CN203759227U - Hypervelocity impact magnetic field three dimensional magnetic induction intensity measurement coil - Google Patents
Hypervelocity impact magnetic field three dimensional magnetic induction intensity measurement coil Download PDFInfo
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- CN203759227U CN203759227U CN201420056687.6U CN201420056687U CN203759227U CN 203759227 U CN203759227 U CN 203759227U CN 201420056687 U CN201420056687 U CN 201420056687U CN 203759227 U CN203759227 U CN 203759227U
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Abstract
The utility model discloses a hypervelocity impact magnetic field three dimensional magnetic induction intensity measurement coil which belongs to the technical field of impact dynamics test. The measurement coil comprises a spherical framework and three annular coils. The spherical framework is spherical. Three annular grooves which are perpendicular to each other are radially arranged on the surface of the spherical framework. The depths of three annular grooves successively decrease. Three annular coils are correspondingly wound in three annular grooves and are mutually independent. Each coil is connected with a BNC plug. The BNC plugs are connected with three external data acquisition channels which are mutually independent. According to the utility model, three coils are used to acquire magnetic induction intensity values of a point in three directions in a space, wherein the spaces of three coils are perpendicular to each other; the magnetic field information of a measurement point is comprehensively understood; interference and error, which are produced on the study of an impact magnetic field, are avoided; measured coil induced electromotive force signals are synchronous in time, thus a measurement result is accurate; and the measurement coil has the advantages of simple design and easy operation, and can be reused.
Description
Technical field
Utility model relates to a kind of measurement mechanism of measuring hypervelocity impact generation magnetic field, belongs to shock dynamics technical field of measurement and test.
Background technology
Space junk has caused a lot of spacecraft accidents to the high-speed impact of spacecraft, the hypervelocity impact that research shows space junk is not only that thump causes the spacecraft inner structure mechanics machinery causing that lost efficacy to be injured to injuring of spacecraft, also has injuring that the galvanomagnetic effect of collision initiation causes the interference of spacecraft internal circuitry.
When carrying out hypervelocity impact and generating an electromagnetic field the experiment of characteristic research, in order to obtain magnetic field that collision the produces intensity level at some place, space, because its magnetic induction density is little, conventionally adopt sandwich wound coil to measure.But conventional sandwich wound coil can only measure with coil plane vertical direction on magnetic induction density value, the magnetic-field component in None-identified parallel coil direction.Like this will be not comprehensive to the Magnetic Field understanding of this point, research is produced and disturbed, or obtain conclusion and have error.
Utility model content
In view of this, the utility model provides a kind of hypervelocity impact magnetic field Three-Dimensional Magnetic induction measuring coil, utilize three mutually perpendicular coils in space to obtain the magnetic induction density value in three directions of space point, can realize space magnetic induction density is measured more accurately.
A kind of hypervelocity impact magnetic field Three-Dimensional Magnetic induction measuring coil, comprise spherical skeleton and three toroid windings, wherein, the profile of spherical skeleton is spheroidal, the surface of spherical skeleton radially processes the three mutually perpendicular ring grooves in road, and the degree of depth of three road ring grooves is successively decreased successively; Three toroid winding correspondences are wound in three road ring grooves and are independent mutually, and each coil connects a BNC connector, and BNC connector is connected with three separate data acquisition channels of outside.
Further, three toroidal cross sections are rectangle;
Further, innermost layer toroid winding copper enameled wire diameter D is 0.29mm, and coil section axial length a is 10mm, internal coil diameter d
11for 20mm, mean diameter d
1for 25.8mm, coil outer diameter d
12for 31.6mm, the number of turn N of coil is 600, and the canoe of coil is every layer of 30 circle, totally 20 layers;
Middle layer toroid winding copper enameled wire diameter D is 0.29mm, and coil section axial length a is 10mm, the inner diameter d of coil
21for 32.73mm, outside diameter d
22for 41.43mm, mean diameter d
2for 37.08mm, the number of turn N of coil is 450, and the canoe of coil is every layer of 30 circle, totally 15 layers;
Outermost layer toroid winding copper enameled wire diameter D is 0.29mm, and coil section axial length a is 10mm, the inner diameter d of coil
31for 45.8mm, outside diameter d
32for 52.76m, mean diameter d
3for 49.28mm, the number of turn N of coil is 360, and the canoe of coil is every layer of 30 circle, totally 12 layers.
Further, described three toroidal outsides are wound around respectively the aluminium foil layer that thickness is 2mm, and to this aluminium foil layer ground connection.
The definite step of described three toroid winding parameters is as follows:
The first step: the magnetic field magnitude that produces according to laboratory condition hypervelocity impact, the resolution of the induction level of surveying and back end signal Acquisition Instrument determine the toroidal parameter of innermost layer; Parameter comprises axial length a and the radical length r in copper enameled wire diameter D, toroidal number of turn N, mean diameter d, cross section;
Second step: according to formula
Calculate the toroidal inductance of innermost layer;
Wherein, L is the inductance of square-section sandwich wound coil, μ
0for permeability of vacuum;
The 3rd step: determine middle layer toroid winding and the toroidal parameter of outermost layer in the equal condition of synchronization inductance according to three coils;
Because inductance equates with innermost layer toroid winding, in the toroidal inductance computing formula of middle layer toroid winding and outermost layer, there are 4 variablees, be respectively the number of turn N of coil, the mean diameter d of coil, the axial length a of coil section, the radical length r of coil section, according to the actual processing features of coil, is further qualified 4 variate-values; Middle layer toroid winding keeps identical with innermost layer coil with outermost layer toroid winding cross section axial dimension, and so a in inductance computing formula becomes known quantity by variable, in formula, only has 3 variablees; Middle layer toroid winding and outermost layer toroid winding employing are carried out coiling with the enameled wire of innermost layer coil same diameter, and therefore the number of turn n of every layer of winding of 3 coils is identical; If the number of plies of coil winding is unknown quantity x, enameled wire diameter is D, and internal coil diameter is d
min, the number of turn N=nx of coil; The thickness that coil is every layer equates with enameled wire diameter D, coil section radial dimension r=Dx, coil mean diameter d=d
min+ r=d
min+ Dx; Being known quantity according to the known n of the parameter of innermost layer coil and D, is d according to three variable N, r, d in the known inductance computing formula of aforementioned analysis
minwith the function of x, only surplus d in coil computing formula
minwith two variablees of x; Middle layer coil, according to inductance computing formula, can calculate corresponding internal coil diameter d according to different number of plies x
min, because the internal diameter of middle layer coil must be larger than the external diameter of innermost layer coil, get d
minbe the internal diameter of middle layer coil for being greater than the minimum value of innermost layer coil outer diameter, corresponding coil number of plies x is the number of plies of middle layer coil, the all parameters of coil can be calculated accordingly, according to the parameter of middle layer coil, the parameter of outermost layer coil can be calculated according to said process.
Principle of work: while carrying out hypervelocity impact, each toroid winding on spherical skeleton can measure the magnetic-field component vertical with this coil, according to the coil-induced electromotive force e measuring, carry out again integral and calculating and just can obtain magnetic induction density B, according to the principle of disc type " point " coil, the magnetic induction density B measuring can be used as the magnetic induction density of hub of a spool point in coil axis direction.Three coils that are mutually vertically wound on spherical skeleton can measure the magnetic induction density value of three directions of the centre of sphere, because magnetic induction density is vector, can calculate the magnetic induction density value of centre of sphere point by vector calculus.
Beneficial effect:
1, the utility model adopts three mutually perpendicular coils in space to obtain the magnetic induction density value in three directions of space point, overcome sandwich wound coil can only measure with coil plane vertical direction on the technological deficiency of magnetic induction density value, three mutually perpendicular coils in space can be identified the magnetic-field component in parallel coil direction, Magnetic Field that can full appreciation measurement point, avoids the research of collision magnetic field to produce and disturb and error.
2, the utility model passes through coil width, internal diameter, external diameter, the enameled wire diameter of three coils and is wound around determining of the correlation parameters such as the number of turn, ensure that the coil-induced electromotive force signal recording is synchronous in time, make measurement result more accurate, the research in collision magnetic field is had laid a good foundation.
3, the aluminium foil that the utility model is 2mm by the outside surface Jacket thickness of three coils; and by this aluminium foil layer ground connection; the electromagnetic interference (EMI) producing can shield external electrical field to measurement time; prevent from, owing to colliding the panus direct effect producing in experimentation to coil, can playing a protective role to inner coil simultaneously.
Brief description of the drawings
Fig. 1 is the integrally-built cut-open view of the utility model (along the toroidal section of radially crossing spherical frame center of outermost layer);
Fig. 2 is the stereographic map of the spherical skeleton of the utility model.
Wherein, 1-innermost layer toroid winding, 2-middle layer toroid winding, 3-outermost layer toroid winding, the spherical skeleton of 4-.
Embodiment
Below in conjunction with the accompanying drawing embodiment that develops simultaneously, the utility model is described in detail.
The utility model provides a kind of hypervelocity impact magnetic field Three-Dimensional Magnetic induction measuring coil, as shown in Figure 1, comprise spherical skeleton 4 and three toroid windings, the profile of spherical skeleton 4 is spheroidal, the surface of spherical skeleton 4 radially processes the three mutually perpendicular ring grooves in road, the degree of depth of three road ring grooves is successively decreased successively, as shown in Figure 2; Three toroid winding correspondences are wound in three road ring grooves and are independent mutually, and it is rectangle that three toroid windings are respectively innermost layer toroid winding 1, middle layer toroid winding 2 and 3, three toroidal cross sections of outermost layer toroid winding;
Further, described three toroidal outsides are wound around respectively the aluminium foil layer that thickness is 2mm, and to this aluminium foil layer ground connection.
According to existing related data, the magnetic field magnitude that known laboratory condition hypervelocity impact produces is nT.Can estimate accordingly the coil parameter that can identify target.From Faraday's electromagnetic induction law, the area that the sensitivity of coil is defined to coil is directly proportional, so can be using this coil as innermost layer toroid winding 1.The area that coil defines simultaneously too conference affects measuring accuracy, so can not be excessive.The copper enameled wire wire diameter that this example is selected is 0.29mm, and the parameter of innermost layer toroid winding 1 is: coil is wide is that coil section axial length a is 10mm, inner diameter d
11for 20mm, mean diameter d
1for 25.8mm, outside diameter d
12for 31.6mm, now the canoe of coil is every layer of 30 circle, and totally 20 layers, total number of turns N is 600.
Three toroid windings are independently, and synchronous in time in order to ensure signal, three toroidal inductance are identical.The inductance L of square-section annular coil is:
The inductance that can obtain innermost layer toroid winding 1 according to the computing formula of inductance is 9.49mH; Toroid winding 2 sectional axis in middle layer keep constant with innermost layer toroid winding 1 width 10mm to dimension width, adopt the enameled wire of the 0.29mm diameter identical with innermost layer toroid winding 1 to carry out coiling; Equate with Line 1 circle inductance according to middle layer toroid winding 2 coil inductances, calculate middle layer toroid winding 2 its corresponding inner diameter d in the time that the number of plies is 12,13,14,15 and 16 layers
21be respectively 45.84mm, 40.7mm, 36.4mm, 32.73mm and 29.54mm, the inner diameter d of middle layer toroid winding 2
21must be greater than the outside diameter d of coil 1
1231.6mm, and to get the minimum value that is greater than 31.6mm be 32.73mm, now the coil number of plies is 15; The parameter of middle layer toroid winding 2 is: inner diameter d
21for 32.73mm, outside diameter d
22for 41.43mm, mean diameter d
2for 37.08mm, number of turn N is 450; According to identical method, calculate outermost layer toroid winding 3 its corresponding inner diameter d in the time that the number of plies is 10,11,12 and 13 layers
31be respectively 59.85mm, 52.08mm, 45.8mm and 40.7mm, the inner diameter d of outermost layer toroid winding 3
31must be greater than the outside diameter d of middle layer toroid winding 2
2241.43mm, and to get the minimum value that is greater than 41.43mm be 45.8mm, now the coil number of plies is 12.The parameter of outermost layer toroid winding 3 is: inner diameter d
31for 45.8mm, outside diameter d
32for 52.76m, mean diameter d
3for 49.28mm, number of turn N is 360.
When experiment, each toroid winding connects a BNC connector, and BNC connector is connected with three separate data acquisition channels of outside, and in the time of plane that vicissitudinous magnetic field is defined by coil, toroid winding can produce induction electromotive force.The electromotive force collecting is carried out to integration and can obtain the average magnetic induction intensity through toroid winding defining surface, the magnetic induction density value using it as hub of a spool place.In the time that one of them toroid winding has induction current, can produce magnetic field, because three toroid windings are mutually vertical, the magnetic field that this coil produces can not have influence on other measurement of two toroid windings to magnetic field of the goal.The magnetic field intensity of spherical shaped framework coil central point can be expressed as (B1, B2, B3).
In sum, these are only preferred embodiment of the present utility model, be not intended to limit protection domain of the present utility model.All within spirit of the present utility model and principle, any amendment of doing, be equal to replacement, improvement etc., within all should being included in protection domain of the present utility model.
Claims (4)
1. a hypervelocity impact magnetic field Three-Dimensional Magnetic induction measuring coil, is characterized in that, comprising: spherical skeleton and three toroid windings; Wherein, the profile of spherical skeleton is spheroidal, and the surface of spherical skeleton radially processes the three mutually perpendicular ring grooves in road, and the degree of depth of three road ring grooves is successively decreased successively; Three toroid winding correspondences are wound in three road ring grooves and are independent mutually, and each coil connects a BNC connector, and BNC connector is connected with three separate data acquisition channels of outside.
2. high velocity impact as claimed in claim 1 magnetic field Three-Dimensional Magnetic induction measuring coil, is characterized in that, described three toroidal cross sections are rectangle.
3. high velocity impact as claimed in claim 1 or 2 magnetic field Three-Dimensional Magnetic induction measuring coil, is characterized in that, described innermost layer toroid winding copper enameled wire diameter D is 0.29mm, and coil section axial length a is 10mm, internal coil diameter d
11for 20mm, mean diameter d
1for 25.8mm, coil outer diameter d
12for 31.6mm, the number of turn N of coil is 600, and the canoe of coil is every layer of 30 circle, totally 20 layers;
Middle layer toroid winding copper enameled wire diameter D is 0.29mm, and coil section axial length a is 10mm, the inner diameter d of coil
21for 32.73mm, outside diameter d
22for 41.43mm, mean diameter d
2for 37.08mm, the number of turn N of coil is 450, and the canoe of coil is every layer of 30 circle, totally 15 layers;
Outermost layer toroid winding copper enameled wire diameter D is 0.29mm, and coil section axial length a is 10mm, the inner diameter d of coil
31for 45.8mm, outside diameter d
32for 52.76m, mean diameter d
3for 49.28mm, the number of turn N of coil is 360, and the canoe of coil is every layer of 30 circle, totally 12 layers.
4. high velocity impact as claimed in claim 3 magnetic field Three-Dimensional Magnetic induction measuring coil, is characterized in that, described three toroidal outsides are wound around respectively the aluminium foil layer that thickness is 2mm, and to this aluminium foil layer ground connection.
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN103760502A (en) * | 2014-01-29 | 2014-04-30 | 北京理工大学 | Three-dimensional magnetic induction intensity measurement coil for ultra-high-speed collision magnetic field |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN103760502A (en) * | 2014-01-29 | 2014-04-30 | 北京理工大学 | Three-dimensional magnetic induction intensity measurement coil for ultra-high-speed collision magnetic field |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20140806 Termination date: 20190129 |
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CF01 | Termination of patent right due to non-payment of annual fee |