CN202218993U - Self-damping vibration restraining maglev artificial heart blood pump rotor - Google Patents

Abstract

The utility model discloses a self-damping vibration restraining maglev artificial heart blood pump rotor which comprises a circular rotor body suspending in a blood pump through a maglev system, the rotor body rotates around a rotation shaft in the center of the rotor body, the rotor body is internally provided with a hollow part, at least one damping block is arranged in the hollow part, the damping block is connected with the rotor body through an elastic connector, and the hollow part is full of damping liquid. The self-damping vibration restraining maglev artificial heart blood pump rotor has the following main beneficial effects: with the arrangement of the damping block and the damping liquid, damping can be provided for sway and vibration of the rotor in the rotor. Therefore, vibration of the blood pump rotor caused by various imbalances is reduced, the heating of the maglev system can be reduced, the scraping between the blood pump rotor and a stator can be reduced, the possibility of failure of magnetic levitation is greatly lowered, and the reliability and the comfort level of an artificial heart system are improved.

Description

A kind of self-damping suppresses the magnetic suspension manual heart blood pump rotor of vibration

Technical field

This utility model belongs to technical field of medical instruments, relates to a kind of implanted artificial organ manufacturing technology, relates in particular to a kind of rotor that uses the artificial heart blood pump of magnetic levitation technology.This utility model has also related to the dynamics field of rotor, especially under the rotor situation that possibly resonate to the inhibition of vibration.

Background technology

The fast development of artificial heart mainly has benefited from the fast development of its critical piece blood pump, and nowadays, the magnetic suspension blood pump has become a kind of important technology in the artificial heart of new generation.In order to reach the property inserted requirement, the magnetic suspension magnetic circuit to artificial heart carries out very careful optimization usually.Blood pump makes impeller suspended through magnetic suspension system; The direct permanent magnetismization of impeller is inserted the permanent magnetism coil in the stator of blood pump, interact through axial between magnetized impeller and stator or the pump case and radial magnetic field; Make impeller suspended in the middle of pump case, the rotation of drive systems impeller.Along with the development of technology, suspended impeller can be directly as the rotor of motor, the motor directly variation through magnetic force drives the wheel rotation that suspends and promotes blood flow.

In general, the coupling mutually of the magnetic suspension in the artificial heart, motor magnetic circuit, the magnetic balance of blood pump rotor, dynamic balancing error can't accomplish zero.Because above-mentioned imbalance problem, will receive the corresponding interference of certain subharmonic so during the blood pump rotor rotation with rotor speed.

There is a resonant frequency in the blood pump rotor rocking on the direction driven suspension often.When the described interferential frequency in front near or when equaling the resonant frequency of rotor; Rotor will produce violent resonance; Increase the heating of magnetic suspension system greatly; Increase the probability that scraping of rotor and stator even magnetic suspension were lost efficacy, thereby reduced the reliability and the comfort level of artificial heart system.

The utility model content

The purpose of this utility model provides the magnetic suspension manual heart blood pump rotor that a kind of self-damping suppresses vibration.

The purpose of this utility model will be achieved through following technical scheme:

A kind of self-damping suppresses the magnetic suspension manual heart blood pump rotor of vibration; Comprise through maglev system suspension in the intermediary annular rotor body of blood pump; Said rotor body rotates around the rotating shaft that it is positioned at the center, is provided with a hollow bulb in the said rotor body, is placed with at least one damping block in the said hollow bulb; Said damping block is connected through elastomeric connector with said rotor body, is full of damping fluid in the said hollow bulb.

Preferably, through rotor body, two axial ends of said rotor body are fixed with an end cap outward respectively to said hollow bulb for axially.Prepare hollow bulb and more convenient like this.

Preferably, said hollow bulb is annular or sphere.

Preferably, the outer peripheral face of said damping block is a curved surface.

Preferably, said damping block axially upwards offers at least one damping through hole respectively with the footpath.So just more can be through calculating the damped coefficient of controlling damping block more accurately.

Preferably, said damping block axially connects with the damping through hole that directly makes progress each other.

Preferably, said elastomeric connector is a spring wire, and an end is connected in damping block, and the other end is connected in first side that is close in rotating shaft of the hollow bulb of rotor body.

Preferably, the roughness of the contact surface of said rotor body and damping block and damping fluid is greater than the surface roughness of rotor body most peripheral.

Preferably, the one of which of second side that is away from rotating shaft of the hollow bulb of said rotor body or damping block outer surface or damping through-hole surfaces or all surface are corrugated or screw-like.

Preferably, the coefficient of viscosity of said damping fluid is greater than the coefficient of viscosity of water and less than the coefficient of viscosity of machine oil, the diameter of said damping hole is directly proportional with the resonant frequency of the coefficient of viscosity of damping fluid and rotor body.

The beneficial effect of this utility model is mainly reflected in: through the setting of damping block and damping liquid, can damping is provided in the inside of rotor the vibration of rocking of rotor self.In view of the above; Because the vibration of the blood pump rotor that various imbalances cause will significantly reduce, thereby reduce the heating of magnetic suspension system, reduce the scraping of blood pump rotor and stator; Reduce the probability that magnetic suspension was lost efficacy greatly, and then improved the reliability and the comfort level of artificial heart system.

Description of drawings

Fig. 1 is vertical cut-away view of this utility model first embodiment.

Fig. 2 is the horizontal cut-away view of this utility model first embodiment.

Fig. 3 is vertical cut-away view of this utility model second embodiment.

Fig. 4 is rotating speed and the amplitude relation curve chart that this utility model is used to show damping.

The specific embodiment

This utility model provides a kind of self-damping to suppress the magnetic suspension manual heart blood pump rotor of vibration; Shown in Fig. 1 to 3; Comprise through maglev system suspension that in the intermediary annular rotor body 1 of blood pump said rotor body 1 is around rotating shaft 2 rotations at its center, said rotor body 1 offers a cylindrical hollow 4 along its axial end that axially runs through said rotor body 1; Be provided with at least 1 damping block 5 in the said hollow bulb 4, damping block 5 the bests are 6-12.

In order to prevent that the damping block 5 and the inner surface of hollow bulb 4 from being the outside end face 5 generation frictions of rotor and conflicting; The outer peripheral face 51 of said damping block 5 is a curved surface; First side 12 of said damping block 5 and said rotor body 1 is through can axially rocking also and can be connected at radially extended elastomeric connector 3 simultaneously; If confirming does not have radial vibration, 3 functions that can only realize circumferentially rocking of elastomeric connector.Certainly, elastomeric connector 3 also can be connected with second side 11 of rotor body 1.The elastomeric connector 3 general spring wires that adopt get final product.

In said hollow bulb 4, be filled with the damping fluid 6 of the partially submerged or complete submergence damping block 5 of ability.The adding of damping fluid 6, when rotor body 1 in the preparation, on one side end cap fixed again the other end fixed after damping fluid 6 is added in the back; Perhaps also can adopt the method for this utility model: use end cap with rotor seal earlier, and keep somewhere the fill orifice that is used to pour into damping fluid.For choosing of damping fluid 6, the coefficient of viscosity of said damping fluid 6 is greater than the coefficient of viscosity of water and less than the coefficient of viscosity of machine oil; Reason is, if damping characteristic is too little, then damping is also very little.If damping characteristic is too big, then damping block will move with rotor, not have damping action.Because damping block 5 also has been full of damping fluid 6 in the distribution of the position of hollow bulb 4 relation between the gap between each damping block 5, also can play the effect of damping.

Axial and the footpath of said damping block 5 upwards offers at least one damping through hole 8 respectively.Particularly, the diameter of said damping through hole 8 is directly proportional with the coefficient of viscosity of damping fluid 6 and the resonant frequency of rotor body 1.It is relevant with the resonant frequency of the axial dimension of the coefficient of viscosity of damping fluid 6 and rotor body 1, rotor that the diameter of damping through hole 8 is chosen.Axial resonance frequency is high more, and the damped coefficient of damping fluid 6 is high more, and the diameter of damping through hole 8 is big more.Axial dimension is big more, and the diameter of damping through hole 8 is big more.Certainly, the quantity of damping through hole 8 can be decided as required.Said damping through hole 8 is linear or shaped form, has been full of damping fluid 6 in the damping through hole 8.More than these results all derive by follow-up computing formula.

The surface of second side 11, damping block 5 outer surfaces and the damping through hole 8 of said rotor body 1 is called the damping surface.In order to increase damped coefficient, the damping surface all is formed with corrugated or the screw-like with certain roughness.

Certainly, as shown in Figure 3 in order to improve damping characteristic, the another embodiment of this utility model, hollow bulb 4 is a spherical, perhaps also can other shapes.Be full of damping fluid 6 in the hollow bulb 4.The outer surface 51 of damping block 5 wherein is a curved surface.

During the blood pump working rotor of this utility model; Rotor body 1 is around rotating shaft 2 rotations the time; If rotor body 1 steadily rotates; Then the damping block 5 in the rotor body 1, damping liquid 6 and elastomeric connector 3 finally all will together rotate with rotor body 1, and the relative velocity between them is zero, and whole motion conditions is identical with solid rotor.

When rotor body 11 is receiving the influence that becomes the perturbed force of certain subharmonic with rotating speed; And when resonance takes place; Rotor body 11 will have 3 kinds of behaviors: A. rotor body 11 is done axial vibration along rotating shaft 2; B. the rotating shaft of rotor body 1 deflects, and rocks vibration, and C. rotor body 1 produces radial vibration.

Particularly, rotor as shown in Figure 1, its characteristic is different with solid rotor when above-mentioned vibration takes place.Rock or during rotational vibration, because inertia and gyroscopic effect, the state that damping block 5 tends to keep original is constant.At this moment, deformation takes place in elastomeric connector 3, and rotor body 1 changes with the end play of damping block 5.At this moment, damping fluid 6 must flow through this end play or damping through hole 8.Owing to the viscosity property of damping fluid 6 and the turbulent flow that the damping surface causes, the vibrational energy of whole rotor will be depleted in the flow process.Like this, the sharp-pointed resonance peak of rotor on this rotating speed will disappear, thus rotor can be between original resonance region in operate as normal.

When radial vibration took place, because inertia, the state that damping block 5 tends to keep original was constant.At this moment, deformation takes place in elastomeric connector 3, show as length and change, so the radial clearance of rotor body 1 and damping block 5 changes.At this moment, damping fluid 6 must flow through this radial clearance or damping through hole 8.Owing to the viscosity property of damping fluid 6 and the turbulent flow that the damping surface causes, the vibrational energy of whole rotor will be depleted in the flow process.Like this, the sharp-pointed resonance peak of rotor on this rotating speed will disappear, thus rotor can be between original resonance region in operate as normal.

Effect through concrete data verification this utility model magnetic suspension rotor below.

One, the precession of magnetic suspension rotor with reverse:

When rotor received the moment of face of vertical and rotor direction of rotation, the direction of rotor angular momentum can change.Satisfy following formula

${\mathrm{\ω}}_p=\frac{T}{I_s{\mathrm{\ω}}_s}---\left(1\right)$

ω _pPrecession frequency

The T opplied moment

I _sThe rotor axial angular momentum

ω _sRotor velocity

During the magnetic suspension support rotor, rocking the relevant parameter of vibration with rotor is torsional rigidity k _mSuppose that the rotor windup-degree is θ, the moment that then produces does

T＝k _mθ (2)

In conjunction with (1), obtain the precession frequency of rotor and the relation of torsion angle

${\mathrm{\ω}}_p=\frac{k_m}{I_s{\mathrm{\ω}}_s}\mathrm{\θ}---\left(3\right)$

Two, magnetic suspension rotor precessional resonance:

(3) formula is the situation of stable precession.In the practical situation, rotor can be done the precession vibration according to a certain frequency.Its vibration is described by Eulerian equation

I _sθ _x″＝-k _mθ _x-B _mθ _x′-H _yθ′

I _sθ _y″＝-k _mθ _y-B _mθ _y′+H _xθ′ (4)

Wherein

B _mAxially damping (the handled key parameter of this patent)

H=I _sω _sAxial angular momentum

Its component equation can be write as

${\left(\begin{array}{c}{\mathrm{\θ}}_x\\ {\mathrm{\θ}}_y\\ {\mathrm{\θ}}_x^{\′}\\ {\mathrm{\θ}}_y^{\′}\end{array}\right)}^{\′}=\left(\begin{array}{cccc}0& 0& 1& 0\\ 0& 0& 0& 1\\ {-k}_m/I_s& 0& {-B}_m/I_s& -H/I_s\\ 0& {-k}_m/I_s& H/I_s& {-B}_m/I_s\end{array}\right)\left(\begin{array}{c}{\mathrm{\θ}}_x\\ {\mathrm{\θ}}_y\\ {\mathrm{\θ}}_x^{\′}\\ {\mathrm{\θ}}_y^{\′}\end{array}\right)$ (5)

$=\left(\begin{array}{cccc}0& 0& 1& 0\\ 0& 0& 0& 1\\ {-a}_r& 0& {-b}_r& {-c}_r\\ 0& {-a}_r& c_r& -b_r\end{array}\right)\left(\begin{array}{c}{\mathrm{\θ}}_x\\ {\mathrm{\θ}}_y\\ {\mathrm{\θ}}_x^{\′}\\ {\mathrm{\θ}}_y^{\′}\end{array}\right)$

This equation has two different character values

${\mathrm{\λ}}_p=\frac{1}{2}[{-b}_r+{\mathrm{ic}}_r+\sqrt{{b_r}^2-{c_r}^2-{4a}_r-{2\mathrm{ib}}_r{c}_r}]$ (6)

${\mathrm{\λ}}_n=\frac{1}{2}[{-b}_r+{\mathrm{ic}}_r-\sqrt{{b_r}^2-{c_r}^2-{4a}_r-{2\mathrm{ib}}_r{c}_r}]$

Therefore its precession and nutation frequency can be in the hope of doing

${\mathrm{\ω}}_p=\left|{\mathrm{\λ}}_p\right|,{\mathrm{\ζ}}_p=-\frac{\mathrm{Re}\left({\mathrm{\λ}}_p\right)}{{\mathrm{\ω}}_p}$ (7)

${\mathrm{\ω}}_n=\left|{\mathrm{\λ}}_n\right|,{\mathrm{\ξ}}_n=-\frac{\mathrm{Re}\left({\mathrm{\λ}}_n\right)}{{\mathrm{\ω}}_n}$

We calculate a rotor instance.The parameter of this rotor is:

Rotor height	14.5	Millimeter
			Root diameter	25	Millimeter
Rotor quality	100	Gram
			Inclination rigidity	5.6956	N-m/rad
The inclination damping	7.25e-6	N-m-s/rad
			Precession critical speed	1566	RPM

According to (7) formula, can obtain, when the rotating speed of rotor rose, its precession frequency descended.When the rotating speed of rotor equaled precession frequency, resonance promptly can take place in rotor.This frequency also becomes the critical frequency of rotor.The amplitude of precessional resonance is relevant with the damping characteristic of rotor.

Three, the damping of the precessional resonance of magnetic suspension rotor

If the rotary inertia of the damping block 5 of the said rotor of this patent is I ₅, the rotary inertia of removing after damping fast 5 and the damping fluid 6 is I ₁, ignore the quality of damping fluid 6.The value of choose reasonable damping fluid 6 can be adjusted the damped coefficient of whole rotor.Damping ratio, the damping torque that promptly receives under the unit angular velocity can be expressed as

$\frac{T}{{\mathrm{\&omega;}}_p}=\&Integral;{\mathrm{\&mu;<figure-callout\; id="2"\; label="gr"\; filenames="HSA00000562511400021.png,HSA00000562511400031.png"\; state="\{\{state\}\}">gr</figure-callout>}}^2\mathrm{dS}---\left(8\right)$

Wherein μ is the coefficient of viscosity of damping fluid 6, and g is the occupied gap (damping gap) of damping fluid 6, and r is damping fluid 6 residing radiuses, and s is a damping block 5 and the contact area of liquid.Generally, have only the outside liquid (blood) of rotor that damping is provided.In this patent scheme, the coefficient of viscosity μ of damping fluid 6, damping gap g, especially damping work area S can improve greatly.Only, just can damping ratio be improved more than 10 times through damping through hole 8 is set on damping block 5.This means that under the situation of other parameter constants the amplitude of rotor will be attenuated to original about 1/10.

Shown in Figure 4 is the concrete effect example of this utility model, shows that rotor whenever rotates a circle to receive twice interference.Therefore, in the process that rotating speed improves, at first be that 2 subharmonic of rotating speed cause resonance, be 1 subharmonic of rotating speed causes resonance then, one has two critical frequencies.Self-damping through this utility model suppresses the method for vibration, and damping ratio is improved 10 times, is example with first resonance peak, finds that it approximately is original 1/10 that amplitude has been reduced to.

The effect of this utility model is embodied in: through at inner damping block and the damping fluid of increasing of magnetic suspension rotor, can increase the damped coefficient that rotor rocks vibration, reduce the amplitude under the kindred circumstances, improve the stability and the reliability of magnetic suspension rotor.

This utility model still has numerous embodiments, and all employing equivalents or equivalent transformation and all technical schemes of forming all drop within the protection domain of this utility model.

Claims (10)

1. a self-damping suppresses the magnetic suspension manual heart blood pump rotor of vibration; Comprise through maglev system suspension in the intermediary annular rotor body of blood pump; Said rotor body rotates around the rotating shaft that it is positioned at the center, it is characterized in that: be provided with a hollow bulb in the said rotor body, be placed with at least one damping block in the said hollow bulb; Said damping block is connected through elastomeric connector with said rotor body, is full of damping fluid in the said hollow bulb.

2. suppress the magnetic suspension manual heart blood pump rotor of vibration according to the said a kind of self-damping of claim 1, it is characterized in that: through rotor body, two axial ends of said rotor body are outward respectively through an end cap fixing seal for axially for said hollow bulb.

3. suppress the magnetic suspension manual heart blood pump rotor of vibration according to the said a kind of self-damping of claim 1, it is characterized in that: said hollow bulb is annular or sphere.

4. suppress the magnetic suspension manual heart blood pump rotor of vibration according to the said a kind of self-damping of claim 1, it is characterized in that: the outer peripheral face of said damping block is a curved surface.

5. suppress the magnetic suspension manual heart blood pump rotor of vibration according to the said a kind of self-damping of claim 1, it is characterized in that: the axial and footpath of said damping block upwards offers at least one damping through hole respectively.

6. suppress the magnetic suspension manual heart blood pump rotor of vibration according to the said a kind of self-damping of claim 5, it is characterized in that: the damping through hole that axially makes progress with the footpath of said damping block connects each other.

7. the magnetic suspension manual heart blood pump rotor that suppresses vibration according to the said a kind of self-damping of claim 1; It is characterized in that: said elastomeric connector is a spring wire; One end is connected in damping block, and the other end is connected in first side that is close in rotating shaft of the hollow bulb of rotor body.

8. suppress the magnetic suspension manual heart blood pump rotor of vibration according to the said a kind of self-damping of claim 1, it is characterized in that: the roughness of the contact surface of said rotor body and damping block and damping fluid is greater than the surface roughness of rotor body most peripheral.

9. said according to Claim 8 a kind of self-damping suppresses the magnetic suspension manual heart blood pump rotor of vibration, and it is characterized in that: second side that is away from rotating shaft of the hollow bulb of said rotor body or the one of which of damping block outer surface or damping through-hole surfaces or all surface are corrugated or screw-like.

10. the magnetic suspension manual heart blood pump rotor that suppresses vibration according to the said a kind of self-damping of claim 1; It is characterized in that: the coefficient of viscosity of said damping fluid is greater than the coefficient of viscosity of water and less than the coefficient of viscosity of machine oil, the diameter of said damping hole is directly proportional with the resonant frequency of the coefficient of viscosity of damping fluid and rotor body.

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