CN202460957U - Electromagnetic vibration table system with adjustable electric viscoelastic support device - Google Patents

Abstract

An electromagnetic vibration table system with an adjustable electric viscoelastic support device comprises an electromagnetic vibration table, a power amplifier and an adjustable electric viscoelastic support device. The electromagnetic vibration table is supported by the adjustable electric viscoelastic support device. The adjustable electric viscoelastic support device comprises a displacement sensor for monitoring the displacement of each moving part of the electromagnetic vibration table, a first adjustable amplifier, a second adjustable amplifier, a differentiator, an adder, an adjustable phase shifter, a subtracter and a proportioner. By changing the amplifying times of the adjustable amplifiers, the adjustable phase shifter and the proportioner, etc., the support rigidity characteristic parameter and the damping characteristic parameter of the vibration table can be directly adjusted. Meanwhile, good linearity is maintained. The electromagnetic vibration table system with the adjustable electric viscoelastic support device has the advantages of adjustable parameters, good linearity and convenient realization.

Description

Electromagnetic type shaking table system with adjustable electric viscoplasticity bracing or strutting arrangement

Technical field

The utility model relates to a kind of electromagnetic type shaking table system with adjustable electric viscoplasticity bracing or strutting arrangement.

Technical background

The electromagnetic type shake table generally comprises parts such as fixed pedestal, excitation system, moving component, guiding and support system.And along with science and technology development; The electromagnetic type shake table more and more is asked to export the vibration signal of big displacement; As when being used for the output of low frequency and even ultralow frequency range; In order to obtain the big vibration signal of signal to noise ratio, shake table output displacement peak-to-peak value can reach 1000mm, and big stroke vibration platform has proposed new requirement to resilient supporting unit.

The electromagnetic type shake table generally adopts mechanical elastic bracing or strutting arrangements such as leaf spring, emulsion tube, and moving component is supported and locatees.At the shake table work shift hour, the mechanical elasticity bracing or strutting arrangement works in linear zone, can ignore the influence of shake table output-index; When the shake table moving displacement is big (as when the ultralow frequency work that is low to moderate 0.01Hz; Output displacement peak-to-peak value can reach 1000mm); The mechanical elasticity bracing or strutting arrangement of conventional vibration platform will present bigger nonlinear characteristic, thereby the shake table performance indications are produced bigger influence; In addition; The shake table displacement is big more, requires the rigidity of mechanical elasticity bracing or strutting arrangement less, yet for reducing table top drift and external environment The noise; Require bracing or strutting arrangement to have bigger damping again, it is little and mechanical elasticity bracing or strutting arrangement that damping is big has difficulties to design this rigidity; In addition, because the variation of mechanical elasticity bracing or strutting arrangement material property, its location repeatability also can't guarantee; At last, the mechanical elasticity bracing or strutting arrangement that installs, its support stiffness and damping parameter can not arbitrarily change.So the mechanical elasticity bracing or strutting arrangement can't satisfy the constantly requirement of development of electromagnetic type shake table, especially big stroke vibration platform.

The utility model content

For overcoming the above-mentioned shortcoming of prior art; The utility model provides a kind of electromagnetic type shaking table system with electric viscoplasticity bracing or strutting arrangement; The alternative mechanical elasticity bracing or strutting arrangement of this electricity viscoplasticity bracing or strutting arrangement; Make the support stiffness and the damping parameter of moving component in the electromagnetic type shake table require convenient the adjusting, and under big stroke condition of work, have favorable linearity, thereby can greatly improve the service behaviour under the big stroke of electromagnetic type shake table according to actual motion.

Have the electromagnetic type shaking table system of adjustable electric viscoplasticity bracing or strutting arrangement, comprise electromagnetic type shake table and power amplifier;

It is characterized in that: the bracing or strutting arrangement of described electromagnetic type shake table is an adjustable electric viscoplasticity bracing or strutting arrangement; Described adjustable electric viscoplasticity bracing or strutting arrangement comprises displacement transducer, first adjustable amplifier, second adjustable amplifier, differentiator, adder and adjustable phase shifter, subtracter, the proportional controller of monitoring electromagnetic type shake table moving component displacement;

The displacement signal one tunnel that described displacement transducer obtains forms first amplifying signal through first adjustable amplifier; Another road of described displacement signal forms second amplifying signal successively behind the differentiator and second adjustable amplifier; Described first amplifying signal and second amplifying signal form plus signal through described adder addition; In the described plus signal input adjustable phase shifter, the phase shift signal of adjustable phase shifter output is as in the subtrahend input subtracter, and described subtracter is connected with the signal generator that produces standard signal; Described standard signal is as the minuend of subtracter; The output of described subtracter is connected with the input of proportional controller, and the output of described proportional controller is connected with the input of power amplifier, and the output signal of described power amplifier is as the driving signal of electromagnetic type shake table.

Further, the transfer function of described shaking table system is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}$

$=K_3{K}_p\·\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+c_{2}L)s^2+[{\mathrm{Rc}}_2+{\left(\mathrm{Bl}\right)}^2+K_2{K}_3{K}_4{K}_p\mathrm{Bl}]s+K_1{K}_3{K}_4{K}_p\mathrm{Bl}}$

$=\frac{K_3{K}_p\mathrm{Bl}}{R}\·\frac{\mathrm{Bl}}{\frac{\mathrm{mL}}{R}{s}^3+(m+\frac{c_{2}L}{R})s^2+[c_2+\frac{{\left(\mathrm{Bl}\right)}^2+K_2{K}_3{K}_4{K}_p\mathrm{Bl}}{R}]s+\frac{K_1{K}_3{K}_4{K}_p\mathrm{Bl}}{R}}---\left(1\right)$

In the formula, m is the gross mass of moving component and load; c ₂For the damping that produces by other factors beyond the supporting system, like air damping; B is the magnetic induction intensity in control air crack; L is the length of moving coil winding; L is the equivalent inductance of moving coil winding; R is the equivalent resistance of moving coil winding; K ₁It is the multiplication factor of first adjustable amplifier; K ₂It is the multiplication factor of second adjustable amplifier; K ₃It is the multiplication factor of proportional controller; K ₄It is the multiplication factor of adjustable phase shifter; K _pIt is the multiplication factor of power amplifier; S=j ω is complex frequency;

In the formula (1); Parameter

has reflected the damping characteristic of system, and parameter

has reflected the rigidity characteristic of system.c ₂Mainly produce, through reasonable setting K wherein by air damping ₂, K ₃, K ₄, can make

Thereby

Suppose that magnetic induction density B is and the irrelevant constant of displacement x, then the damping characteristic parameters C of shaking table system and rigidity characteristic parameter K are the constant parameter, and therefore system has better linearity; And through changing K ₁, K ₂, K ₃, K ₄Parameter can make system obtain suitable damping and stiffness parameters.

Further, the transfer function of described shaking table system under low frequency and ultralow frequency motion conditions is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}=K_3{K}_P\·\frac{\mathrm{Bl}}{{\mathrm{mRs}}^2+[{\mathrm{Rc}}_2+K_2{K}_3{K}_4{K}_P\mathrm{Bl}+{\left(\mathrm{Bl}\right)}^2]s+K_1{K}_3{K}_4{K}_P\mathrm{Bl}}$

$=\frac{K_3{K}_P\·\mathrm{Bl}}{R}\·\frac{1}{{\mathrm{ms}}^2+[c_2+\frac{K_2{K}_3{K}_4{K}_P\mathrm{Bl}+{\left(\mathrm{Bl}\right)}^2}{R}]s+\frac{K_1{K}_3{K}_4{K}_P\mathrm{Bl}}{R}}---\left(2\right)$

In the formula (2), system's equivalent damping coefficient does System's equivalent stiffness coefficient does

c ₂Mainly produce, through reasonable setting K wherein by air damping ₂, K ₃, K ₄, make

Thereby

Suppose that magnetic induction density B is and the irrelevant constant of displacement x, then system's equivalent stiffness and damped coefficient K and C are the constant parameter, and therefore system has better linearity.Through changing the multiplication factor of controllable amplifier, controllable phase shifter, proportional controller etc., can directly regulate equivalent stiffness coefficient and damped coefficient K and C that shake table supports.

The technical conceive of the utility model is: the link factor of cancellation non-controlled, linear difference in the mechanical system changes by convenient controlled, good linearity, electric link that precision is high and realizes.Specifically be to add differential and phase shift through ratio to handle to electromagnetic type shake table displacement signal, the feedback signal of construction system, realize the function of alternative mechanical link.

The electromagnetic type shake table generally comprises parts such as fixed pedestal, excitation system, moving component, guiding and support system, and wherein, traditional electromagnetic type shake table often adopts mechanical elastic bracing or strutting arrangements such as leaf spring, emulsion tube that moving component is supported and locatees.Moving-coil, moving coil framework, work top connect good in the moving component; Its first order resonance frequency is usually designed to more than 5 times of operating frequency; So when shake table was worked, moving component can be considered a rigid body, and then can the electromagnetic type shake table be reduced to the single-degree-of-freedom mechanical model; Consider the electric equation of drive coil simultaneously, its mechanical-electric coupling equation is:

In the formula, m is the gross mass of moving component and load; K is the support spring rigidity of moving component; C is the kinetic damping coefficient of moving component, c=c ₁+ c ₂, c wherein ₁Be the damping of mechanical elasticity bracing or strutting arrangement, c ₂The damping that other factors of serving as reasons produce is like air damping; B is the magnetic induction intensity in control air crack; L is the length of moving coil winding; L is the equivalent inductance of moving coil winding; R is the equivalent resistance of moving coil winding; I is a drive current in the moving-coil; u ₀Voltage for power amplifier input winding two ends; X is the output displacement of shake table.

So traditional electromagnetic type shake table transfer function is:

$G_2\left(s\right)=\frac{X\left(s\right)}{U_0\left(s\right)}=\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+\mathrm{cL})s^2+[\mathrm{Rc}+{\left(\mathrm{Bl}\right)}^2+\mathrm{kL}]s+\mathrm{Rk}}---\left(4\right)$

Traditional shaking table system is made up of power amplifier and electromagnetic type shake table, power amplifier transfer function G ₁(s)=K _pSo traditional shaking table system transfer function is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}=K_p\·\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+\mathrm{cL})s^2+[\mathrm{Rc}+{\left(\mathrm{Bl}\right)}^2+\mathrm{kL}]s+\mathrm{Rk}}$

$=\frac{K_p\mathrm{Bl}}{R}\·\frac{\mathrm{Bl}}{\frac{\mathrm{mL}}{R}{s}^3+(m+\frac{\mathrm{cL}}{R})s^2+[c+\frac{{\left(\mathrm{Bl}\right)}^2+\mathrm{kL}}{R}]s+k}---\left(5\right)$

In the formula, K _pMultiplication factor for power amplifier.

In the formula (5); Parameter

has reflected the damping characteristic of system, and parameter K=k has reflected the rigidity characteristic of system.After the installation of electromagnetic type shake table, K and C all are malleables not, and all relevant with nonlinear parameter k, c, so K and C also have nonlinear characteristic.

Cancelled the mechanical elastic supporting arrangement in the utility model, thus in formula (3) k=0, c=c ₂, shake table mechanical-electric coupling equation becomes:

C in the formula ₂Mainly produce by air damping.This moment, the shaking table system transfer function was:

$G_2\left(s\right)=\frac{X\left(s\right)}{U_0\left(s\right)}=\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+c_{2}L)s^2+[{\mathrm{Rc}}_2+{\left(\mathrm{Bl}\right)}^2]s}---\left(7\right)$

Simultaneously, native system has been introduced adjustable electric viscoplasticity bracing or strutting arrangement, and its implementation procedure is: displacement transducer detects the displacement x of electromagnetic type shake table moving component, and this displacement signal x one tunnel is through first adjustable amplifier (the multiplication factor K ₁), another road is earlier after differentiator, second adjustable amplifier (the multiplication factor K ₂) handle, the signal after this two-way is handled is through the adder addition, and (multiplication factor is K to pass through adjustable phase shifter again ₄, phase shift

) after, the standard signal u that exports with signal generator asks difference operation, gets deviation signal u ₁, then through proportional controller (multiplication factor K ₃) after export to power amplifier (multiplication factor K _p), drive the electromagnetic type shake table.

After introducing adjustable electric viscoplasticity bracing or strutting arrangement, the transfer function of feedback unit is:

Make controllable phase shifter phase shift then:

G ₃(s)＝(K ₁+K ₂s)·K ₄ (9)

Power amplifier transfer function G ₁(s)=K _p, proportional controller transfer function G ₄(s)=K ₃So ssystem transfer function is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}$

$=K_3{K}_p\·\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+c_{2}L)s^2+[{\mathrm{Rc}}_2+{\left(\mathrm{Bl}\right)}^2+K_2{K}_3{K}_4{K}_p\mathrm{Bl}]s+K_1{K}_3{K}_4{K}_p\mathrm{Bl}}$

$=\frac{K_3{K}_p\mathrm{Bl}}{R}\·\frac{\mathrm{Bl}}{\frac{\mathrm{mL}}{R}{s}^3+(m+\frac{c_{2}L}{R})s^2+[c_2+\frac{{\left(\mathrm{Bl}\right)}^2+K_2{K}_3{K}_4{K}_p\mathrm{Bl}}{R}]s+\frac{K_1{K}_3{K}_4{K}_p\mathrm{Bl}}{R}}---\left(10\right)$

Can know by formula (10); Parameter

has reflected the damping characteristic of system, and parameter has reflected the rigidity characteristic of system.Through reasonable setting K wherein ₂, K ₃, K ₄, can make

Thereby

Compare with formula (5), nonlinear parameter k, c all do not appear in the K of shaking table system and C parameter.Suppose that magnetic induction density B also is and the irrelevant constant of displacement x, then the damping characteristic parameters C of shaking table system and rigidity characteristic parameter K are the constant parameter, and therefore system has better linearity; And through changing K ₁, K ₂, K ₃, K ₄Parameter can make system obtain suitable damping and stiffness parameters.

Especially; For shake table low frequency, ultralow frequency motion conditions; is very little; So can make

item in the formula (3) is 0, then traditional shake table mechanical-electric coupling equation is:

Correspondingly, the transfer function of traditional shaking table system is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}=K_p\·\frac{\mathrm{Bl}}{{\mathrm{mRs}}^2+[\mathrm{Rc}+{\left(\mathrm{Bl}\right)}^2]s+\mathrm{Rk}}=\frac{K_p\mathrm{Bl}}{R}\·\frac{1}{{\mathrm{ms}}^2+(c+\frac{{\left(\mathrm{Bl}\right)}^2}{R})s+k}---\left(12\right)$

This system is typical single-degree of freedom vibration system model, and wherein the equivalent damping coefficient is K=k for

equivalent stiffness coefficient.After the installation of electromagnetic type shake table, K and C all are malleables not, and all relevant with nonlinear parameter k, c, so K and C also have nonlinear characteristic.

Behind the cancellation mechanical elastic supporting arrangement, shake table mechanical-electric coupling equation (6) is:

After introducing adjustable electric viscoplasticity bracing or strutting arrangement, the shaking table system transfer function is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}=K_3{K}_P\·\frac{\mathrm{Bl}}{{\mathrm{mRs}}^2+[{\mathrm{Rc}}_2+K_2{K}_3{K}_4{K}_P\mathrm{Bl}+{\left(\mathrm{Bl}\right)}^2]s+K_1{K}_3{K}_4{K}_P\mathrm{Bl}}$ (14)

$=\frac{K_3{K}_P\·\mathrm{Bl}}{R}\·\frac{1}{{\mathrm{ms}}^2+[c_2+\frac{K_2{K}_3{K}_4{K}_P\mathrm{Bl}+{\left(\mathrm{Bl}\right)}^2}{R}]s+\frac{K_1{K}_3{K}_4{K}_P\mathrm{Bl}}{R}}$

This system also is typical single-degree of freedom vibration system model, and wherein the equivalent damping coefficient does

The equivalent stiffness coefficient does

c ₂Mainly produce, through reasonable setting K wherein by air damping ₂, K ₃, K ₄, make

Thereby

Suppose that magnetic induction density B is and the irrelevant constant of displacement x, then equivalent stiffness and damped coefficient K and C are the constant parameter in the formula (14), and therefore system has good linear, thereby can improve systematic function.Contrast formula (12) and formula (14) can be found out more significantly, through changing the multiplication factor of controllable amplifier, controllable phase shifter, proportional controller etc., can directly regulate equivalent stiffness coefficient and damped coefficient K and C that shake table supports.

Cause that for solving shake table input voltage and carry-out bit shift out existing phase shift problem when operating frequency increases, can guarantee that the phase difference between feedback signal and the signal source is constant through regulating adjustable phase shifter.

The utlity model has adjustable, the good linearity of parameter, the convenient advantage that realizes.

Description of drawings

Fig. 1 is an electromagnetic type shake table moving component kinetic model.

Fig. 2 is an electromagnetic type shake table electromechanical Coupling Model.

Fig. 3 is the system model with mechanical elasticity bracing or strutting arrangement.

Fig. 4 is the structured flowchart of the utility model.

Fig. 5 is for introducing the system model of electric viscoplasticity bracing or strutting arrangement.

The specific embodiment

With reference to accompanying drawing, further specify the utility model:

Have the electromagnetic type shaking table system of adjustable electric viscoplasticity bracing or strutting arrangement, comprise electromagnetic type shake table and power amplifier;

The bracing or strutting arrangement of described electromagnetic type shake table is an adjustable electric viscoplasticity bracing or strutting arrangement; Described adjustable electric viscoplasticity bracing or strutting arrangement comprises displacement transducer, first adjustable amplifier, second adjustable amplifier, differentiator, adder and adjustable phase shifter, subtracter, proportional controller;

The displacement signal one tunnel that described displacement transducer obtains forms first amplifying signal through first adjustable amplifier; Another road of described displacement signal forms second amplifying signal successively behind the differentiator and second adjustable amplifier; Described first amplifying signal and second amplifying signal form plus signal through described adder addition; In the described plus signal input adjustable phase shifter, the phase shift signal of adjustable phase shifter output is as in the subtrahend input subtracter, and described subtracter is connected with the signal generator that produces standard signal; Described standard signal is as the minuend of subtracter; The output of described subtracter is connected with the input of proportional controller, and the output of described proportional controller is connected with the input of power amplifier, and the output signal of described power amplifier is as the driving signal of electromagnetic type shake table.

The technical conceive of the utility model is: the link factor of cancellation non-controlled, linear difference in the mechanical system changes by convenient controlled, good linearity, electric link that precision is high and realizes.Specifically be to add differential and phase shift through ratio to handle to electromagnetic type shake table displacement signal, the feedback signal of construction system, realize the function of alternative mechanical link.

The electromagnetic type shake table generally comprises parts such as fixed pedestal, excitation system, moving component, guiding and support system, and wherein, traditional electromagnetic type shake table often adopts mechanical elastic bracing or strutting arrangements such as leaf spring, emulsion tube, and moving component is supported and locatees.Moving-coil, moving coil framework, work top connect well in the electromagnetic type shake table moving component, and its first order resonance frequency is usually designed to more than 5 times of operating frequency, so when shake table is worked; Moving component can be considered a rigid body; And then can the electromagnetic type shake table be reduced to the single-degree-of-freedom mechanical model, and as shown in Figure 1, consider the electric equation of drive coil simultaneously; Traditional electromagnetic type shake table electromechanical Coupling Model is as shown in Figure 2, and its mechanical-electric coupling equation is:

In the formula, m is the gross mass of moving component and load; K is the support spring rigidity of moving component; C is the kinetic damping coefficient of moving component, c=c ₁+ c ₂, c wherein ₁Be the damping of mechanical elasticity bracing or strutting arrangement, c ₂The damping that other factors of serving as reasons produce is like air damping; B is the magnetic induction intensity in control air crack; L is the length of moving coil winding; L is the equivalent inductance of moving coil winding; R is the equivalent resistance of moving coil winding; I is a drive current in the moving-coil; u ₀Voltage for power amplifier input winding two ends; X is the output displacement of shake table.

So traditional electromagnetic type shake table transfer function is:

$G_2\left(s\right)=\frac{X\left(s\right)}{U_0\left(s\right)}=\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+\mathrm{cL})s^2+[\mathrm{Rc}+{\left(\mathrm{Bl}\right)}^2+\mathrm{kL}]s+\mathrm{Rk}}---\left(2\right)$

The block mold of traditional shaking table system is as shown in Figure 3, power amplifier transfer function G ₁(s)=K _pSo ssystem transfer function is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}=K_p\·\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+\mathrm{cL})s^2+[\mathrm{Rc}+{\left(\mathrm{Bl}\right)}^2+\mathrm{kL}]s+\mathrm{Rk}}$

$=\frac{K_p\mathrm{Bl}}{R}\·\frac{\mathrm{Bl}}{\frac{\mathrm{mL}}{R}{s}^3+(m+\frac{\mathrm{cL}}{R})s^2+[c+\frac{{\left(\mathrm{Bl}\right)}^2+\mathrm{kL}}{R}]s+k}---\left(3\right)$

In the formula, K _pMultiplication factor for power amplifier.

In the formula (3); Parameter

has reflected the damping characteristic of system, and parameter K=k has reflected the rigidity characteristic of system.After the installation of electromagnetic type shake table, K and C all are malleables not, and all relevant with nonlinear parameter k, c, so K and C also have nonlinear characteristic.

Cancelled the mechanical elastic supporting arrangement in the utility model, thus in formula (1) k=0, c=c ₂, shake table mechanical-electric coupling equation becomes:

C in the formula ₂Mainly produce by air damping.This moment, electromagnetic type shake table transfer function was:

$G_2\left(s\right)=\frac{X\left(s\right)}{U_0\left(s\right)}=\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+c_{2}L)s^2+[{\mathrm{Rc}}_2+{\left(\mathrm{Bl}\right)}^2]s}---\left(5\right)$

Simultaneously, native system has been introduced adjustable electric viscoplasticity bracing or strutting arrangement, and its structure is formed as shown in Figure 4.Adjustable electric viscoplasticity bracing or strutting arrangement is by displacement transducer, compositions such as first adjustable amplifier, second adjustable amplifier, differentiator, adjustable phase shifter and adder, subtracter, proportional controller.Its implementation procedure is: displacement transducer detects the displacement x of electromagnetic type shake table moving component, and this displacement signal x one tunnel is through first adjustable amplifier (the multiplication factor K ₁), another road is earlier after differentiator, second adjustable amplifier (the multiplication factor K ₂) handle, the signal after this two-way is handled is through the adder addition, and (multiplication factor is K to pass through adjustable phase shifter again ₄, phase shift

) after, the standard signal u that exports with signal generator asks difference operation, gets deviation signal u ₁, then through proportional controller (multiplication factor K ₃) after export to power amplifier (multiplication factor K _p), drive the electromagnetic type shake table.

After introducing adjustable electric viscoplasticity bracing or strutting arrangement, system model further can be reduced to as shown in Figure 5.Wherein, the transfer function of feedback unit is:

Make controllable phase shifter phase shift

then:

G ₃(s)＝(K ₁+K ₂s)·K ₄ (7)

Power amplifier transfer function G ₁(s)=K _p, proportional controller transfer function G ₄(s)=K ₃So ssystem transfer function is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}$

$=K_3{K}_p\·\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+c_{2}L)s^2+[{\mathrm{Rc}}_2+{\left(\mathrm{Bl}\right)}^2+K_2{K}_3{K}_4{K}_p\mathrm{Bl}]s+K_1{K}_3{K}_4{K}_p\mathrm{Bl}}$

$=\frac{K_3{K}_p\mathrm{Bl}}{R}\·\frac{\mathrm{Bl}}{\frac{\mathrm{mL}}{R}{s}^3+(m+\frac{c_{2}L}{R})s^2+[c_2+\frac{{\left(\mathrm{Bl}\right)}^2+K_2{K}_3{K}_4{K}_p\mathrm{Bl}}{R}]s+\frac{K_1{K}_3{K}_4{K}_p\mathrm{Bl}}{R}}---\left(8\right)$

Can know by formula (8); Parameter has reflected the damping characteristic of system, and parameter

has reflected the rigidity characteristic of system.Through reasonable setting K wherein ₂, K ₃, K ₄, can make

Thereby

Compare with formula (3), nonlinear parameter k, c all do not appear in the K of shaking table system and C parameter.Suppose that magnetic induction density B also is and the irrelevant constant of displacement x, then the damping characteristic parameters C of shaking table system and rigidity characteristic parameter K are the constant parameter, and therefore system has better linearity; And through changing K ₁, K ₂, K ₃, K ₄Parameter can make system obtain suitable damping and stiffness parameters.

Especially; For shake table low frequency, ultralow frequency motion conditions;

is very little, is 0 so can make item in the formula (1).Adopt the shake table mechanical-electric coupling equation of mechanical elastic supporting arrangement to be:

Correspondingly, the transfer function formula of shaking table system is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}=K_p\·\frac{\mathrm{Bl}}{{\mathrm{mRs}}^2+[\mathrm{Rc}+{\left(\mathrm{Bl}\right)}^2]s+\mathrm{Rk}}=\frac{K_p\mathrm{Bl}}{R}\·\frac{1}{{\mathrm{ms}}^2+(c+\frac{{\left(\mathrm{Bl}\right)}^2}{R})s+k}---\left(10\right)$

This system is typical single-degree of freedom vibration system model, and wherein the equivalent damping coefficient is K=k for

equivalent stiffness coefficient.After the installation of electromagnetic type shake table, K and C all are malleables not, and all relevant with nonlinear parameter k, c, so K and C also have nonlinear characteristic.

Behind the cancellation mechanical elastic supporting arrangement, shake table mechanical-electric coupling equation (4) is:

After introducing adjustable electric viscoplasticity bracing or strutting arrangement, the shaking table system transfer function is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}=K_3{K}_P\·\frac{\mathrm{Bl}}{{\mathrm{mRs}}^2+[{\mathrm{Rc}}_2+K_2{K}_3{K}_4{K}_P\mathrm{Bl}+{\left(\mathrm{Bl}\right)}^2]s+K_1{K}_3{K}_4{K}_P\mathrm{Bl}}$ (12)

$=\frac{K_3{K}_P\·\mathrm{Bl}}{R}\·\frac{1}{{\mathrm{ms}}^2+[c_2+\frac{K_2{K}_3{K}_4{K}_P\mathrm{Bl}+{\left(\mathrm{Bl}\right)}^2}{R}]s+\frac{K_1{K}_3{K}_4{K}_P\mathrm{Bl}}{R}}$

This system also is typical single-degree of freedom vibration system model, and wherein the equivalent damping coefficient does

The equivalent stiffness coefficient does

c ₂Mainly produce, through reasonable setting K wherein by air damping ₂, K ₃, K ₄, make

Thereby

Suppose that magnetic induction density B is and the irrelevant constant of displacement x, then equivalent stiffness and damped coefficient K and C are the constant parameter in the formula (12), and therefore system has good linear, thereby can improve systematic function.Contrast formula (10) and formula (12) can be found out more significantly, through changing the multiplication factor of controllable amplifier, controllable phase shifter, proportional controller etc., can directly regulate equivalent stiffness coefficient and damped coefficient K and C that shake table supports.

Cause that for solving shake table input voltage and carry-out bit shift out existing phase shift problem when operating frequency increases, can guarantee that the phase difference between feedback signal and the signal source is constant through regulating adjustable phase shifter.

The described content of this specification embodiment only is enumerating the way of realization of utility model design; The protection domain of the utility model should not be regarded as and only limit to the concrete form that embodiment states, the protection domain of the utility model also reach in those skilled in the art according to the utility model design the equivalent technologies means that can expect.

Claims (3)

1. have the electromagnetic type shaking table system of adjustable electric viscoplasticity bracing or strutting arrangement, comprise electromagnetic type shake table and power amplifier;

It is characterized in that: the bracing or strutting arrangement of described electromagnetic type shake table is an adjustable electric viscoplasticity bracing or strutting arrangement; Described adjustable electric viscoplasticity bracing or strutting arrangement comprises displacement transducer, first adjustable amplifier, second adjustable amplifier, differentiator, adder and adjustable phase shifter, subtracter, the proportional controller of monitoring electromagnetic type shake table moving component displacement;

The displacement signal one tunnel that described displacement transducer obtains forms first amplifying signal through first adjustable amplifier; Another road of described displacement signal forms second amplifying signal successively behind the differentiator and second adjustable amplifier; Described first amplifying signal and second amplifying signal form plus signal through described adder addition; In the described plus signal input adjustable phase shifter, the phase shift signal of adjustable phase shifter output is as in the subtrahend input subtracter, and described subtracter is connected with the signal generator that produces standard signal; Described standard signal is as the minuend of subtracter; The output of described subtracter is connected with the input of proportional controller, and the output of described proportional controller is connected with the input of power amplifier, and the output signal of described power amplifier is as the driving signal of electromagnetic type shake table.

2. the electromagnetic type shaking table system with adjustable electric viscoplasticity bracing or strutting arrangement as claimed in claim 1, it is characterized in that: the transfer function of described shaking table system is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}$

$=K_3{K}_p\·\frac{\mathrm{Bl}}{{\mathrm{mLs}}^3+(\mathrm{mR}+c_{2}L)s^2+[{\mathrm{Rc}}_2+{\left(\mathrm{Bl}\right)}^2+K_2{K}_3{K}_4{K}_p\mathrm{Bl}]s+K_1{K}_3{K}_4{K}_p\mathrm{Bl}}$

$=\frac{K_3{K}_p\mathrm{Bl}}{R}\·\frac{\mathrm{Bl}}{\frac{\mathrm{mL}}{R}{s}^3+(m+\frac{c_{2}L}{R})s^2+[c_2+\frac{{\left(\mathrm{Bl}\right)}^2+K_2{K}_3{K}_4{K}_p\mathrm{Bl}}{R}]s+\frac{K_1{K}_3{K}_4{K}_p\mathrm{Bl}}{R}}$

In the formula, m is the gross mass of moving component and load; c ₂For the damping that produces by other factors beyond the supporting system, like air damping; B is the magnetic induction intensity in control air crack; L is the length of moving coil winding; L is the equivalent inductance of moving coil winding; R is the equivalent resistance of moving coil winding; K ₁It is the multiplication factor of first adjustable amplifier; K ₂It is the multiplication factor of second adjustable amplifier; K ₃It is the multiplication factor of proportional controller; K ₄It is the multiplication factor of adjustable phase shifter; K _pIt is the multiplication factor of power amplifier; S=j ω is complex frequency;

Parameter

has reflected the damping characteristic of system, and parameter

has reflected the rigidity characteristic of system.

3. the electromagnetic type shaking table system with adjustable electric viscoplasticity bracing or strutting arrangement as claimed in claim 2 is characterized in that: described electromagnetic type shake table is under low frequency and ultralow frequency motion conditions, and the transfer function of shaking table system is:

$G\left(s\right)=\frac{X\left(s\right)}{U\left(s\right)}=K_3{K}_P\·\frac{\mathrm{Bl}}{{\mathrm{mRs}}^2+[{\mathrm{Rc}}_2+K_2{K}_3{K}_4{K}_P\mathrm{Bl}+{\left(\mathrm{Bl}\right)}^2]s+K_1{K}_3{K}_4{K}_P\mathrm{Bl}}$

$=\frac{K_3{K}_P\·\mathrm{Bl}}{R}\·\frac{1}{{\mathrm{ms}}^2+[c_2+\frac{K_2{K}_3{K}_4{K}_P\mathrm{Bl}+{\left(\mathrm{Bl}\right)}^2}{R}]s+\frac{K_1{K}_3{K}_4{K}_P\mathrm{Bl}}{R}}$

System is equivalent damping coefficient

System equivalent stiffness coefficient is

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