JP4204303B2 - Magnetic impedance sensor chip and magnetic sensor element using the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention is a magnetic sensor element for detecting magnetism with high sensitivity and high accuracy, which is suitable mainly for use in home appliances, information terminals, industrial equipment, and the like, and in particular, a magnetic impedance sensor chip utilizing impedance change. And a magnetic sensor element using the same.
[0002]
[Prior art]
  A conventional magnetic sensor element using a magnetic impedance sensor chip utilizing impedance change will be described. Here, the magneto-impedance effect is the following phenomenon. A high frequency voltage is applied to both ends of a soft magnetic material having an easy magnetization axis in the width direction of the elongated magnetic material as shown in FIG. 19, and the high frequency current flowing in the magnetic material generates a magnetic field in the width direction of the magnetic material. Due to the magnetic permeability in the width direction of the soft magnetic material, the higher the magnetic permeability, the higher the self-inductance of the high-frequency current increases toward the center of the magnetic material, so that the current flows only near the surface. The skin depth δ of the high-frequency current distribution is given by the following formula (1), where resistivity is ρ, frequency is f, and magnetic permeability in the magnetic body width direction is μ.
[0003]
δ = [2πρ / (f · μ)] 1/2 (1)
[0004]
  At a depth t from the surface of the magnetic material, impedance Z is given by the following equation (2), where DC resistance is R.
[0005]
Z = R · exp (t / δ) (2)
[0006]
  The magnetic permeability μ in the width direction of the magnetic body is low. The reason is that, as shown in FIG. 20, magnetization is directed in the width direction of the magnetic body in the absence of a magnetic field, and magnetization reversal due to domain wall movement hardly occurs at a high frequency of the MHz band or higher.
[0007]
  When a slightly larger magnetic field than the magnetic anisotropy is applied in the longitudinal direction of the magnetic material, as shown in FIG. 21, the magnetization is slightly directed in the longitudinal direction of the magnetic material, and the magnetization of the high-frequency current is generated in the magnetic field. It becomes possible to follow by vibration, and the magnetic permeability becomes high in the magnetic body width direction even at a high frequency of the MHz band or higher.
[0008]
  When a stronger magnetic field is applied in the longitudinal direction of the magnetic material, the magnetization becomes constrained in the longitudinal direction of the magnetic material, as shown in FIG. As a result, the magnetic permeability in the width direction of the magnetic material decreases.
[0009]
  As described above, since the magnetic permeability μ in the width direction of the magnetic material changes depending on the magnetic field applied in the longitudinal direction of the magnetic material, it is a magnetic impedance sensor chip that can be detected as an impedance change through the skin effect.
[0010]
  The high frequency that can be realized by a general-purpose circuit is about several tens of MHz. The magnetic permeability of the soft magnetic material is about several thousand. From there, the magnetoimpedance effect comes out from the formula (1) with a thickness of 1 micron or more. Further, the current that can be generated in the general-purpose circuit is about several mA, and the voltage amplitude needs several V. For this reason, an impedance of 100Ω or more is necessary for the magnetic impedance sensor chip.
[0011]
  On the other hand, when making a magnetic material of several microns as a pattern, a method of forming a film on a dielectric substrate such as glass with a sputtering apparatus is suitable for the magnetic material, and patterning is performed in units of microns by etching or lift-off with a photoresist. Can be produced. When the width of the magnetic material is several tens of microns or less, the characteristics are likely to be unstable due to the influence of the pattern edge. Therefore, since the impedance is required to be 100Ω or more, the length of the magnetic material is required to be 5 mm or more.
[0012]
  If the length of the magnetic material is 5 mm, it is too large as a magnetic sensor element, so that the chip is miniaturized by making the pattern folded several times, and the impedance is also predetermined. When the pattern interval of the folded pattern is 10 microns or less, the demagnetizing field increases because the adjacent magnetic patterns are too close to each other. If the pattern interval exceeds 100 microns, the advantage of miniaturization by the folded structure cannot be obtained.
[0013]
  In the folded pattern, when the folded portion is continuous with the magnetic material pattern, the magnetic flux is disturbed in the folded portion. A configuration in which a folded portion is connected by a nonmagnetic conductor film without using a magnetic material is disclosed in Japanese Patent Application Laid-Open No. 2000-206217 by the same applicant.
[0014]
  FIG. 29 is an explanatory diagram of a manufacturing method in which the folded portion of the magnetic body pattern is joined by a conductor film of a nonmagnetic piece of 1 μm or less. FIG. 30 is an explanatory view of the folded portion of the magnetic pattern connected by the conductor film of nonmagnetic pieces of 1 μm or less.
[0015]
  A structure in which the magnetic core is configured only by a zigzag-shaped magnetic material without using a nonmagnetic piece is also possible, but when an external magnetic field is applied from a direction inclined with respect to the direction in which the zigzag side extends, In the magnetic piece 141, the magnetic flux is bent by the bent portion of the spell, and a uniform magnetic field is not applied to the entire magnetic piece 141. Therefore, it is preferable that the bent portion of the magnetic piece 141 is formed by the nonmagnetic piece 142.
[0016]
  FIG. 23 is a characteristic diagram of impedance versus external magnetic field of the magnetic impedance sensor chip. Since the impedance of the magnetic impedance sensor chip changes due to the change in permeability in the width direction, the magnetic impedance sensor chip has a positive / negative symmetrical characteristic as shown in FIG. In order to detect a weak magnetic field, a constant magnetic field is applied to the point where the impedance changes, and when the magnetic field to be measured is applied, the impedance changes even if it is very small.
[0017]
  In order to obtain a constant magnetic field, there is a method of supplying a current to the coil or using a magnet, but it is preferable to supply a constant current to the coil in order to stabilize the impedance with zero measurement magnetic field. In the configuration disclosed in Japanese Patent Laid-Open No. 2000-206217 by the same applicant, a spiral conductive thin film pattern is formed via an insulating layer.
[0018]
  FIG. 24 is an example of a magnetic sensor element having a uniaxial magnetic detection direction. The magnetic impedance chip 20 has a magnetic core 22 having a folded structure on a dielectric substrate such as glass, and electrode pads 42 on both poles of the magnetic core 22, and is electrically connected to the electrode 41 on the printed circuit board 11 side by soldering. Connect to. Furthermore, a constant magnetic field can be applied by winding. FIG. 25 shows the relationship between the number of turns at a current of 10 mA and the magnetic bias.
[0019]
  Further, when the number of detection axes is increased to two or three axes, a method of arranging the uniaxial sensor in two directions for two axes is used. FIG. 26 is a diagram illustrating an example of a magneto-impedance sensor chip provided with a magnetic pattern inclined at 35 degrees with respect to the printed circuit board surface. FIG. 27 is a diagram showing an example of a magnetic sensor element formed by attaching the magnetic impedance sensor chip of FIG. 26 to a triangular prism.
[0020]
  In the case of three axes, since it is necessary to stand the magnetic sensor element in a direction perpendicular to the printed circuit board, there is a problem that it is taller than other mounted components. Therefore, as shown in FIG. As shown in FIG. 27, a magneto-impedance chip with a diagonal magnetic body pattern 21a is attached to a triangular prism, connected to a printed circuit board by a conductive adhesive, and covered with a wound round bobbin. The magnetic bias is applied in the vertical direction. FIG. 28 is a characteristic diagram of the number of turns and the magnetic bias at a current of 10 mA on the bobbin of the coil of the magnetic sensor element of FIG. The bobbin had an inner diameter of 6.5 mm, an outer diameter of 7.5 mm, and a height of 4 mm.
[0021]
[Problems to be solved by the invention]
  In the conventional magnetic sensor element, there is an interval of several mm between the winding and the magnetic sensor element, and the influence of the leakage magnetic field cannot be ignored. FIG. 17 is a characteristic diagram of application of a magnetic field from a thin film coil. When the bias coil is formed of a thin film, the magnetic field generated by the coil is applied through an insulating film of several microns, so that the interval is too small and a non-uniform magnetic field is applied as shown in FIG. For this reason, since the thickness of the winding is several tens of μm and the thin film winding pattern is several tens of μm, the coils need to be wound at intervals of about several tens to several hundreds of μm.
[0022]
  In a magnetic sensor element having a single detection axis, a magneto-impedance sensor chip is erected, and there is a space between the element and the coil, and the distance from the winding coil is also different in each part of the magnetic pattern. It is uniform. Further, in the case of a magnetic sensor having a three-axis detection axis, the bobbin has a round shape, and there is a non-uniform spacing of several millimeters between the magnetic impedance sensor chip attached to the triangular prism and this is not possible. A uniform magnetic field is applied.
[0023]
  Further, the magnetic sensor element having three detection axes has a large shape because the magnetic pattern is oblique. Further, the magnetic film needs to have a thickness of several microns. For the conductor film, a thickness of about several thousand mm is sufficient from the resistivity. However, in order to avoid disconnection, the film thickness needs to be close to the thickness of the magnetic film.
[0024]
  The magnetic material pattern is formed by ion etching, chemical etching, or lift-off. FIG. 4 is a cross-sectional view of a magnetic pattern of a conventional magnetic impedance sensor chip. In the etching method, the remaining pattern portion is protected with a resist, and the remaining magnetic film is eroded. Therefore, the cross section of the magnetic film is a vertical cross section as shown in FIG. Become.
[0025]
  In the lift-off process, the magnetic film is formed by covering portions other than the remaining pattern with a resist pattern. In this case, in order to increase the pattern accuracy, conditions such as evaporation and sputtering are set so that the evaporated magnetic particles are attached perpendicularly to the substrate surface, so that the cross-sectional shape is close to the shape of FIG.
[0026]
  FIG. 30 is an explanatory diagram of the folded portion of the magnetic pattern connected by the conductor film of nonmagnetic pieces of 1 μm or less. The magnetic film inevitably needs a film thickness of several μm in order to exhibit MI characteristics, and the cross section of the magnetic material pattern is almost vertical at the folded portion of the magnetic material pattern connected by the conductor film of 1 μm or less shown in FIG. A disconnection failure occurred due to the fact that
[0027]
  Accordingly, an object of the present invention is to provide an inexpensive magnetic impedance sensor chip in which a magnetic material pattern and a conductor pattern are stably connected and highly reliable, and a magnetic sensor element using the magnetic impedance sensor chip.
[0028]
[Means for Solving the Problems]
  In response to the above-described problems, according to the present invention, magnetic detection is performed by utilizing the fact that the magnetic domain structure and the magnetization distribution affect the magnetic permeability of the magnetic thin film by applying an external magnetic field to the magnetic thin film pattern, thereby changing the impedance. In a magnetic sensor element to be performed, a plurality of elongated rectangular magnetic substance patterns are arranged, end portions are connected by a non-magnetic conductor pattern, and the magnetic substance patterns are connected in series by the conductor pattern. The pattern and the pattern in which the non-magnetic wiring extends from the terminal end of the last magnetic pattern to the electrode are covered with an insulating film except for the electrode portion formed on the flat dielectric substrate. The cross-sectional shape is solved by being a substantially trapezoidal shape in which the longer of two parallel sides is arranged on the substrate side.
[0029]
  With this configuration, since the cross section of the magnetic pattern is trapezoidal, disconnection is less likely to occur at the portion where the magnetic pattern is connected by the conductor film.
[0030]
  According to the present invention, in the magneto-impedance sensor chip, the longitudinal direction of the magnetic material pattern has an angle of about 35 degrees with the plane of the printed circuit board as the magnetic detection direction, and the regular triangular prism stands on the printed circuit board. A magnetic impedance sensor chip is fixed to each side of the pattern surface on the outside, and is connected to the printed circuit board electrode via a conductor, and a hexagonal winding frame with corners of each vertex of an equilateral triangle. This is solved by the fact that the apex of the triangular prism and the inside of the winding bobbin are close to each other.
[0031]
  Since the winding coil is closer to the pattern surface than in the prior art and the distance is constant, a uniform and highly efficient magnetic bias can be applied.
[0032]
  Further, according to the present invention, there is a leg portion having a height substantially the same as the electrode portion of the magnetic impedance at the lower part of the bobbin of the magnetic sensor element, and this is solved by exposing the magnetic impedance sensor chip electrode.
[0033]
  With this configuration, the height can be further reduced as compared with the conventional case. Further, according to the present invention, in the magnetic sensor element, the electrode of the magneto-impedance sensor chip is extended to the bottom facing the printed circuit board, and the bottom electrode and the printed circuit board electrode are connected by a conductor. is doing.
[0034]
  According to the present invention, in the magneto-impedance sensor chip, the pattern surface of the magneto-impedance sensor chip faces the printed circuit board, and two electrodes are formed on the printed circuit board at positions facing the electrodes of the magnetic impedance sensor chip. This is solved by connecting the electrodes to each other with a conductive material.
[0035]
  With this configuration, since the pattern surface faces the printed circuit board side, not only the pattern surface is protected, but also the magnetic impedance sensor chip substrate itself is protected, so that the thickness is thinner than the conventional one. In addition, according to the present invention, the problem can be solved by forming a spiral conductor pattern at a location facing the pattern portion of the magnetic impedance sensor chip on the printed circuit board of the magnetic sensor element.
[0036]
  Further, according to the present invention, in the magnetic sensor element, the problem can be solved by sandwiching the polyimide film on which the spiral conductor pattern is formed between the magnetic impedance sensor chip and the printed board.
[0037]
  In addition, according to the present invention, the problem can be solved by winding the conducting wire on the outside of the printed circuit board of the magnetic sensor element and the magnetic impedance sensor chip.
[0038]
  Further, according to the present invention, the magnetic sensor element includes the edge of the magnetic pattern.Dielectric substrateThis can be solved by arranging one electrode in the blank portion surrounded by the edge of the first electrode and forming the other electrode in the blank portion on the opposite side through the magnetic material pattern.
[0039]
  According to the present invention, in the magnetic sensor element, the DC resistance of the elongated substantially rectangular magnetic substance pattern is in the range of 5 to 50Ω, and the DC resistance of the conductor pattern portion is elongated and the DC resistance of the substantially rectangular magnetic substance pattern. It can be solved by being less than one-fifth.
[0040]
  Further, according to the present invention, in the magnetic sensor element, the problem can be solved by the interval between the substantially rectangular magnetic body patterns being 10 μm to 100 μm.
[0041]
  According to the present invention, in the magnetic sensor element, the composition of the magnetic film is Co70-85 atomic%, the remaining composition is Nb and Zr, and the atomic% X of Nb and the atomic% Y of Zr are: (X = 30, Y = 0), (X = 23, Y = 7), (X = 8, Y = 7), (X = 15, Y = 0) Preferably, it is solved by having a composition range of (X = 27, Y = 3), (X = 25, Y = 5), (X = 10, Y = 5), (X = 12, Y = 3) it can.
[0042]
DETAILED DESCRIPTION OF THE INVENTION
  A magnetic impedance sensor chip according to an embodiment of the present invention and a magnetic sensor element using the same will be described below.
[0043]
(Reference Example 1)
  FIG. 1 illustrates the present invention.Reference example 1It is explanatory drawing of the magnetic impedance sensor chip by. A plurality of elongated rectangular magnetic patterns 2 are arranged on a substrate 1 such as glass and are electrically connected in series by a conductor pattern 3. Here, both ends 3 a and 3 b of the magnetic substance-conductor series pattern are connected to the electrode 4, respectively.
[0044]
  Here, the magnetic material pattern 2 is induced with an easy axis by applying a magnetic field in the width direction and performing a heat treatment in an inert atmosphere. Electrode pads are formed on both ends 3a and 3b of the magnetic material-conductor series pattern, and the electrodes other than the electrode partial pads are covered with an insulating protective film such as resist, photosensitive polyimide resin, silicon oxide, glass, alumina, etc. Is preventing.
[0045]
  FIG. 2 illustrates the present invention.Reference example 1It is explanatory drawing of the composition of the magnetic film of the magnetic impedance sensor chip by. The composition of the magnetic film is Co 70-85 atomic%, the remaining composition is Nb and Zr, and the atomic% X of Nb and the atomic% Y of Zr are (X = 30, Y = 0) in FIG. , (X = 23, Y = 7), (X = 8, Y = 7), (X = 15, Y = 0), the magnetostriction is almost zero in this range. It becomes. Further, a composition range surrounded by (X = 27, Y = 3), (X = 25, Y = 5), (X = 10, Y = 5), (X = 12, Y = 3)And soft magnetic characteristics sexSince the coercive force is less than 10 mT, the magnetic impedance sensor chip has more suitable characteristics.
[0046]
  FIG. 3 illustrates the present invention.Reference example 1It is sectional drawing of the magnetic body pattern of the magnetic impedance sensor chip by. As shown in FIG. 3, a forward tapered shape is formed by using ion etching or a lift-off method when the magnetic pattern 2 is formed. Here, the forward taper shape refers to a trapezoidal shape and a substantially trapezoidal shape with a base on the substrate.
[0047]
  In order to obtain a forward taper shape, it is important that the resist thickness is at least twice the magnetic film thickness. In the lift-off method, when a magnetic film is formed on a thick resist pattern, the film thickness gradually becomes thinner at the bottom of the thick resist, resulting in a bottomed shape. In ion etching, a trapezoidal forward taper shape is obtained by injecting an ion beam obliquely into the resist on the magnetic film and etching. Although the conductor pattern 3 is also shown in the figure, since it has a forward taper shape, disconnection failure due to the pattern cut does not occur even if the conductor pattern 3 is thin.
[0048]
  FIG. 4 is a cross-sectional view of a magnetic pattern of a conventional magnetic impedance sensor chip. Conventionally, for example, in the cross section as shown in FIG. 4 formed by wet etching or the like, there is only a method for preventing the disconnection by increasing the thickness of the conductor pattern 31, and it takes time to form the film, resulting in an increase in cost. Further, when the insulating protective film is formed, the forward tapered cross-sectional shape requires a smaller film thickness of the insulating protective film necessary for protecting the entire pattern, thereby reducing the cost.
[0049]
  FIG. 18 is a diagram showing the relationship between the disconnection failure rate of the magnetic pattern and the region width of the forward tapered shape. Conventionally, the forward-tapered region is cut off at 0.5 μm or less, but in the present invention, the disconnection failure rate hardly occurs by setting it to 2 to 3 μm.
[0050]
(Reference Example 2)
  FIG. 5 illustrates the present invention.Reference example 2It is explanatory drawing of the magnetic sensor element by this. The magnetic sensor element of FIG. 5 forms a circuit with a winding coil 6 for magnetic bias on a magnetic impedance sensor chip.
[0051]
  6 is an AA cross-sectional view of the magnetic sensor portion of the magnetic sensor element of FIG. The pattern surface of the magnetic impedance sensor chip faces the printed circuit board surface, and the electrodes of the printed circuit board and the electrode pads of the magnetic impedance sensor chip are connected by a conductor such as soldering or a conductive adhesive. Since the printed circuit board electrode 8 is raised, the magnetic pattern of the magnetic impedance sensor chip is not pressed. In order to form the winding coil 6, it is only necessary to perform winding by using the protrusion of the end of the printed circuit board as a guide, and the winding only hits the back surface of the pattern of the magnetic impedance sensor chip and does not affect the characteristics.
[0052]
  The winding coil 6 is covered with a silicone resin to prevent disconnection. By setting the substrate of the magnetic impedance sensor chip to a thickness of 1/3 or less of the length in the longitudinal direction of the magnetic material pattern, that is, 20 to 900 μm, an appropriate gap is formed between the winding coil 6 and A uniform and highly efficient magnetic bias can be applied.
[0053]
(Reference Example 3)
  FIG. 7 illustrates the present invention.Reference example 3It is explanatory drawing of the magnetic sensor element by this. In the magnetic sensor element of FIG. 7, a magnetic bias winding and a circuit are formed on a magnetic impedance sensor chip.
[0054]
  8 is a cross-sectional view of BB of the magnetic sensor unit in the magnetic sensor element of FIG. The pattern surface of the magnetic impedance sensor chip faces the printed circuit board surface, and the printed circuit board electrode 8a and the electrode pad of the magnetic impedance sensor chip are connected by a conductor such as soldering or a conductive adhesive. Since the printed circuit board electrode is raised, the magnetic body pattern of the magnetic impedance sensor chip is not pressed.
[0055]
  The coil pattern is formed on the printed circuit board in a spiral shape, and is thinner than the winding. Inside the spiral pattern, as shown in FIG. 8, a lead-out line is formed on the back surface with a through hole, which is connected to a magnetic bias circuit. Similarly, the printed circuit board side electrode for the magneto-impedance sensor chip has a lead-out line by a through hole connected to the detection circuit on the back surface.
[0056]
(Embodiment 1)
  FIG. 9 illustrates the present invention.Embodiment 1It is explanatory drawing of the magnetic sensor element by this. The magnetic sensor element of FIG. 9 forms a magnetic bias winding and a circuit on a magnetic impedance sensor chip.
[0057]
  FIG. 10 is a cross-sectional view of CC of the magnetic sensor unit in the magnetic sensor element of FIG. The pattern surface of the magnetic impedance sensor chip faces the printed board surface, and the printed board electrode 8b and the electrode pad 7b of the magnetic impedance sensor chip are connected by a conductor such as soldering or a conductive adhesive. Since the printed circuit board electrode is raised, the magnetic body pattern of the magnetic impedance sensor chip is not pressed.
[0058]
  FIG. 11 is a view showing a polyimide resin film having a spiral conductor pattern used in the magnetic sensor element of FIG. A polyimide resin film 13 having the spiral conductor pattern shown in FIG. 11 is sandwiched and mounted between the printed circuit board and the magnetic impedance sensor chip. By forming the spiral coil pattern 6b on the polyimide resin film 13, a finer winding is possible than when the pattern is formed on the printed circuit board.
[0059]
(Reference Example 4)
  FIG. 12 illustrates the present invention.Reference example 4It is explanatory drawing of the magnetic sensor element by this. FIG. 13 is an explanatory diagram of the pattern of the magnetic impedance sensor chip of the magnetic sensor element of FIG. As shown in FIG. 13, five magnetic patterns 2b are arranged, and ends are connected by nonmagnetic conductor patterns 3b. The magnetic patterns 2b are connected in series by the conductor patterns 3b, and magnetic The longitudinal direction of the body pattern 2b has an angle of about 35 degrees with the printed circuit board plane as the magnetic detection direction.Reference example 1In the same way, the first magnetic pattern and the pattern in which the non-magnetic wiring extends from the end of the last magnetic pattern to the electrode is an insulating film except for the electrode portion formed on the flat dielectric substrate.CoatingHas been. The electrode is formed below the magnetic pattern.
[0060]
  By tilting the magnetic pattern diagonally, the height of the element can be reduced. At the same time, three magnetic impedance sensor chips are attached to the side surface of the regular triangular prism, so that the magnetic detection axes are orthogonal to each other. In addition, since the electrodes enter the gaps in the magnetic pattern, the chip can be miniaturized and the cost can be reduced.
[0061]
  In FIG. 12, the winding bobbin for applying a magnetic bias has an equilateral triangle in which the inner wall and the outer wall are rounded, and the inner wall and the outer wall are at a substantially constant distance on the surface of the magnetic impedance sensor chip attached to the equilateral triangular prism. Is closer to the apex of the regular triangular prism on which the magneto-impedance sensor chip is mounted, and closer to the top surface than the bottom of the bobbin. With such a configuration, the winding is closest to the surface of the magneto-impedance sensor chip at a certain distance, so that the magnetic bias efficiency is maximized, so that the current consumption is minimized and uniform magnetic bias is achieved. Sensitivity degradation due to bias non-uniformity does not occur.
[0062]
  In addition, there is a leg at the bottom of the winding bobbin, and the electrode portion of the magnetic impedance sensor chip is exposed, thereby avoiding swell when solder or conductive adhesive is used for bonding to the printed circuit board electrode. . FIG. 14 compares the magnetic bias efficiency and magnetic sensitivity of the conventional round bobbin and the triangular bobbin of the present invention. In the present invention, the magnetic bias efficiency is improved and the magnetic sensitivity is also improved.
[0063]
(Reference Example 5)
  FIG. 15 illustrates the present invention.Reference Example 5It is explanatory drawing of the magnetic sensor element by this. FIG. 16 is an explanatory diagram of the pattern of the magnetic impedance sensor chip of the magnetic sensor element of FIG. As shown in FIG. 16, five magnetic patterns 2c are arranged side by side, and the end portions are connected by a nonmagnetic conductor pattern 3c. The magnetic pattern 2c is connected in series by the conductor pattern 3c. The longitudinal direction of the body pattern 2c has an angle of about 35 degrees with the printed circuit board plane as the magnetic detection direction. AfterReference example 1In the same way as above, the first magnetic pattern and the pattern in which the nonmagnetic wiring extends from the terminal end of the last magnetic pattern to the electrode are covered with an insulating film except for the electrode portion formed on the flat dielectric substrate. Has been. In the electrode 4c, one electrode is disposed in a blank portion surrounded by the edge of the magnetic pattern and the dielectric substrate, and the other electrode is formed in the blank portion on the opposite side through the magnetic pattern.
[0064]
  By tilting the magnetic pattern diagonally, the height of the element can be reduced. At the same time, the three magnetic impedance sensor chips are attached to the sides of the regular triangular prism so that the magnetic detection axes are orthogonal to each other. In addition, detection can be performed, and further, the electrodes can be inserted into the gaps of the magnetic material pattern, so that the chip can be miniaturized and the cost can be reduced.
[0065]
  The winding bobbin for applying a magnetic bias has an equilateral triangle whose inner and outer walls are rounded, and the inner and outer walls are at a substantially constant distance on the surface of the magneto-impedance sensor chip attached to the equilateral triangular prism. It is close to the apex of the equilateral triangular prism to which the chip is attached, and closer to the top surface than the bottom of the bobbin. With such a configuration, the winding is closest to the surface of the magneto-impedance sensor chip at a certain distance, so that the magnetic bias efficiency is maximized, so that the current consumption is minimized and uniform magnetic bias is achieved. Sensitivity degradation due to bias non-uniformity does not occur.
[0066]
【The invention's effect】
  As described above, according to the present invention, an inexpensive magnetic impedance sensor chip in which a magnetic pattern and a conductor pattern are stably connected and highly reliable, and a magnetic sensor element using the magnetic impedance sensor chip can be provided.
[0067]
[Brief description of the drawings]
FIG. 1 of the present inventionReference example 1Explanatory drawing of the magnetic impedance sensor chip by.
FIG. 2 of the present inventionReference example 1Explanatory drawing of the composition of the magnetic body of the magnetic impedance sensor chip by FIG.
FIG. 3 of the present inventionReference example 1Sectional drawing of the magnetic body pattern of the magneto-impedance sensor chip | tip by a.
FIG. 4 is a cross-sectional view of a magnetic pattern of a conventional magnetic impedance sensor chip.
FIG. 5 shows the present invention.Reference example 2Explanatory drawing of the magnetic sensor element by this.
6 is an AA cross-sectional view of a magnetic sensor portion of the magnetic sensor element of FIG.
FIG. 7 shows the present invention.Reference example 3Explanatory drawing of the magnetic sensor element by this.
8 is a BB cross-sectional view of a magnetic sensor portion of the magnetic sensor element of FIG.
FIG. 9 shows the present invention.Embodiment 1Explanatory drawing of the magnetic sensor element by this.
10 is a cross-sectional view of CC of the magnetic sensor unit in the magnetic sensor element of FIG. 9;
11 is a view showing a polyimide resin film having a spiral conductor pattern used in the magnetic sensor element of FIG. 9;
FIG. 12 shows the present invention.Reference example 4Explanatory drawing of the magnetic sensor element by this.
13 is an explanatory diagram of a pattern of a magnetic impedance sensor chip of the magnetic sensor element of FIG. 12. FIG.
FIG. 14 is a diagram comparing the magnetic bias efficiency and magnetic sensitivity of a conventional round bobbin and a triangular bobbin of the present invention.
FIG. 15 shows the present invention.Reference Example 5Explanatory drawing of the magnetic sensor element by this.
16 is an explanatory diagram of a pattern of a magnetic impedance sensor chip of the magnetic sensor element of FIG.
FIG. 17 is a characteristic diagram of applying a magnetic field from a thin film coil.
FIG. 18 is a diagram showing a relationship between a disconnection defect rate of a magnetic pattern and a forward tapered region width.
FIG. 19 is a diagram showing an example of a magnetic sensor element having a uniaxial magnetic detection direction.
FIG. 20 is an explanatory diagram of a domain wall in a non-magnetic field.
FIG. 21 is an explanatory diagram of a domain wall when a magnetic field slightly larger than the magnetic anisotropy is applied in the longitudinal direction of the magnetic body.
22 shows that a stronger magnetic field is applied in the longitudinal direction of the magnetic body than in the case of FIG.WasFIG.
FIG. 23 is a characteristic diagram of impedance versus external magnetic field of a magnetic impedance sensor chip.
FIG. 24 is a diagram showing an example of a magnetic sensor element having a uniaxial magnetic detection direction.
FIG. 25 is a diagram showing an example of the relationship between the number of turns and a magnetic bias at an energization current of 10 mA.
FIG. 26 is a view showing an example of a magneto-impedance sensor chip provided with a magnetic body pattern inclined at 35 degrees with respect to the printed board surface.
27 is a view showing an example of a magnetic sensor element formed by attaching the magnetic impedance sensor chip of FIG. 26 to a triangular prism.
FIG. 28 is a characteristic diagram of the number of turns and magnetic bias when the bobbin energizing current is 10 mA in the coil of the magnetic sensor element of FIG. 27;
FIG. 29 is an explanatory view of a manufacturing method for joining a folded portion of a magnetic pattern with a conductor film of a non-magnetic piece of 1 μm or less.
FIG. 30 is an explanatory view of a folded portion of a magnetic pattern connected by a non-magnetic piece conductor film of 1 μm or less.
[0068]
[Explanation of symbols]
1,1a, 1b substrate
11, 11a, 11b Printed circuit board
2, 2a, 2b, 21, 21a Magnetic pattern
3, 3a, 3b, 31 Conductor pattern
3a, 3b both ends
4, 4a, 4b, 41, 41a, 41b, 41c, 41d
5 Circuit mounting part
6, 6a, 6b, 6c, 6d, 61, 61a Winding coil
7, 7a, 7b Sensor electrode
8, 8a, 8b Printed circuit board electrode
9, 9a, 9b, 9c, 9d, 91 conductive adhesive
10, 10a Magnetic sensor part
12Through hole
13Polyimide film
14, 14a Insulating protective film
20, 20a, 20b, 20c, 20d Magnetic impedance sensor chip
22 Magnetic core
42 electrode pad
43 Solder
110 Glass substrate
120 Hard magnetic film
130, 160, 180 interlayer insulation film
141 Magnetic piece
142 Non-magnetic piece
170 Spiral coil layer
200 Electrode pad raised section
210 Protective film

Claims (1)

A magnetic impedance sensor chip for performing magnetic detection by utilizing the fact that the magnetic domain structure and the magnetization distribution affect the magnetic permeability of the magnetic thin film by changing the impedance by applying an external magnetic field to the magnetic pattern. Is a plurality of strips having a substantially trapezoidal cross-sectional shape in which the longer parallel side is formed on a flat dielectric substrate and the longer parallel side is disposed on the substrate side. A magneto-impedance sensor chip that is connected in series, is connected to an electrode formed on the dielectric substrate by a nonmagnetic conductor pattern at the start and end, and is covered with an insulating film at portions other than the electrode. A magnetic sensor element,
The magnetic impedance sensor chip is disposed with a surface on which the magnetic material pattern and a nonmagnetic conductor pattern are formed facing a printed circuit board, and the nonmagnetic conductive pattern of the magnetic impedance sensor chip on the surface of the printed circuit board. Two electrodes formed at positions facing each other are connected to the nonmagnetic conductor pattern by a conductor,
A magnetic sensor element, wherein a film of a polymer material on which a spiral conductor pattern is formed is disposed between the magnetic impedance sensor chip and a printed board.

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