CN1963537A - An eddy-current screen filter and its design method - Google Patents
An eddy-current screen filter and its design method Download PDFInfo
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- CN1963537A CN1963537A CN 200610144019 CN200610144019A CN1963537A CN 1963537 A CN1963537 A CN 1963537A CN 200610144019 CN200610144019 CN 200610144019 CN 200610144019 A CN200610144019 A CN 200610144019A CN 1963537 A CN1963537 A CN 1963537A
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Abstract
This invention relates to one meter device and method in meter process relatively to low temperature current comparator device, which can eliminate high frequency interference in low temperature comparator system, wherein, the whirl screen filter set in the low temperature current comparator to solve the problems of high frequency interference in low temperature current comparator system; the said whirl current filter device comprises test coil in the comparing system and the said test coil is of conductive materials.
Description
Technical field:
The invention belongs to a kind of a kind of gauging instrument and method thereof in metering process, relevant with the cryo-current comparator device.Relate in particular to and a kind ofly in the cryo-current comparator system, can eliminate high frequency interference, stablize the eddy-current screen filter and the method for designing thereof of cryo-current comparator duty.
Background technology:
In the electricity metering, voltage standard and resistance standard are two kinds of the most basic standards.As long as this two kinds of standards have been arranged, other standard all can derive therefrom.In actual applications, the resistance standard is preserved and is kept by calibration resistor, so it is very important to be used for the surveying instrument of standard of comparison resistance value.
1980, the blue or green professor of the Feng Keli of Germany found the quantization Hall effect, and the quantization Hall effect is meant under the condition of high-intensity magnetic field and ultralow temperature, and the two-dimensional electron gas in the semiconductor devices can complete quantization, and the Hall resistance of this moment is
H is a Planck's constant herein, and e is the elementary charge electric weight, and i is a positive integer.
An important feature of formula (1) is the Hall resistance R after the quantization
HOnly relevant with physics constant h and e, all irrelevant with material and other external condition of device.This is a kind of very ideal situation.People can reappear unit of resistance in view of the above, are not subjected to the restriction of place, time.Therefore from find, the standard laboratory of various countries has dropped into big strength and has set up this kind " quantum resistance benchmark ", and has raked in achievement.
Satisfying under the condition of complete quantization, the numerical value of the Hall resistance of the platform area of quantization Hall effect correspondence only depends on constant h/e
2This constant is made up of physics constant, can not change in principle, and it is very desirable being used to reappear unit of resistance.Using GaAs-Al
XGa
1-XDuring the As heterojunction device, the quantization Hall resistance value at corresponding with the gap between the Landau sub-band of first and second nature the is platform place of i=2 is
R
H=h/(2e
2)=25812.807Ω=12906.4035Ω (2)
This be one by the 18th CCE meeting suggestion, and obtain after the approval of the 77th CIPM the international recommendation of the quantization Hall resistance benchmark worldwide enabled from January 1 nineteen ninety.Each National Laboratory that has built up quantization Hall resistance experimental provision has all set up the quantum resistance benchmark of oneself according to formula (2).
Utilize formula (2) to set up accurately and can will overcome the difficulty of some measuring technique aspects for the decade resistance benchmark of daily calibration operation use.At first, what formula (2) provided is a non integer value, could compare with common decade resistance with special method.Simultaneously, formula (2) is used as error free constant in fact as international recommendation.Therefore, aspect measuring technique, need develop a kind of exact instrument that can compare to pin-point accuracy non integer value resistance value.
The traditional energy pin-point accuracy ground relatively exact instrument of non integer value resistance value has two types.First kind is the Harmon measurer method that obtains non-integer resistance value ratio with the resistance series-parallel connection method, can reach the uncertainty of 10-8 magnitude.Many laboratories once made and obtained result preferably in this way the eighties.But it is more loaded down with trivial details that this method uses, and the instability of resistive element has also limited the further raising of this kind method accuracy, therefore seldom uses in recent years.Second method is to grow up the nineties and progressively ripe cryo-current comparator method, can reach 10
-9-10
-10Magnitude.
The principle of work of cryo-current comparator as shown in Figure 1.The radio-frequency signal generator of 180MHz is fed to radiofrequency signal the resonant tank that is made of resonance coil and electric capacity.The centre frequency of this resonant tank is aimed at the output frequency of radio-frequency oscillator, and the amplitude of the radiofrequency signal on the resonant tank is detected by a wave detector.Radio-frequency coil and unijunction SQUID loop are coupled, and the radiofrequency signal amplitude of resonant tank should be adjusted to and satisfy the magnetic flux make in the SQUID loop condition a little less than a quantum magnetic flux.
Among Fig. 1, the ampere turns I in the cryo-current comparator primary coil
1W
1Ampere turns I with secondary coil
2W
2Should balance each other.In case slightly unbalance, just have unbalanced signal and be coupled in the magnetic test coil.Magnetic test coil and pickup coil are all used the superconducting line coiling, and both link together and have constituted the superconducting circuit of a closure.Based superconductive loop constant flux linkage theorem, the uneven magnetic flux in the magnetic test coil also can induce corresponding magnetic flux in pickup coil, and making the total magnetic flux in this closure superconducting circuit is zero.Magnetic flux in the pickup coil is coupled with the SQUID loop again, makes to produce corresponding electric current in the SQUID loop.When this electric current surpassed the critical current of Josephson junction in the SQUID loop, the magnetic flux in this SQUID loop will quantum magnetic flux of saltus step.Process is corresponding therewith, can the produce power loss.When being coupled to the continuous break-in of radio-frequency current of resonant tank from radio-frequency signal generator, this kind energy loss process causes the quality factor q value of resonant tank to reduce constantly repeatedly, and the amplitude of the radiofrequency signal on the resonant tank is also corresponding to be reduced.In other words, the amplitude of the radiofrequency signal on the resonant tank can reflect the uneven situation of ampere turns of the primary and secondary coil of cryo-current comparator.After the situation of change of this radiofrequency signal amplitude is detected by wave detector, after links such as filtering, amplification, feed back in the supply current source of secondary coil of cryo-current comparator, constitute closed feedback system, make the ampere turns of the primary and secondary coil of cryo-current comparator remain on equilibrium state.Thereby I
1W
1And I
2W
2Sum is zero.I
1With I
2Ratio just equal (W
2/ W
1).W
1And W
2Represent the number of turn of primary and secondary coil respectively, be positive integer, so I
1With I
2Ratio also just become the ratio of two positive integers, very accurate, the basic functional principle of Here it is cryo-current comparator.
Extensively adopt in the cryo-current comparator system that above-mentioned principle of work is developed abroad, but wherein there is a bigger problem, as shown in Figure 1, the low-pass filter of wave detector back is made of the RC circuit, when frequency is higher, there is distributed capacitance on the resistive element R, has distributed inductance among the capacity cell C.These distribution parameters make RC circuit filtering high-frequency signal well when high frequency.Remaining high-frequency signal can be scurried in the cryo-current comparator secondary loop by amplifying return circuit, constituted the closed feedback loop of high-frequency signal again through magnetic test coil, pickup coil, SQUID loop etc., the duty of cryo-current comparator system is interfered, can produces a series of wild effect.Therefore how to eliminate high frequency interference effectively, become and stablize the cryo-current comparator duty, reduce the cryo-current comparator measuring error, improving accuracy of measurement is the present technical issues that need to address.
Summary of the invention:
The present invention in order to solve because the skeleton of magnetic test coil of the prior art can not the filtering high-frequency interferencing signal with pottery, this class insulating material of plastics, and this type of signal is coupled in the magnetic test coil, form closed feedback loop, reduced the technical matters of the stability of cryo-current comparator feedback system, and a kind of eddy-current screen filter and the method for designing thereof of development.
Technical scheme of the present invention is:
A kind of eddy-current screen filter, described eddy-current screen filter is arranged in the cryo-current comparator system, is used for solving the problem of the high frequency interference of cryo-current comparator system; Described eddy-current screen filter is included in the magnetic test coil of cryo-current comparator system, and the skeleton of described magnetic test coil is a conductive material.
In concrete experiment, described eddy-current screen filter comprises the superconducting coil that adheres on conducting matrix grain and the skeleton outside surface, and the conducting matrix grain of promptly concrete described eddy-current screen filter adopts nonmagnetic brass material; The material of the superconducting coil that adheres on the described skeleton outside surface is a scolding tin.
A kind of method for designing of eddy-current screen filter, described eddy-current screen filter is arranged in the cryo-current comparator system, is used for solving the problem of the high frequency interference of cryo-current comparator system; Described method is that the skeleton of the magnetic test coil in the cryo-current comparator system is set to brass material conducting matrix grain, has solved the not high problem of the too low or too high filtering performance that causes of conductivity because of the skeleton of magnetic test coil.
Described method comprises:
1, makes the skeleton step of magnetic test coil: take conductive material to make the skeleton of magnetic test coil;
2, coating superconducting layer step: the superconducting layer that coating is made of soldering-tin layer on conducting matrix grain;
3, form superconduction magnetic test coil step: on the superconducting layer of step 2, carve a helix with lathe tool.Remove superconductor in spiral (line) line until in spiral (line) line, conducting matrix grain occurring, promptly formed the superconducting coil of a thin layer type on the conducting matrix grain surface.Promptly on the superconducting layer of conducting matrix grain coating, carve a screw-shaped groove, and remove the superconductor part in the groove with lathe tools.Such way is equivalent to and has covered one with the affected thin layer molded lines circle of superconductor on the skeleton surface.
The conducting matrix grain of described eddy-current screen filter adopts nonmagnetic brass material; The material of the superconducting coil that adheres on the described skeleton outside surface is a scolding tin; Promptly formed the scolding tin coil of a thin layer type on brass skeleton surface.
When the skeleton of magnetic test coil is made with insulating material, owing to there is not the eddy current filter effect described in the background technology, high-frequency signal is run helter-skelter in system, the concentric cable geometric position of each parts of connected system changes slightly, will produce significantly influence to the duty of system, total system is difficult to steady operation.Sometimes also the high frequency spurious oscillation can take place in the system, make working state of system not normal.When we make the skeleton of magnetic test coil with conductive material after, more than said bad phenomenon all can not occur, the good steady operation of system has reached higher technical merit.
Description of drawings:
Fig. 1 is the principle of work of cryo-current comparator;
Fig. 2 is that the eddy current in the conduction short-circuit loop stops the high frequency magnetic flux to penetrate in the loop;
Fig. 3 is the curve of output design sketch that the skeleton of magnetic test coil adopts electric bridge zero indicator behind nonconducting high frequency magnetic material;
Fig. 4 is the curve of output design sketch that the skeleton of magnetic test coil adopts electric bridge zero indicator behind the nonmagnetic brass material.
Embodiment:
The invention solves the problem of the high frequency interference in the cryo-current comparator system.Introduce earlier for this reason that the shielding action owing to eddy current makes the high frequency magnetic flux can't invade the notion in loop in the conduction closed-loop path of short circuit.
If the resistance in the galvanic circle of the short circuit among Fig. 2 is R, inductance is L.If an extraneous magnetic flux will penetrate the loop, then can induce eddy current in the loop, resist penetrating of extraneous magnetic flux.According to electrotechnical principle, the time constant of galvanic circle is τ=L/R, is the alternating flux of ω if extraneous magnetic flux is an angular frequency, and when ω>>1/ τ, eddy current will eject the loop to alternating flux, and alternating flux can not penetrate the loop.
Magnetic test coil among Fig. 1 generally need be with a skeleton, so that the coiling of coil.The skeleton of magnetic test coil pottery commonly used, this class insulating material of plastics are made in the cryo-current comparator system that make in external laboratory.The method that patent of the present invention proposes is exactly the skeleton of the detection among Fig. 1 to be used instead conductive material make, so just can utilize the eddy current filtering high-frequency interferencing signal in the skeleton very naturally, make this class signal can't be coupled in the magnetic test coil at all, therefore thoroughly block the closed feedback loop of aforesaid high-frequency signal, thereby improved the stability of cryo-current comparator feedback system greatly.Seem that this is a very simple method, but effect is fairly obvious.Experiment shows, when the skeleton of magnetic test coil is made with insulating material, owing to there is not the eddy current filter effect described in the background technology, high-frequency signal is run helter-skelter in system, the concentric cable geometric position of each parts of connected system changes slightly, will produce significantly influence to the duty of system, total system is difficult to steady operation.Sometimes also the high frequency spurious oscillation can take place in the system, make working state of system not normal.When we make the skeleton of magnetic test coil with conductive material after, more than said bad phenomenon all can not occur, the good steady operation of system reaches good technical effect.
It is a very important techniques problem that the framework material of magnetic test coil is selected, and this point mainly is reflected on the spectral characteristic of noise.When using nonmagnetic brass to make skeleton,, also help the elimination of current jump phenomenon because the effect of eddy current has reduced much high-frequency interferencing signal in the brass, thereby makes the feedback system of cryo-current comparator more stable.But when making skeleton, find that the low-frequency noise of system increases to some extent, cause accuracy of measurement to reduce with the more good red copper of electric conductivity (conductivity of red copper is than high tens of times of brass under liquid helium temperature).According to analysis, this phenomenon be since in the red copper skeleton low frequency component of thermonoise big due to.Make the galvanic circle that the magnetic test coil skeleton has formed a closure with conductive material, the average energy of current in loop thermonoise is kT.Be Boltzmann constant, T is a liquid helium temperature.In frequency domain, these electrical current heat noise energies will be evenly distributed in the passband of galvanic circle.If the passband of galvanic circle is than broad, the low frequency component of electrical current heat noise is just smaller.And concerning the magnetic test coil of red copper skeleton, very high in liquid helium temperature lower skeleton conductivity of electrolyte materials, according to calculating, the passband of the galvanic circle that is formed by skeleton is less than 1 hertz.Total amount is that the electrical current heat noise energy of kT is compressed in the narrow like this passband, and its low frequency component is just bigger naturally.Simultaneously, the electrical current heat noise in the galvanic circle of skeleton must be coupled to the input end of SQUID by magnetic test coil, and its low frequency component will make the zero indicator output signal rock and influence accuracy of measurement.
Except correct selection framework material, can another key technical problem that obtain better filter effect be the manufacture craft of magnetic test coil.Can this be the key that obtain better filter effect.
In schematic diagram shown in Figure 1, magnetic test coil is only represented with a few circle helixes.Do not show with how combining between the brass skeleton.But this also is a very important problem.If solve badly, the filter effect of eddy-current screen filter will be reduced greatly.
The commonsense method that is manufactured with the coil of skeleton in the prior art is to cover one deck insulating material on skeleton, again the coil of circle on insulating material.If also with such method magnetic test coil and brass coil are combined, the filter effect of eddy-current screen filter will greatly reduce.This is because have the space between circular coil and the brass skeleton.Insulating material has more strengthened such space.When flowing through electric current in the magnetic test coil, electric current also can produce magnetic flux in the space.And because the lead of close magnetic test coil of the magnetic flux in the space, magnetic flux density is also the strongest, thereby the magnetic flux in the space will be to occupy suitable ratio in the total magnetic flux of magnetic test coil.Magnetic flux in the space generally just is called leakage flux.Magnetic flux in the brass skeleton then is called main flux.Leakage flux all exists in various coils, but does not generally play a leading role, and is a kind of secondary phenomenon of association.But in eddy-current screen filter of the present invention, leakage flux can influence filter effect to a great extent.This is because the main flux in leakage flux and the brass skeleton is the addition relation.High fdrequency component in the main flux is because the filter action meeting of eddy current obtains decay, but leakage flux is present in the helium space, is not subjected to the influence of eddy current, and high fdrequency component just can intercouple between magnetic test coil and pickup coil in the clear by leakage flux.That is to say that high fdrequency component can not be coupled to the degradation that makes cryo-current comparator in the follow-up electronic circuit by main flux via leakage flux.Leakage flux proportion in total magnetic flux is big more, and this problem is also serious more.
In order to reduce leakage flux as far as possible, the present invention proposes a kind of new magnetic test coil method for making.We have coated one deck scolding tin in brass skeleton outside earlier.On soldering-tin layer, carving a helix with lathe tool on the lathe again.Scolding tin in the helix must full scale clearance, till exposing brass.Like this, just formed the scolding tin coil of a thin layer type on brass skeleton surface.Because scolding tin also is superconductor, the scolding tin coil of brass surfaces just can be as the magnetic test coil among Fig. 1.Because soldering-tin layer is very thin, is close to brass skeleton surface again, so leakage flux has been reduced to insignificant degree.The magnetic test coil and the intercoupling problem between the pickup coil that cause owing to leakage flux have also just solved basically.The filter effect of eddy-current screen filter has also obtained giving full play to.
Do not have insulation course between brass skeleton and the magnetic test coil, brass conducts electricity, and can or can not produce the bypass effect to the useful signal in the magnetic test coil is the problem that should consider.In fact, the useful signal in the magnetic test coil is a kind of direct current signal.For direct current signal, the conductance of the magnetic test coil of superconduction is infinitely great, and the conductance of brass then is limited.Therefore brass can not produce the bypass effect to the signal in the magnetic test coil.In the making of other superconducting coil, this point also often is utilized.Conductive materials such as brass, red copper, aluminium are equivalent to insulating material for superconducting coil, in superconductor technology through being commonly used for layer insulation, can increase the stability of superconducting coil, also have the good characteristic of heat conduction concurrently, play than the better effect of common insulating material.
As mentioned above, too low (as insulating material, its conductivity is zero) of the conductivity of the skeleton of magnetic test coil or too high (as red copper) all can not make the overall performance of cryo-current comparator reach best.Use the moderate material of the such conductivity of brass then can obtain result preferably.
Fig. 3 is the curve of output (design sketch) that the skeleton of magnetic test coil adopts electric bridge zero indicator behind nonconducting high frequency magnetic material, and Fig. 4 is the curve of output (design sketch) that the skeleton of magnetic test coil adopts electric bridge zero indicator behind the nonmagnetic brass material.By contrasting this two design sketchs, we can find that after adopting nonmagnetic brass material to make the skeleton of magnetic test coil, beating of cryo-current comparator electric bridge zero indicator dwindled tens times, overall performance be improved significantly.
Claims (6)
1, a kind of eddy-current screen filter, described eddy-current screen filter is arranged in the cryo-current comparator system, is used for solving the problem of the high frequency interference of cryo-current comparator system; Described eddy-current screen filter is included in the magnetic test coil of cryo-current comparator system, and the skeleton of described magnetic test coil is a conductive material.
2, a kind of eddy-current screen filter according to claim 1 is characterized in that: described eddy-current screen filter comprises the superconducting coil that adheres on conducting matrix grain and the skeleton outside surface.
3, a kind of eddy-current screen filter according to claim 1 and 2 is characterized in that: the conducting matrix grain of described eddy-current screen filter adopts nonmagnetic brass material; The material of the superconducting coil that adheres on the described skeleton outside surface is a scolding tin.
4, a kind of method for designing of eddy-current screen filter, described eddy-current screen filter is arranged in the cryo-current comparator system, is used for solving the problem of the high frequency interference of cryo-current comparator system; Described method is the conducting matrix grain that the skeleton of the magnetic test coil in the cryo-current comparator system is set to the brass material, has solved the not high problem of the too low or too high filtering performance that causes of conductivity because of the skeleton of magnetic test coil.
5, the method for designing of a kind of eddy-current screen filter according to claim 4 is characterized in that: described method comprises:
1, makes the skeleton step of magnetic test coil: take conductive material to make the skeleton of magnetic test coil;
2, coating superconducting layer step: the superconducting layer that coating is made of soldering-tin layer on conducting matrix grain;
3, form superconduction magnetic test coil step: on the superconducting layer of step 2, carve a helix; Remove superconductor in the helix groove until in helix, exposing the conducting matrix grain material, promptly formed the superconducting coil of a thin layer type on the conducting matrix grain surface.
6, the method for designing of a kind of eddy-current screen filter according to claim 5 is characterized in that: the conducting matrix grain of described eddy-current screen filter adopts nonmagnetic brass material; The material of the superconducting coil that adheres on the described skeleton outside surface is a scolding tin; Promptly formed the superconducting coil that constitutes by soldering-tin layer of a thin layer type on brass skeleton surface.
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CN107209232A (en) * | 2015-01-12 | 2017-09-26 | 赫尔穆特·惠得利 | Equipment and its application for guiding carrier |
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CN2051395U (en) * | 1989-08-19 | 1990-01-17 | 东南大学 | High quality internal deflection exciting coil |
GB2311617A (en) * | 1996-03-25 | 1997-10-01 | Cryogenic Ltd | Cryogenic current comparator |
US5880583A (en) * | 1996-12-27 | 1999-03-09 | The United States Of America As Represented By The Secretary Of Commerce | Cryogenic current comparator based on liquid nitrogen temperature superconductors |
CN1707706B (en) * | 2004-06-09 | 2010-04-28 | 中国科学院电工研究所 | High temperature superconducting double-disk coil skeleton |
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CN107209232A (en) * | 2015-01-12 | 2017-09-26 | 赫尔穆特·惠得利 | Equipment and its application for guiding carrier |
CN107209232B (en) * | 2015-01-12 | 2020-07-07 | 赫尔穆特·惠得利 | Device for guiding charge carriers and use thereof |
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