JP2006048939A - Anisotropic conductive sheet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a conductive sheet having wiping function. <P>SOLUTION: The sheet has a structure where the conductive sheet slides on the surface of the partner member thereof in pressing. In this structure, for example, the pressing force does not necessarily act only vertically to the partner surface, but a shearing stress acts between mutual surfaces of the sheet and a target electrode field. At this time, the proximity of a slidable sliding part contains rich amount of abrasive material. As such an abrasive material, nickel, carbon fiber or the like can be used. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a conductive sheet, and particularly to an anisotropic conductive sheet having conductivity only in the thickness direction. The present invention also relates to a conductive contact structure using such an anisotropic conductive sheet.

  This anisotropic conductive sheet is preferably used as a connector in an electrical inspection device of a circuit device such as a printed circuit board, a semiconductor integrated circuit device, and a liquid crystal display device, and the circuit device having such an anisotropic conductive sheet is used. It also applies to electrical inspection equipment.

  The anisotropically conductive elastomer sheet can include one that exhibits conductivity only in the thickness direction, or one that exhibits conductivity only in the thickness direction when pressed in the thickness direction. By using such an anisotropic conductive elastomer sheet, not only can a compact electrical connection be achieved without using means such as soldering or mechanical fitting, but also mechanical impact and Soft connection is possible by absorbing strain. Therefore, for example, in the field of electronic computers, electronic digital watches, electronic cameras, computer keyboards, etc., to achieve electrical connection between circuit devices such as printed circuit boards and leadless chip carriers, liquid crystal panels, etc. It is widely used as a connector.

  In electrical inspection of circuit devices such as printed circuit boards, semiconductor integrated circuit devices, and liquid crystal display devices, electrodes to be inspected formed on one surface of the circuit device to be inspected and formed on the surface of the circuit substrate for inspection Electrical connection is made by interposing this anisotropic conductive elastomer sheet between the inspection electrodes.

  In recent years, it has been recognized that it is extremely important to conduct not only electrical inspection of a semiconductor integrated circuit device but also electrical inspection of a semiconductor chip itself before being mounted on a carrier or the like. As an inspection method, it has been proposed to use an anisotropic conductive sheet as a probe card in a WLBI (Wafer Level Burn-in) test in which an electrical inspection of a semiconductor chip is performed in a wafer state.

  As such an anisotropic conductive elastomer sheet, an anisotropic conductive elastomer sheet obtained by uniformly dispersing metal particles in an elastomer (for example, Patent Document 1), conductive magnetic particles are not uniform in the elastomer. An anisotropic conductive elastomer sheet (for example, Patent Document 2) in which a large number of conductive path forming portions extending in the thickness direction by being distributed and insulating portions that insulate them from each other are formed, and the surface of the conductive path forming portion An anisotropic conductive elastomer sheet (for example, Patent Document 3) in which a step is formed between the insulating portion and the insulating portion is disclosed.

In such an anisotropic conductive sheet, the contact electrical resistance with the mating electrode with which the sheet contacts becomes important when high speed performance such as an electric circuit is increasingly required. Such contact electric resistance is considered to be caused by an oxide film or the like on the surface of the electrode, and a device for removing such an oxide film or the like has been made (for example, Patent Document 4).
JP 51-93393 A Japanese Patent Laid-Open No. 53-147772 JP-A-61-250906 Japanese Patent Application No. 11-270576

  However, such contact electrical resistance is caused not only by metal oxides on the electrode surface but also by organic substances such as fatty acids adhering to the surface, which are often handled as so-called contamination. It is also important.

  The present invention has been made on the basis of the above circumstances. For example, when used for electrical inspection of a circuit device, the position of a practical electrical inspection device even for a minute electrode to be inspected. It is possible to provide an anisotropic conductive sheet that can reliably achieve a required electrical connection within the alignment accuracy and has less contamination attached to the surface of the electrode to be connected.

  In other words, an anisotropic conductive sheet having a surface structure in which sliding that eliminates contamination occurs on the surface of the target electrode is provided. For example, when the target electrode is pressed against the sheet, the surface of the target electrode is slid by the pressing force. More specifically, the structure is such that the pressing force does not necessarily act perpendicularly to the surface of the target electrode, and a shear stress acts between the sheet and the target electrode interface. At this time, the abrasive is richly contained in the vicinity of the sliding portion that can be slid. As such an abrasive material, for example, flaky nickel, powdered nickel, a relatively short carbon fiber, or the like can be used.

  More specifically, the following is provided.

  (1) In the conductive sheet that can have conductivity in the thickness direction, one or more protrusions are provided on the sheet surface of the conductive sheet so as to be narrow or thin toward the tip, The protrusion protrudes from the sheet surface of the conductive sheet at a predetermined angle with respect to the surface, and the protrusion height from the base is substantially smaller than the width or thickness of the protrusion at the base. An anisotropic conductive sheet characterized by being 20% or more with respect to.

  Here, the conductive sheet may include a so-called anisotropic conductive sheet, and may include a sheet whose conductivity changes according to compression. The protrusion may include a convex portion or a member protruding from the surrounding reference surface, and it does not matter whether the shape seen from above is a circle, a rectangle, or any other shape. The narrow or thin thickness toward the tip may include, for example, a protrusion shape that narrows toward the tip. The angle of protrusion is determined by the imaginary line and the sheet surface when a virtual line is drawn from the so-called center of the base surface along the sheet surface that is the base of the protrusion toward the substantial tip of the protrusion. The angle to make. For example, in the case of a hemispherical protrusion, the imaginary line connecting the center of the base surface (for example, the center of the base circle) and the tip is substantially perpendicular to the sheet surface. The height of the projection can be measured along this imaginary line. If it is a hemisphere, 50% of the diameter of the sphere, which is the reference width of the basal plane (the radius of the sphere), corresponds to the height. To do. In the case of 1/3 sphere and 1/4 sphere instead of a hemisphere, the height is about 35% and the reference width of the basal plane with respect to almost the diameter (about 95%) which is the reference width of the basal plane. The height is about 30% with respect to the length (about 85%) almost close to the diameter, and about 2/3 sphere and 3/4 sphere are about 70% and about 90%, respectively.

  (2) The anisotropic conductive sheet according to (1), wherein the height of the protrusion is 3 μm to 10 μm.

  The height of the protrusion is desirably 0.1 μm or more, more desirably 1 μm or more, and further desirably 3 μm or more. Further, the height of the protrusion is desirably 100 μm or less, more desirably 20 μm or less, and still more desirably 10 μm or less.

  (3) The anisotropic conductive sheet according to (1) or (2), wherein the protrusions are also disposed on the opposite sheet surface.

  (4) The anisotropic conductive sheet according to any one of (1) to (3), wherein the predetermined angle is about 30 degrees or more.

  The optimum angle can be changed depending on the material and the shape thereof. In general, the predetermined angle is preferably an angle at which the pressing force is easily changed to the shearing force. Specifically, if the material used for the protrusion is normal rubber, it is preferably 10 degrees or more, more preferably 20 degrees or more, and further preferably 30 degrees or more. When side slip shear is expected, the predetermined angle is preferably 80 degrees or less, more preferably 70 degrees or less, and still more preferably 60 degrees or less. This is because there is a possibility that a large shear component due to force distribution can be obtained. The maximum value of the predetermined angle is theoretically 90 degrees. When a contact shear force is expected, the predetermined angle is preferably about 80 degrees or more, and a predetermined angle of about 90 degrees may be more preferable.

  (5) The anisotropic conductive sheet according to any one of (1) to (3), wherein the predetermined angle is about 80 degrees or more.

  (6) The anisotropic conductive sheet according to any one of (1) to (5), wherein the protrusion has an abrasive-rich portion on the surface or in the vicinity of the surface.

  The abrasive material is preferably a material, member or part that cuts away contamination on the surface and substantially protrudes from the sheet surface. The size is more preferably several μm to several tens of μm.

  (7) The anisotropic conductive sheet according to (6), wherein the abrasive material includes nickel.

  (8) The anisotropic conductive sheet according to (6), wherein the abrasive material includes carbon fibers.

  Nickel may be in the form of flakes, powders, or other shapes, and more preferably has corners that are easy to cut. Nickel oxide or the like may be included. The carbon fiber may include PAN-based, pitch-based, and other carbon fibers.

  (9) The anisotropic conductive sheet according to any one of (1) to (8), wherein the anisotropic conductive sheet is made of a silicone resin.

  (10) The anisotropic conductive sheet according to any one of (1) to (8), wherein the anisotropic conductive sheet is made of a fluororesin.

  (11) The anisotropic conductive sheet according to any one of (1) to (10) above is sandwiched between two substrates and connected by contacting the two sheet surfaces via the anisotropic conductive sheet. A conductive contact structure comprising the substrate and the anisotropic conductive sheet, wherein a bump is provided on a surface of the substrate corresponding to a contact portion of at least one sheet surface.

  Effective in removing organic substances that cause contact electrical resistance.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a schematic diagram showing two contact states of an anisotropic conductive sheet 10 and a counterpart electrode (which may be a substrate in another example) 18 according to an embodiment of the present invention. This anisotropic conductive sheet 10 is a sheet that can have conductivity in the vertical direction (thickness direction) in the figure, and the protrusion 12 on the downward surface (sheet surface) has a predetermined line with respect to the vertical line 14. It extends at an angle (in this figure, diagonally left downward). The protrusion 12 has an approximately elliptical outline in the figure, but has a three-dimensional shape and a protruding bar shape. However, in another embodiment, it may be a band shape extending long from the near side to the far side in the figure.

  Near the tip of the protrusion 12, there is an opposing contact portion 16 ′ (first contact portion) that is pressed at the contact portion 16 (first contact portion) of the electrode 18 (the substrate to be held is not shown), Mechanical contact and electrical conduction with the electrode 18 are possible. At this time, the distance between the anisotropic conductive sheet 10 and the respective reference surfaces of the electrodes 18 is d1 (FIG. 1A). On the surface of the electrode 18, the distance from the vertical line 14 that passes through substantially the center of the base portion of the protrusion 12 (connection portion with the surface of the anisotropic conductive sheet 10) to the first contact portion 16 is D 1. .

  In the vicinity of the first contact portion 16 ′ of the protruding portion 12, nickel is basically included in a metal state, which not only contributes to conductivity but also the first electrode facing the counterpart electrode 18. It becomes possible to remove at least a part of a film such as an organic substance on the surface of the contact portion 16. Such a mechanism for removing the organic coating is generally considered to be due to abrasive wear, and in addition to nickel, metal, ceramics, carbon fiber, and other materials having abrasive properties can be appropriately selected. If importance is attached to the function of improving conductivity, it is preferable to apply an abrasive material having conductivity such as metal.

  FIG. 1B shows a case where the distance between the anisotropic conductive sheet 10 and the electrode 18 is further increased to d2. The projecting portion 12 is further tilted to the left by the pressing force to be approached, and is pressed at the contact portion 20 (second contact portion) of the electrode 18, and is opposed to the electrode 18 by the opposing contact portion 20 ′ (second contact portion). Can be brought into mechanical contact and electrical conduction. As can be seen from the figure, the distance from the vertical line 14 to the second contact portion 20 is D2, and D2> D1. Accordingly, if attention is paid to the electrode 18, the contact portion is slightly shifted to the left from the first contact portion 16 to the second contact portion 20, and the distance between the anisotropic conductive sheet 10 and the electrode 18 is d2. It can be seen that sliding with the surface of the protrusion 12 occurs in the process of bringing the protrusions close to each other. At this time, the first contact portion 16 ′ of the protrusion 12 is positioned on the more distal side of the protrusion 12 than the second contact portion 20 ′. However, it is possible to prevent the position of the contact portion from changing by changing the shape or structure of the protrusion, and conversely, the second contact portion can be arranged more on the tip side. .

  FIG. 2 schematically shows two contact states of the anisotropic conductive sheet 10 and the counterpart electrode (which may be a substrate in another example) 18 according to another embodiment of the present invention. This anisotropic conductive sheet 10 is a sheet that can have conductivity in the vertical direction (thickness direction) in the figure, and has an oblique protrusion 12 similar to that shown in FIG. Vertical protrusions 22 are each inclined at a predetermined angle with respect to the vertical line 14 and extend substantially parallel to the vertical line 24. These protrusions 12 and 22 have almost half of an elliptical outline in the figure, but are three-dimensional and have a protruding bar shape. However, in another embodiment, it may be a band shape extending long from the near side to the far side in the figure.

  As in FIG. 1, there is an opposing contact portion 16 ′ (first contact portion) that is pressed at the contact portion 16 (first contact portion) of the electrode 18 almost at the tip of the projection portion 12. There is an opposing contact portion 26 ′ (first contact portion) pressed at the contact portion 26 (first contact portion) of the electrode 18 at the tip of the portion 22, and mechanical contact with the electrode 18 and electrical Conduction is possible. At this time, the distance between the anisotropic conductive sheet 10 and the respective reference surfaces of the electrodes 18 is d3 (FIG. 2A). On the surface of the electrode 18, the distance from the vertical line 14 that passes through substantially the center of the base portion of the protrusion 12 (connection portion with the surface of the anisotropic conductive sheet 10) to the first contact portion 16 is D3. The distance between the vertical lines 14 and 24 is L3.

  As in the embodiment in FIG. 1, the first contact portions 16 ′ and 26 ′ of the protrusion 12 include nickel in a basically metallic state, which not only contributes to conductivity, It becomes possible to remove at least a part of a coating film such as an organic substance on the surface of the first contact portion 16 facing the opposing electrode 18, and materials other than nickel are also considered.

  FIG. 2B shows a case where the distance between the anisotropic conductive sheet 10 and the electrode 18 is further increased to d4. The protruding portion 12 is further tilted to the left by the pressing force to be approached, and is pressed at the contact portion 20 (second contact portion) of the electrode 18. Although the same, the respective contact portions 26 and 26 ′ are capable of mechanical contact and electrical conduction with the electrode 18. As can be seen from the figure, the distance from the vertical line 14 to the second contact portion 20 'is D4, and D4> D3. Accordingly, when attention is paid to the electrode 18, the contact portion slightly shifts to the left from the first contact portion 16 to the second contact portion 20, and the distance between the anisotropic conductive sheet 10 and the electrode 18 is d4. It can be seen that sliding with the surface of the protrusion 12 occurs in the process of bringing the protrusions close to each other. At this time, the first contact portion 16 ′ of the protrusion 12 is positioned closer to the distal end side of the protrusion 12 than the second contact portion 20 ′ is the same as in the embodiment of FIG. .

  Although the contact portion 26 ′ at the tip of the protrusion 22 of the anisotropic conductive sheet 10 does not skid, it receives the pressing force as it is, and the contact area does not increase so much, so the contact pressure becomes considerably high. Therefore, not the destruction of the coating film due to the shearing force caused by sliding, but the piercing effect of the abrasive can be expected. In addition, since the relative lateral displacement force acting on the anisotropic conductive sheet 10 and the electrode 18 due to the sliding of the protruding portion 12 is opposed by the frictional force at the contact portions 26 and 26 ', lateral displacement hardly occurs.

  FIG. 3 schematically shows two contact states of the anisotropic conductive sheet 10 and the counterpart electrode (which may be a substrate in another example) 18 according to still another embodiment of the present invention. . This anisotropic conductive sheet 10 is a sheet that can have conductivity in the vertical direction (thickness direction) in the figure, and the oblique projections 12 similar to those shown in FIG. 1 on the downward surface, and The protrusions 42 inclined in the opposite direction extend at an angle with respect to the vertical lines 14 and 44, respectively. These protrusions 12 and 42 have almost half of an elliptical outline in the figure, but are three-dimensional and have a protruding bar shape. However, in another embodiment, it may be a band shape extending long from the near side to the far side in the figure.

  As in FIG. 1, there is an opposing contact portion 16 ′ (first contact portion) that is pressed at the contact portion 16 (first contact portion) of the electrode 18 at substantially the tip of the protruding portion 12. Near the tip of the protrusion 42 is an opposing contact portion 46 ′ (first contact portion) that is pressed at the contact portion 46 (first contact portion) of the electrode 18, and mechanical contact with the electrode 18 and Electrical continuity is possible. At this time, the distance between the anisotropic conductive sheet 10 and each reference surface of the electrode 18 is d5 (FIG. 3A). On the surface of the electrode 18, each of the first contact portions 16 is formed from vertical lines 14 and 44 that pass through substantially the center of each base portion (connecting portion with the surface of the anisotropic conductive sheet 10) of the projecting portions 12 and 42. , 46 is D5, D5 ′, and the distance between the vertical lines 14 and 44 is L5.

  As in the embodiment in FIG. 1, nickel is basically included in the metallic state in the vicinity of the first contact portions 16 ′, 20 ′ and the contact portions 46 ′, 48 ′ of the protrusions 12 and 42. In addition to contributing to conductivity, it is possible to remove at least part of the coating of organic matter or the like on the surface of the opposing first contact portions 16 and 46 of the counterpart electrode 18, and materials other than nickel can be used. Will also be considered.

  FIG. 3B shows a case where the distance between the anisotropic conductive sheet 10 and the electrode 18 is further increased to d6. The projecting portion 12 is further tilted to the left by the pressing force to be approached, and is pressed at the contact portion 20 (second contact portion) of the electrode 18, and is opposed to the contact portion 20 ′ (second contact portion). The protruding portion 42 is further tilted to the right and pressed at the contact portion 48 (second contact portion) of the electrode 18, and is in mechanical contact with the electrode 18 at the opposed contact portion 48 ′ (second contact portion). In addition, electrical conduction is possible. As can be seen from the figure, the distances from the respective vertical lines 14 and 44 to the second contact portions 20 ′ and 48 ′ are D6 and D6 ′, and D6> D5 and D6 ′> D5 ′. . Accordingly, when attention is paid to the electrode 18, the contact portion is slightly shifted to the left from the first contact portion 16 to the second contact portion 20, and the contact portion is shifted from the first contact portion 46 to the second contact portion 20. 2 is slightly shifted to the right, and in the process of bringing the distance between the anisotropic conductive sheet 10 and the electrode 18 close to d6, sliding with the surface of the protrusions 12 and 42 occurs. I understand that. At this time, the fact that the first contact portions 16 ′, 46 ′ of the projections 12, 42 are located on the more distal side of the projections 12, 42 than the second contact portions 20 ′, 48 ′, etc. This is the same as in the first embodiment.

  The relative lateral displacement force acting on the anisotropic conductive sheet 10 and the electrode 18 due to the sliding of the protrusion 12 is opposed to the relative lateral displacement force acting on the anisotropic conductive sheet 10 and the electrode 18 due to the sliding of the protrusion 42. , Cancel each other and do not easily cause a lateral shift.

  FIG. 4 is a schematic diagram showing two contact states of an anisotropic conductive sheet 50 and a counterpart electrode (which may be a substrate in another example) 58 according to another embodiment of the present invention. The anisotropic conductive sheet 10 is a sheet that can have conductivity in the vertical direction (thickness direction) in the figure, and two protrusions 52 and 62 are formed on the downward surface with respect to the vertical lines 54 and 64. It extends almost in parallel (downward in this figure). The protrusions 52 and 62 have almost half of an elliptical outline in the figure, but have a three-dimensional shape and have a protruding bar shape. However, in another embodiment, it may be a band shape extending long from the near side to the far side in the figure.

  On the surface of the electrode 58 facing the anisotropic conductive sheet 50, the bump 59 is formed in a substantially hemispherical shape. The protrusions 52 and 62 are opposed to the contact portions 56 ′ and 66 ′ (first contact portion) opposed to each other by pressing at the contact portions 56 and 66 (first contact portion) of the bump 59. In this way, mechanical contact and electrical conduction with the electrode 58 are possible. At this time, the distance between the anisotropic conductive sheet 50 and each reference plane of the electrode 58 is d7 (FIG. 4A). On the surface of the bump 59, the vertical lines 54 and 64 that pass through substantially the center of the base portions of the protrusions 52 and 62 (connection portions with the surface of the anisotropic conductive sheet 10) to the first contact portions 56 and 66. The distances are very short, almost zero each. This can be changed as appropriate depending on the tip shape of the protrusions 52 and 62 and the surface shape of the bump 59.

  In the vicinity of the first contact portions 56 ′ and 66 ′ of the protrusions 52 and 62, nickel is basically contained in a metal state, which not only contributes to conductivity but also the bumps 59 on the other side. It becomes possible to remove at least a part of the organic film or the like on the surfaces of the first contact portions 56 and 66 facing each other. Such organic film removal mechanism is generally considered to be due to abrasive wear, and other than nickel, it is possible to appropriately select metals, ceramics, and other materials having abrasive properties, and selection considering conductivity. Is also possible.

  FIG. 4B shows a case where the distance between the anisotropic conductive sheet 50 and the electrode 58 is further increased to d8. The protrusions 52 and 62 are further tilted to the left and right, respectively, by the pressing force to be brought close to each other, and are pressed at the contact portions 60 and 70 (second contact portion) of the bump 59, facing contact portions 60 ′ and 70 ′ ( The second contact portion) enables mechanical contact and electrical continuity with the bump 59 and thus the electrode 58. As can be seen, the distances from the vertical lines 54 and 64 to the second contacts 60 and 70 are D8 and D8 ', respectively. Accordingly, when attention is paid to the bump 59, the contact portion slightly shifts to the left and right from the first contact portions 56 and 66 to the second contact portions 60 and 70, and the anisotropic conductive sheet 50 In the process of bringing the distance between the electrode 58 and d8 close to each other, it can be seen that sliding with the surfaces of the protrusions 52 and 62 occurs. At this time, the first contact portions 56 ′ and 66 ′ of the protrusions 52 and 62 are located on the more distal side of the protrusions 52 and 62 than the second contact portions 60 ′ and 70 ′. However, it is possible to prevent the position of the contact portion from changing by changing the shape or structure of the protrusion, and conversely, the second contact portion can be arranged more on the tip side. .

  FIG. 5 shows two contact states ((a) and (b) of an anisotropic conductive sheet 110 and a counterpart electrode (which may be a substrate in another example) 118 according to another embodiment of the present invention. )). This anisotropic conductive sheet 110 is a sheet that can have conductivity in the longitudinal direction (thickness direction) in the figure, and the protrusion 112 is substantially perpendicular to the vertical line 114 on the downward surface (sheet surface). (In this figure, downward). The protrusion 112 has a circular outline slightly smaller than half in the drawing, but has a three-dimensional shape and a hemispherical shape. However, in another embodiment, it may be a band shape extending long from the near side to the far side in the figure.

  Near the tip of the protrusion 112, an opposing contact portion 116 ′ (first contact portion) that is pressed by a contact portion 116 (first contact portion) of the electrode 118 (the substrate to be held is not shown) is a protrusion. It is on the side of 112 and is capable of mechanical contact and electrical conduction with the electrode 118. At this time, the distance between the anisotropic conductive sheet 110 and each reference plane of the electrode 118 is d9 (FIG. 5A). On the surface of the electrode 118, a vertical line 114 that passes through substantially the center of the base portion of the protrusion 112 (connecting portion with the surface of the anisotropic conductive sheet 110) substantially passes through the first contact portion 116.

  In the vicinity of the first contact portion 116 ′ of the protrusion 112, flaky nickel 113 is basically contained in a metal state, which not only contributes to conductivity but also faces the counterpart electrode 118. It is possible to remove at least a part of a film such as an organic substance on the surface of the first contact portion 116 to be cut. Such a mechanism for removing the organic coating is generally considered to be due to abrasive wear, and in addition to nickel, metal, ceramics, carbon fiber, and other materials having abrasive properties can be appropriately selected. If importance is attached to the function of improving conductivity, it is preferable to apply conductive abrasive materials such as metals and some carbon fibers.

  FIG. 5B shows a case where the distance between the anisotropic conductive sheet 110 and the electrode 118 is further increased to d10. The protrusion 112 is flattened by the pressing force to approach, and the contact is expanded and pressed to the contact 120 (second contact) of the electrode 118. The contact 120 ′ (second) of the opposite protrusion 112 is pressed. The contact portion of the electrode 118 also comes into contact, and mechanical contact and electrical conduction with the electrode 118 are possible. It should be noted here that the same thing occurs on the right side of the center line 114. As can be seen, the distance from the vertical line 114 to the second contact portion 120 is D10. Therefore, when attention is paid to the electrode 118, the contact portion continuously increases from the first contact portion 116 to the second contact portion 120. That is, it can be seen that the contact area between the surface of the protrusion 112 and the electrode 118 is widened in the process of bringing the anisotropic conductive sheet 110 and the electrode 118 closer to d10.

  The mechanism at this time will be discussed with reference to FIG. A hemispherical protrusion 112 is disposed on the sheet surface of the anisotropic conductive sheet 110. This hemisphere is drawn by the circular arc obtained from the circle of radius R centering on the virtual center C in the figure. Below that, the X-axis 130 extends parallel to the sheet surface. The point O on the X-axis 130 corresponds to the first contact portion 116 ′ of the protrusion 112. The point P is a position corresponding to 120 ′ in FIG. 5B, and the position of the orthogonal projection on the X axis 130 is the point A. That is, the distance OA = R × sin θ. However, the distance from 116 ′ to the point P corresponds to the distance OB on the X axis 130 (theoretically, OB = R × θ) when measured along the outer surface of the hemisphere 112. Since the distance OB is obviously longer than the distance OA, in FIG. 5 (b), the distance OB is substantially a straight line distance (corresponding to the distance OA) from the first contact portion 116 ′ to the second contact portion 120 ′. A line that forms an arc of only OB (only in the figure, actually a two-dimensional surface) is accommodated. This is because the protrusion 112 is an elastic body made of a rubber component, and the line that forms the arc of the distance OB is compressed so as to trace the surface of the electrode 118 made of a material having a higher elastic modulus. is there. In other words, when the distance between the anisotropic conductive sheet 110 and the electrode 118 is changed from d10 to d9, the line that forms the compressed arc returns to the original distance OB, and therefore a line corresponding to the distance OA on the other side. A shear force is applied to (actually a surface). That is, the contamination layers on the surfaces of the anisotropic conductive sheet 110 and the electrode 118 are respectively given compressive and tensile forces. At this time, the corners of the nickel pieces on the surface of the protruding portion 112 remove the contamination on the surface of the electrode 118.

  On the other hand, in the process of reducing the distance between the anisotropic conductive sheet 110 and the electrode 118 from d9 to d10, a shearing force is generated because the arc-shaped line is compressed. That is, the contaminant layers on the surfaces of the anisotropic conductive sheet 110 and the electrode 118 act as tensile and compressive forces, respectively. At this time, the corners of the nickel pieces on the surface of the protruding portion 112 remove the contamination on the surface of the electrode 118.

  Note that such consideration is based on the theory and may differ from what is actually occurring, but in the above-described embodiment, as a result, it has a wiping function, and the configuration as described above. However, apart from the details of the mechanism, there is no doubt that it is effective in solving the problems of the present invention.

  As described above, according to the present invention, there is an effect in removing organic substances that cause contact electrical resistance. The present invention is not limited to the above embodiment, and various design changes and modifications can be added within the scope of the present invention.

It is a schematic diagram of the anisotropically conductive sheet and counterpart electrode which concern on embodiment of this invention. It is a schematic diagram of the anisotropically conductive sheet and counterpart electrode which concern on embodiment of this invention. It is a schematic diagram of the anisotropically conductive sheet and counterpart electrode which concern on embodiment of this invention. It is a schematic diagram of the anisotropically conductive sheet and counterpart electrode which concern on embodiment of this invention. It is a schematic diagram of the anisotropically conductive sheet and counterpart electrode which concern on embodiment of this invention. It is a figure explaining a projection part shape.

Explanation of symbols

10, 50, 110 Anisotropic conductive sheet 12, 22, 42, 52, 62, 112 Protrusion 14, 24, 44, 54, 64, 114 Vertical line 16, 46, 56, 66, 116 First contact portion 18, 58, 118 Electrodes 20, 48, 60, 70, 120 Second contact portion 26 Contact portion 59 Bump

Claims (11)

In the conductive sheet that can have conductivity in the thickness direction,
One or more protrusions are provided on the sheet surface of the conductive sheet so as to be narrow or thin toward the tip,
The protrusion protrudes from the sheet surface of the conductive sheet at a predetermined angle with respect to the surface,
An anisotropic conductive sheet characterized in that a protruding height from the base portion is 20% or more with respect to a substantially smaller dimension of the width or thickness dimension at the base portion of the protrusion.   The anisotropic conductive sheet according to claim 1, wherein a height of the protrusion is 3 μm to 10 μm.   The anisotropic conductive sheet according to claim 1, wherein the protrusion is disposed also on the opposite sheet surface.   The anisotropic conductive sheet according to claim 1, wherein the predetermined angle is about 30 degrees or more.   The anisotropic conductive sheet according to claim 1, wherein the predetermined angle is about 80 degrees or more.   The anisotropic conductive sheet according to any one of claims 1 to 5, wherein the protrusion has an abrasive-rich portion on the surface or in the vicinity of the surface.   The anisotropic conductive sheet according to claim 6, wherein the abrasive material includes nickel.   The anisotropic conductive sheet according to claim 6, wherein the abrasive material includes carbon fibers.   The anisotropic conductive sheet according to claim 1, wherein the anisotropic conductive sheet is made of a silicone resin.   The anisotropic conductive sheet according to claim 1, wherein the anisotropic conductive sheet is made of a fluororesin. The substrate that is connected by sandwiching the anisotropic conductive sheet according to any one of claims 1 to 10 between two substrates and contacting the two sheet surfaces through the anisotropic conductive sheet, and the substrate A conductive contact structure comprising an anisotropic conductive sheet, wherein a bump is provided on a surface of the substrate corresponding to a contact portion of at least one sheet surface.

Images