The solar panel is connected with the diagonal draw bar at the position which is two thirds away from the bottom end, and the solar panel is unfolded and fixed on the horizontal plane.

The utility model discloses a slice piezoelectricity foil gage is pasted to every solar panel, apart from stiff end third length position, and be located width direction's mid point, the length direction of piezoelectricity foil gage is unanimous with solar panel's length direction.

The piezoelectric ceramic actuator is pasted at a position 50mm away from the fixed end of the solar panel, four pieces of each solar panel are pasted, the interval between every two pieces of the solar panels is 25mm, and the four pieces of the solar panels are connected in parallel.

The central hub is a hollow regular hexagonal prism.

The laser displacement sensors are five groups in total, and each group comprises two laser displacement sensors.

The utility model discloses a working process:

initializing a computer and a controller, setting the sampling frequency of each laser displacement sensor as a uniform frequency, and setting the acquisition speed of a data acquisition card to be the same as the sampling frequency of the laser displacement sensors;

starting a signal generator, setting waveform and frequency, amplifying a signal by a power amplifier, and driving a vibration exciter, wherein the vibration exciter excites a solar panel to generate vibration;

the controller and the data acquisition card acquire data at the same sampling frequency, and transmit the acquired data to the computer, and the computer outputs vibration information of each solar panel after analysis and processing;

the vibration exciter is closed to stop vibration excitation, the computer performs operation according to the piezoelectric strain gauge and vibration information acquired by the laser displacement sensor and then sends a vibration control signal to the piezoelectric amplifier, and the signal is amplified and then drives the piezoelectric ceramic actuator to control the vibration of the solar panel;

and changing the frequency or waveform of the vibration signal, changing the sampling frequency of data, performing multiple experiments, and comparing and analyzing the vibration control effect under different parameters.

The utility model has the advantages that:

(1) the utility model adopts the piezoelectric strain gauge and the laser displacement sensor to simultaneously detect the vibration deformation of different positions of the solar panel, collects a plurality of groups of vibration data, and can more comprehensively detect the vibration deformation condition of the solar panel relative to a single-point vibration measurement method;

(2) the utility model adopts a method that two laser displacement sensors simultaneously detect the vibration displacement at both sides of the free end of the same solar panel, and the bending and distortion information of the solar panel can be obtained by calculating the difference between two sets of displacement data and the static displacement;

(3) the utility model adopts the mode that the five solar panels are asymmetrically installed and the installation directions are different, thereby well simulating the vibration influence between the panels under the conditions of asymmetrical quality and stress;

(4) based on the technical principle of the utility model, only need to make the change slightly to the device, increase or reduce vibration detection and control device, can realize carrying out vibration detection and control analysis to arbitrary quantity's each direction expansion solar panel structure.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a front view of the present invention;

fig. 3 is a top view of the present invention;

fig. 4 is a left side view of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the following examples and drawings, but the present invention is not limited thereto.

Examples

As shown in fig. 1-4, a vibration detecting device for a space multi-solar panel unfolding structure comprises a solar panel body part, a vibration exciting part, a vibration detecting part and a vibration control part;

the solar panel body portion includes:

the solar energy collecting device comprises a central hub 9 for mounting a solar panel, five solar panels which are made of the same material and have the same size and are of a rectangular structure, five solar panels are specifically a first solar panel 1, a second solar panel 5, a third solar panel 7, a fourth solar panel 10 and a fifth solar panel 11, five solar panel diagonal draw bars 8 with the same length and a connecting piece 6 for connecting the solar panels and the diagonal draw bars, the central hub is a hollow regular hexagonal prism, five support columns at the top are connected with the diagonal draw bars, three support legs at the bottom are connected with a guide slide rail 15, and the slide rail is mounted on a right-angle support 14; the five solar panels are unfolded and installed on the same horizontal plane, but the length directions are different, except that the included angle between the first solar panel and the fifth solar panel is 120 degrees, the included angles of the other two adjacent plates are both 60 degrees, one end of the solar panel is directly connected with the central hub by two hinge joints 2, connecting the solar panel with one end of a diagonal draw bar by using a connecting piece at a position 400mm away from the fixed end of the solar panel, fixing the other end of the diagonal draw bar on a support column at the top of a central hub, thereby expand solar panel and fix on same horizontal plane, solar panel's lower surface is 200mm apart from installation testboard mesa, and the diagonal draw bar in this embodiment comprises upper and lower two sections, and the centre uses a collet nut to connect, rotates the contained angle that collet nut can finely tune between solar panel and the horizontal plane, and what the diagonal draw bar adopted is that the quality is light, the high carbon fiber tube of intensity.

The number of the solar panels is odd, the expansion directions of the solar panels are different, the overall quality is not completely symmetrical, the vibration of the solar panels is influenced, and the overall vibration form is complex.

The solar panel is provided with five solar panels, each solar panel is provided with an independent vibration excitation source and a vibration detection sensor, and the device can be used for carrying out single-plate vibration excitation test and multi-plate simultaneous vibration excitation test.

The vibration exciting part comprises a vibration exciter 16, a signal generator 23 and a power amplifier 24, wherein the vibration exciter 16 is positioned below the center of the central hub 9, an installation base of the vibration exciter is fixed on an installation test platform 17 through bolts, an output ejector rod of the vibration exciter 16 is connected with the central hub, the signal generator generates a certain alternating current signal, the signal is amplified to a proper voltage and current through the power amplifier, the vibration exciter is driven to vibrate, and therefore the solar panel is excited to vibrate.

The vibration detection part comprises a piezoelectric strain gauge 12, a charge amplifier 19, a laser displacement sensor 3, a controller 20-level computer 22, wherein the piezoelectric strain gauge is pasted on the surface of a solar panel, each plate is pasted with one plate, the pasting position is the central line of the upper surface width direction of the solar panel and is 200mm away from the fixed end of the solar panel, the length direction of the piezoelectric strain gauge is the same as that of the solar panel, the laser displacement sensor is positioned below the free end of the solar panel and is about 85mm away from the lower surface of the solar panel, the laser displacement sensor is fixed on a test mounting table 17 through a sheet metal part 4 and is used for detecting the vibration displacement of two sides of the free end of the solar panel, when the solar panel vibrates, the piezoelectric strain gauge senses the vibration and converts the vibration into an electric signal to be transmitted to the charge amplifier 19, the electric signal of the piezoelectric strain gauge is linearly amplified by the charge amplifier, finally, the collected data are transmitted to the computer 22 for analysis; the laser displacement sensor 3 collects vibration displacement data of the free end of the solar panel at the same time under the action of the controller 20, the controller records the data collected by the laser displacement sensor and transmits the data to the computer, and the vibration information of each solar panel is obtained through analysis and processing of the computer.

The total 5 groups of laser displacement sensor, two laser displacement sensors in every group connect same controller, two laser displacement sensors detect the vibration displacement of solar panel free end with the same sampling frequency under the control of controller, the controller transmits two sets of vibration displacement data and difference value to the computer after inside operation, the computer is analyzed and processed again and is reachd the bending and the distortion information of solar panel.

The vibration control section includes

Piezoelectric ceramic actuator 13, piezoelectric amplifier 18, piezoelectric ceramic actuator 13 pastes on the upper surface of solar panel, and more 50mm apart from the solar panel stiff end, 4 pieces of solar panel paste of each, and the interval between every two is 25mm, four pieces are connected in parallel, piezoelectric amplifier 18 receives the control signal from the computer, and drive piezoelectric ceramic actuator after amplifying the signal, make its deformation direction and solar panel's deformation direction opposite, thereby control the vibration of solar panel.

The utility model discloses a control process:

initializing a computer and a controller, setting the sampling frequency of each laser displacement sensor as a uniform frequency, and setting the acquisition speed of a data acquisition card to be the same as the sampling frequency of the laser displacement sensors;

starting a signal generator, setting waveform and frequency, amplifying a signal by a power amplifier, and driving a vibration exciter, wherein the vibration exciter excites a solar panel to generate vibration;

the controller and the data acquisition card acquire data at the same sampling frequency, and transmit the acquired data to the computer, and the computer outputs vibration information of each solar panel after analysis and processing;

the vibration exciter is closed to stop vibration excitation, the computer performs operation according to the piezoelectric strain gauge and vibration information acquired by the laser displacement sensor and then sends a vibration control signal to the piezoelectric amplifier, and the signal is amplified and then drives the piezoelectric ceramic actuator to control the vibration of the solar panel;

and changing the frequency or waveform of the vibration signal, changing the sampling frequency of data, performing multiple experiments, and comparing and analyzing the vibration control effect under different parameters.

The dashed lines in fig. 1 indicate the electrical connections between the devices, and the arrows indicate the signal transmission directions.

In this example, five sheets of epoxy material were used to approximate the simulation of solar energyAn expansion board with the size of 600mm multiplied by 200mm multiplied by 2mm and the density of the epoxy resin material of 1.84g/cm³Modulus of elasticity of E_pThe hinge for connecting the hub and the epoxy plate is made of aluminum alloy, with a poisson's ratio of 0.38 being 34.64 Gpa.

The piezoceramic actuator has a geometry of 50mm x 15mm x 2mm, is custom made from Changshafen hang electronics technology, Inc., and is made of a Fuji C-82 type piezoceramic material having a density of 7.5 x 10³kg/m³The elastic modulus is 620GPa, the Poisson ratio is 0.34, and the piezoelectric constant is 600 m/V; the piezoelectric strain gauge (11) is made of piezoelectric ceramics and has the size of 40mm multiplied by 10mm multiplied by 1 mm.

The laser displacement sensor adopts a CD5 series laser displacement sensor of Japan OPTEX FA company, the specific model is CD5-85, a CCD image sensor is adopted, the detection is carried out in a diffuse reflection mode, the detection distance is 85mm, the measured displacement range is +/-20 mm, the resolution is 1 mu m, and the minimum sampling period is 100 mu s; the controller matched with the laser displacement sensor is a CD5A-N type controller of OPTEX FA company, is provided with a USB communication interface, and can be connected with at most three laser displacement sensors.

The charge amplifier adopts YE5853 type charge amplifier of Jiangsu union electron limited company, the data acquisition card adopts 8-channel and 16-bit precision data acquisition card with the model of USB-5817 of Taiwan Hua science and technology, and the USB interface is used for communicating with a computer.

The model of the signal generator is YMC9200 digital signal generator, the manufacturer is Yangzhou Yinmei measurable and controllable technology company, and the output signal amplitude is as follows: 10 Vp; the vibration exciter adopts an MS series modal vibration exciter produced by Yangzhou Yinmei measurable and controllable technology limited company, the specific model is MS-200, the maximum exciting force of a single vibration exciter is 200N, the maximum amplitude is +/-10 mm, the exciting frequency range is 0-4 kHz, and the output signal frequency range is as follows: 0 to 30 kHz; the piezoelectric amplifier is a piezoelectric amplifier which is developed by southern China university and has the model of APEX-PA241DW or APEX-PA240CX, and the maximum amplification multiple digit is 52 times.

The above embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited by the above embodiments, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be equivalent replacement modes, and all are included in the scope of the present invention.

Claims (7)

1. A vibration detection device of a space multi-solar-panel unfolding structure is characterized by comprising a solar panel body part, a vibration excitation part, a vibration detection part and a vibration control part;

the solar panel body part comprises a central hub, an odd number of diagonal draw bars and N solar panels, wherein the N solar panels are arranged on the outer circumference of the central hub, one end of each solar panel is connected with the edge of the bottom end of the central hub through a hinge, the end is called a fixed end, the other end of each solar panel is called a free end, one end of each diagonal draw bar is connected with the top end of the central hub, and the other end of each diagonal draw bar is connected with the solar panels;

the vibration exciting part comprises a vibration exciter, a power amplifier and a signal generator, an output ejector rod of the vibration exciter is connected with the central hub, the signal generator generates an alternating current signal, and the signal is amplified by the power amplifier to drive the vibration exciter to generate vibration, so that the solar panel is excited to vibrate;

the vibration detection part comprises a piezoelectric strain gauge, a charge amplifier, a data acquisition card, a laser displacement sensor, a controller and a computer, wherein the piezoelectric strain gauge is adhered to the surface of the solar panel, the laser displacement sensor is positioned below the free end of the solar panel, the piezoelectric strain gauge detects vibration signals of the solar panel, then the vibration signals are input into the charge amplifier and are input into the computer through the data acquisition card, and the laser displacement sensor acquires the vibration displacement signals of the free end of the solar panel and transmits the vibration displacement signals to the computer through the controller;

the vibration control part comprises a piezoelectric ceramic actuator and a piezoelectric amplifier, the piezoelectric ceramic actuator is pasted on the surface of the solar panel, the computer obtains a control signal according to the vibration signal, and the piezoelectric ceramic actuator is driven by the piezoelectric amplifier.

2. The vibration detecting device according to claim 1, wherein the solar panel body portion comprises five solar panels with the same structure and size, the five solar panels are arranged on the outer circumference of the central hub, the included angle between the solar panels at the head and the tail is 120 degrees, and the included angle between other adjacent solar panels is 60 degrees.

3. The vibration detecting device according to claim 1, wherein the solar panel is connected to the diagonal member at a position spaced from the bottom two thirds thereof, so as to unfold and fix the solar panel on a horizontal plane.

4. The vibration detecting device according to claim 1, wherein each solar panel is attached to a position which is one third of the length of the fixed end and is located at the midpoint in the width direction, and the length direction of the piezoelectric strain gauge is identical to the length direction of the solar panel.

5. The vibration detecting device according to claim 1, wherein the piezoelectric ceramic actuator is attached at a distance of 50mm from the fixed end of the solar panel, four pieces are attached to each solar panel, the distance between every two pieces is 25mm, and the four pieces are connected in parallel.

6. The vibration sensing device of claim 1, wherein the central hub is a hollow regular hexagonal prism.

7. The vibration detecting apparatus according to claim 1, wherein the laser displacement sensors are provided in five groups, each group including two.

Images