CN108286932A - A kind of high-precision two-part differential transformer displacement sensor - Google Patents

Abstract

The invention discloses a kind of high-precision two-part differential transformer displacement sensors, including iron core, skeleton, the primary coil being wound on skeleton, rectangle secondary coil and shell, secondary coil is divided into triangular secondary coil I and triangular secondary coil II by the diagonal line of rectangle secondary coil, and triangle step cross winding is respectively adopted and carries out coiling to get coil finished product；The present invention analyzes and researches its architectural characteristic, and the precision of both ends formula differential transformer displacement sensor is made to improve, and stroke increases, while compact-sized, can be satisfied with the demand of the industries such as equipment manufacturing, military equipment, petroleum machinery.

Description

A kind of high-precision two-part differential transformer displacement sensor

【Technical field】

The invention belongs to displacement sensors and precise electronic component field, and in particular to a kind of high-precision two-part is differential Transformer displacement sensor.

【Background technology】

Differential transformer linear movement pick-up has the characteristics that long lifespan, precision are high, mechanical strength is good, thermal drift is low, extensively The general measurement for being applied to carry out straight-line displacement in the servoactuation systems of industries such as equipment making, military equipment, petroleum machinery.It is right For differential displacement sensor, structure size, linear measurement range are the key factors of type selecting.Because of the demand of miniaturization, Displacement sensor compact-sized, that precision is high and stroke is big is increasingly favored.If want in certain structure size obtain compared with Big linear measurement range, key are the design of coil.According to the difference of LVDT sensor enamel wire coil winding methods, position Displacement sensor can be divided into three kinds of two-part, three-stage and multisection type structures.Wherein three-stage displacement sensor linear measurement range It is smaller, about the 10%~25% of measuring staff, but because its symmetry and winding method are simple, be usually used in small-range than displacement survey Amount；Two-part displacement sensor, structural representation are as shown in Figure 1.Primary coil is wrapped over entire backbone length, therefore intermediate position production Raw even variation length of magnetic field increases, and two secondary coil coiling lengths also increase, and account for the 1/2 of backbone winding linear window length, Therefore secondary coil linear response range also increases, but the linearity is poor, substantially in 10%FS.

【Invention content】

The object of the present invention is to provide a kind of high-precision two-part differential transformer displacement sensors, improve displacement sensing The precision of device, increases stroke, improves the linearity.

The present invention uses following technical scheme：A kind of high-precision two-part differential transformer displacement sensor, including iron core, Skeleton, the primary coil being wound on skeleton, rectangle secondary coil and shell, the winding method of rectangle secondary coil are specially：

Secondary coil is divided into triangular secondary coil I and triangular secondary line by the diagonal line of rectangle secondary coil Circle II is that initiating terminal respectively will be secondary along the long side direction of triangular secondary coil I and triangular secondary coil II, using broadside respectively It is q sections that grade coil I and secondary coil II, which divide, and q is the integer not equal to 0；

Using displacement sensor central point as coordinate origin, the outwardly directed direction of iron core is the directions+x, and iron core withdraws direction For the directions-x；

By preceding q/2 sections of secondary coil I, from the directions+x, sequentially coiling cuts enamel-cover wire tag fore and aft line to coordinate origin Head；

By preceding q/2 sections of secondary coil II, from the directions-x, sequentially coiling is to coordinate origin, and by the rear q/2 of secondary coil II From the directions+x, sequentially coiling cuts enamel-cover wire tag fore and aft line head to section to coordinate origin；

By rear q/2 sections of secondary coil I, from the directions-x, sequentially coiling cuts enamel-cover wire tag fore and aft line to coordinate origin Head；By preceding q/2 sections of the buttock line head short circuit of rear q/2 sections first the end of a thread of secondary coil I and secondary coil I to get around making Rectangle secondary coil.

Further, the total number of turns of secondary coil I and each section the number of turns meet the following conditions：

Pass through formulaThe total number of turns for going out to wait for coiling secondary coil I, pass throughIt is calculated and waits for each section in coiling secondary coil I the number of turns, In, Q is the number of turns of secondary coil I in every square millimeter, and S is the displacement distance of iron core；N is the length of primary coil after coiling Half.

Further, the total number of turns of secondary coil II and each section the number of turns meet the following conditions：

Pass through formulaThe total number of turns for waiting for coiling secondary coil II is calculated, is passed throughIt is calculated and waits for each section in coiling secondary coil II the number of turns W_22-k, wherein Q is the number of turns of secondary coil II in every square millimeter, and S is the displacement distance of iron core.

Further, the number of turns of primary coil meets condition：

According to displacement sensor to be made, magnetic flux path cdef is established, wherein c, d, e, f are respectively displacement sensor measurement range Interior arbitrary different point, secondary coil center line wherein pass through formula

Obtain the number of turns N of primary coil in magnetic flux path cdef₁, wherein μ₀Indicate the magnetic conductivity in air, B_y1For in cd The total magnetic flux density of section, B_y3For in ef sections of total magnetic flux densities, I is the electric current in primary coil, l_yFor cd sections to ef sections of position Set variable quantity；

Due to N₁=W₁L/2n then has formulaAnd primary coil total number of turns W is calculated₁, Wherein, B_mFor iron core endpoint magnetic flux density, 2n is the length of primary coil after coiling, and 2l is core length, r₁It is outside iron core half Diameter, R are magnetic conductive shell inside radius.

The beneficial effects of the invention are as follows：The design that the present invention passes through two-part differential transformer displacement sensor of analyzing and researching Principle and its architectural characteristic derive the transformational relation of displacement and voltage, make original differential transformation of both ends formula by the design The precision of device displacement sensor improves, and stroke increases, while compact-sized, improves the anti-vibration, impact, acceleration of sensor Ability, the demand of the industries such as equipment manufacturing, military equipment, petroleum machinery can be satisfied with.

【Description of the drawings】

Fig. 1 is the structural schematic diagram of two-part differential transformer displacement sensor in the prior art；

Fig. 2 is the equivalent circuit diagram of two-part differential transformer displacement sensor of the present invention；

Fig. 3 is the magnetic flux density schematic diagram of two-part differential transformer displacement sensor of the present invention；

Fig. 4 is the magnetic flux path schematic diagram of two-part differential transformer displacement sensor of the present invention；

Fig. 5 is the coiling schematic diagram of two-part differential transformer displacement sensor of the present invention；

Fig. 6 is the secondary coil coiling schematic diagram of two-part differential transformer displacement sensor of the present invention.

【Specific implementation mode】

The following describes the present invention in detail with reference to the accompanying drawings and specific embodiments.

The invention discloses a kind of high-precision two-part differential transformer displacement sensors, including iron core, skeleton, primary line Enclose P, secondary coil I, secondary coil II and shell, secondary coil I and the series connection of II direction of secondary coil, stroke differential output.

According to displacement sensor parameter to be made, core length 2l, the iron core outer radius r of displacement sensor are determined₁, outside magnetic conduction Shell inside radius R.

According to displacement sensor to be made, as shown in Figure 2 and Figure 3, the magnetism of high magnetic permeability is utilized in the outside of cell winding A magnetic shielding cover is made in material, and the iron core of intermediary movements is made of high-permeability material.Effect of end surface is omitted, flux path is established Diameter cdef, wherein c, d, e, f are respectively arbitrary different point in displacement sensor measurement range, and secondary coil is Triangle-Profile, Magnetic flux density in the product of iron core circular section at any point yWherein, B_mFor iron core endpoint flux density, r indicates iron core any point To the vertical range of co-ordinate zero point (being the central point of displacement sensor).By circuital law, (Maxwell is by Ampere ring road Theorem is extended to circuital law, is one of maxwell equation group fundamental equation of electromagnetic field integrated form.It is max It is assumed that its correctness is consistent by all obtained conclusions of maxwell equation group with experimental fact is tested made by Wei Card.Its content is：Total magnetic pressure on any one closed loop be equal to passed through in face that this closed circuit is surrounded it is complete The algebraical sum of portion's electric current)：

Then have：

Wherein, H_y1For dc sections of magnetic induction, H_y2For ed sections of magnetic induction, H_y3For ef sections of magnetic induction, H_y4For cf The magnetic induction of section；I is the electric current in primary coil, N₁For the number of turns of primary coil in magnetic flux path cdef, due to flux path Cd, ef sections are among magnetic material in diameter, and the magnetic resistance of permeability magnetic material is negligible, obtains：

Formula is obtained after reduction

Wherein, μ₀Indicate the magnetic conductivity in air, B_y1For in cd sections of total magnetic flux densities, B_y3It is close in ed sections of total magnetic fluxs Degree, l_yFor cd sections to ef sections of location variation, R is magnetic conductive shell inside radius.

If B_l1For magnetic induction of the magnetic flux path on cd sections of upper core surfaces, B_l3It is magnetic flux path in ef sections of upper cores Magnetic induction on surface, thenB_y1It indicates in cd sections of total magnetic flux densities, B_y3It indicates In ef sections of total magnetic flux densities, rc indicates core center position to any distance on side, y₁Indicate cd segment distances, y₂Indicate ed sections Distance, y₃Indicate ef segment distances, y₄Indicate cf segment distances, y₁=y₃, y₂=y₄, ef sections of distances for arriving reference axis y of l3 expressions, l1 tables Show the cd sections of distances for arriving reference axis y, then can obtain：

As shown in figure 4, for the magnetic circuit that distance is l, B_l1=B_m, B_l2=0, B_l2For magnetic flux path in cd sections iron Magnetic induction on wicking surface, B_mFor iron core endpoint magnetic flux density, haveDue to N₁=W₁L/2n, It obtains

According to formulaPrimary coil total number of turns W is calculated₁, wherein 2n is primary coil Length.

As shown in figure 5, to make secondary coil perceive the magnetic field of a constant homogeneous, in secondary framework baffle effective distance High temperature enameled wire, layering coiling total number of turns W are chosen in (2n)₁Primary coil and cement, do not allow superimposing thread, ensure primary coil Surrounding generates a uniform magnetic field.

As primary coil selects the high temperature enameled wire of φ 0.12, four layers of coiling, every layer of 550 circle to use golden finger after coiling is complete Adhesive tape is cemented, and prevents from loosening in follow-up winding process.

Secondary coil is divided into secondary coil I and secondary coil II, and selects high temperature enameled wire respectively, using triangle Step cross winding carries out coiling (can increase linear and range), is potted successively after coiling, dipping lacquer obtains two sections of high-precision Formula differential transformer displacement sensor.

Triangle step cross winding is specially：

Triangular secondary coil I is divided by secondary coil to straight line where angular vertex by two of rectangle secondary coil With triangular secondary coil II.It is along the long side direction of triangular secondary coil I and triangular secondary coil II, with broadside respectively It is q sections that initiating terminal, which respectively divides secondary coil I and secondary coil II, and q is the integer not equal to 0.

Pass through formulaThe total number of turns for waiting for coiling secondary coil I is calculated, is passed throughThe number of turns W for waiting for each section of coiling secondary coil I is calculated_21-k, I.e.：First segment waits for that the number of turns of coiling secondary coil I isSecond segment waits for coiling secondary wire Circle I the number of turns beAnd so on, the q sections of circles for waiting for coiling secondary coil I are obtained respectively Number.Wherein, Q is the number of turns of secondary coil I in every square millimeter, and S is the displacement distance of iron core.

Pass through formulaThe total number of turns for waiting for coiling secondary coil II is calculated, is passed throughThe number of turns W for waiting for II each section of coiling secondary coil is calculated_22-k, Wherein, Q is the number of turns of secondary coil II in every square millimeter.

Equivalent magnetic flux linkage chain number for the directions-x of secondary coil I is：

Wherein, b indicates that the triangle base of secondary coil, χ indicate the distance in the directions-x of secondary coil I.

Equivalent magnetic flux linkage chain number for the directions-x of secondary coil II is：

II equivalent magnetic flux linkage chain number of secondary coil is：

Acquiring the mutual inductance potential virtual value that secondary coil I is generated is：

Wherein, ω indicates the electrical angle of key player on a team's wave, M₂₁Indicate that the mutual inductance of primary coil and secondary coil, f indicate to swash Encourage the frequency of power supply, κ₁A constant is represented,

Similarly, it can obtainκ₂Represent a constant, κ₁=κ₂.Then have, U₀=U₂₁-U₂₂=2 κ S, it can be seen that the output voltage U of two-part differential transformer sensor₀Displacement S with iron core is in line Sexual intercourse, its error can be reduced and obtain preferably in it is transmitted and is controlled by so that sensor is obtained higher precision in this way Using.

Using displacement sensor central point as coordinate origin, the outwardly directed direction of iron core is the directions+x, and iron core withdraws direction For the directions-x.

Although greatly increasing the range of linearity with triangle winding, using enameled wire coiling secondary coil, some are tired really Difficulty intersects coiling to make this winding method that there is engineering, secondary coil winding method can further refine using ladder, This winding reduces the coiling number of plies, is as follows：

By preceding q/2 sections in secondary coil I, from the directions+x, sequentially coiling cuts enameled wire and marks head and the tail to coordinate origin The end of a thread.

By preceding q/2 sections in q sections of secondary coils II, from the directions-x, sequentially coiling, and will be in secondary coil II to coordinate origin Sequentially coiling cuts enamel-cover wire tag fore and aft line head to coordinate origin in the rear q/2 sections of directions+x.

By rear q/2 sections in secondary coil I, from the directions-x, sequentially coiling cuts enamel-cover wire tag fore and aft line to coordinate origin Head；Rear q/2 sections first the end of a thread in secondary coil I is obtained into coiling with preceding q/2 sections of buttock line head short circuit in secondary coil I Good rectangle secondary coil.

As shown in fig. 6, secondary coil I is divided into 20 sections, the directions+x and each 10 sections of the directions-x, per segment length 5.6mm；It selects The high temperature enameled wire of φ 0.07, presses that arrow 1 is flat around two layers, and every layer is 225 from the center of primary coil to the directions+x of sensor Circle is cemented with golden finger adhesive tape, prevents from loosening in follow-up winding process.Continue the secondary wire that coiling remains in the directions+x Circle, it is flat around one layer by arrow 2,3,4, every section be respectively 6.5 circles, 14.5 circles, 22.5 circles, 30.5 circles, 38.5 circles, 51.5 circles, 59.5 circles, 67.5 circles, 75.5 circles, 83.5 circles；Enameled wire is cut herein, and head and the tail the end of a thread of coil has been marked after complete.

The high temperature enameled wire coiling secondary coil II for selecting φ 0.07, from the center of primary coil to the sides-x of sensor To flat around two layers by arrow 8, every layer is 225 circles, is cemented with golden finger adhesive tape, prevents from loosening in follow-up winding process； Do not have to cut short enameled wire herein, continues the secondary coil that coiling remains in the directions-x, it is flat around one layer, every section by arrow 9,10,11 Respectively 6.5 circles, 14.5 circles, 22.5 circles, 30.5 circles, 38.5 circles, 51.5 circles, 59.5 circles, 67.5 circles, 75.5 circles, 83.5 circles；With Golden finger adhesive tape is cemented, and prevents from loosening in follow-up winding process.Do not have to cut short enameled wire herein, continues coiling and remain in The secondary coil in the directions+x, it is flat around one layer by arrow 12,13,14, every section of 83.5 circle of difference, 75.5 circles, 67.5 circles, 59.5 circles, 51.5 circles, 38.5 circles, 30.5 circles, 22.5 circles, 14.5 circles, 6.5 circles, golden finger adhesive tape are cemented, and are prevented in follow-up coiling It is loosened in journey, cuts enameled wire after coiling is complete, marked the buttock line head of coil.

Continue coiling secondary coil I, continues the secondary coil that coiling remains in the directions-x, it is flat around one layer by arrow 5,6,7, Every section of 83.5 circle of difference, 75.5 circles, 67.5 circles, 59.5 circles, 51.5 circles, 38.5 circles, 30.5 circles, 22.5 circles, 14.5 circles, 6.5 circles, Head and the tail the end of a thread that coil has been marked after complete, is cemented with golden finger adhesive tape, prevents from loosening in follow-up winding process, arrow The buttock line short circuit of 5 first lines and arrow 4.

It will be successively potted around the displacement sensor for making coil, dipping lacquer obtains high-precision two-part differential transformer position Displacement sensor.

Disclosure sets forth the evolution process of two secondary coils, and the distributed architecture of triangle is changed to by distributed rectangular structure, Bucking coil is increased, which has the characteristics that wide range than high-precision, but two secondary coils hold in winding process Easily broken string or interlayer collapse so that reliability reduce；It after ladder cross winding, solves the problems, such as that gap caves in, improves The engineering productivity of product, reduces total null voltage, enhances the consistency, stability, reliability of sensor.

Claims (4)

1. a kind of high-precision two-part differential transformer displacement sensor, which is characterized in that including iron core, skeleton, be wound on bone Primary coil, rectangle secondary coil on frame and shell, the winding method of the rectangle secondary coil are specially：

Secondary coil is divided into triangular secondary coil I and triangular secondary line by the diagonal line of the rectangle secondary coil Circle II is that initiating terminal respectively will be secondary along the long side direction of triangular secondary coil I and triangular secondary coil II, using broadside respectively It is q sections that grade coil I and secondary coil II, which divide, and q is the integer not equal to 0；

Using displacement sensor central point as coordinate origin, the outwardly directed direction of iron core is the directions+x, and it is-x that iron core, which withdraws direction, Direction；

By preceding q/2 sections of secondary coil I, from the directions+x, sequentially coiling cuts enamel-cover wire tag fore and aft line head to coordinate origin；

By preceding q/2 sections of secondary coil II from the directions-x sequentially coiling to coordinate origin, and by rear q/2 sections of secondary coil II from Sequentially coiling cuts enamel-cover wire tag fore and aft line head to coordinate origin in the directions+x；

By rear q/2 sections of secondary coil I, from the directions-x, sequentially coiling cuts enamel-cover wire tag fore and aft line head to coordinate origin；It will Rear q/2 sections first the end of a thread of secondary coil I is with preceding q/2 sections of the buttock line head short circuit of secondary coil I to get around the rectangle made Grade coil.

2. a kind of high-precision two-part differential transformer displacement sensor according to claim 1, which is characterized in that described The total number of turns of secondary coil I and each section the number of turns meet the following conditions：

Pass through formulaThe total number of turns for going out to wait for coiling secondary coil I, pass throughIt is calculated and waits for each section in coiling secondary coil I the number of turns, In, Q is the number of turns of secondary coil I in every square millimeter, and S is the displacement distance of iron core；N is the length of primary coil after coiling Half.

3. a kind of high-precision two-part differential transformer displacement sensor according to claim 1 or 2, which is characterized in that The total number of turns of the secondary coil II and each section the number of turns meet the following conditions：

Pass through formulaThe total number of turns for waiting for coiling secondary coil II is calculated, is passed throughIt is calculated and waits for each section in coiling secondary coil II the number of turns W_22-k, wherein Q is the number of turns of secondary coil II in every square millimeter, and S is the displacement distance of iron core.

4. a kind of high-precision two-part differential transformer displacement sensor according to claim 3, which is characterized in that described The number of turns of primary coil meets condition：

According to displacement sensor to be made, magnetic flux path cdef is established, wherein c, d, e, f are respectively to appoint in displacement sensor measurement range It anticipates different points, secondary coil center line wherein passes through formula

Obtain the number of turns N of primary coil in magnetic flux path cdef₁, wherein μ₀Indicate the magnetic conductivity in air, B_y1It is total at cd sections Magnetic flux density, B_y3For in ef sections of total magnetic flux densities, I is the electric current in primary coil, l_yBecome for cd sections to ef sections of positions Change amount；

Due to N₁=W₁L/2n then has formulaAnd primary coil total number of turns W is calculated₁, In, B_mFor iron core endpoint magnetic flux density, 2n is the length of primary coil after coiling, and 2l is core length, r₁For iron core outer radius, R For magnetic conductive shell inside radius.