JP6629417B2 - Connectors and electronic equipment - Google Patents

Description

  The present invention relates to a connector and an electronic device.

  Conventionally, as a technique for improving the reliability of connection with an object to be connected, for example, a floating structure that absorbs a positional shift between boards by moving a part of the connector even during and after fitting is provided. Connectors are known.

  Patent Literature 1 discloses an electrical connector that has a floating structure and contributes to miniaturization while suppressing conduction failure due to flux rise.

Japanese Patent No. 5568677

  In recent years, in electronic devices, the amount of information and the speed of signal transmission have been remarkably increasing. Even in a connector using a floating structure, a design corresponding to such large capacity and high speed transmission is required. However, in the electrical connector described in Patent Literature 1, a design corresponding to such large capacity and high speed transmission has not been sufficiently considered.

  An object of the present invention, which has been made in view of such a problem, is to provide a connector having good transmission characteristics in signal transmission.

In order to solve the above-described problems, a connector according to a first aspect includes:
A first insulator formed in a frame shape,
A second insulator that is disposed inside the first insulator, is relatively movable with respect to the first insulator, and fits with a connection target;
A contact having a first base disposed along the first insulator and a second base disposed along the second insulator;
With
The contact includes a first elastic portion that can be elastically deformed, an adjusting portion, and a second elastic portion that can be elastically deformed between the first base portion and the second base portion,
The first elastic portion extends from the first base toward the second insulator,
A first adjusting portion connected to the first elastic portion, the first adjusting portion being arranged in order from a fitting side along a fitting direction of the second insulator and the object to be connected , the first adjusting portion; A second adjustment unit connected to the second adjustment unit , and a third adjustment unit connected to the second adjustment unit .
The first adjusting portion is wider in the extending direction of the first elastic portion than the width of the first elastic portion in the fitting direction and the width of the second elastic portion in the fitting direction, and Projecting toward the first base portion from the second adjustment portion along an extending direction;
The third adjusting portion is wider in the extending direction of the first elastic portion than the width of the first elastic portion in the fitting direction and the width of the second elastic portion in the fitting direction, and Projecting toward the second base portion from the second adjusting portion along an extending direction;
The second elastic portion extends in the extending direction from the third adjusting portion to the second insulator.

In the connector according to the second aspect,
The first elastic portion, the adjusting portion, and the second elastic portion are sequentially formed from a fitting side along the fitting direction.

In the connector according to the third aspect,
Before the second adjusting portion SL is Ru narrow der in the extending direction from the first adjuster and the third adjuster.

In the connector according to the fourth aspect ,
The contact further includes a third elastic portion that is arranged along the inner wall of the second insulator and extends in the fitting direction and is elastically deformable.

In the connector according to the fifth aspect ,
The second base connects the second elastic portion and the third elastic portion.

The connector according to the sixth aspect is:
In a fitting state in which the second insulator and the connection target are fitted, the electronic device further includes a contact portion that is in electrical contact with the connection target,
The contact portion is formed at a distal end of a portion that is continuous from the third elastic portion in the fitting direction.

In the connector according to the seventh aspect ,
The second insulator includes a wall formed at a position facing the second base.

In the connector according to the eighth aspect ,
The contact is formed to be flat in a thickness direction of the contact, which is orthogonal to the fitting direction and the extending direction.

An electronic device according to a ninth aspect includes:
It has any one of the above connectors.

  ADVANTAGE OF THE INVENTION According to the connector which concerns on one Embodiment of this invention, the transmission characteristic in signal transmission is favorable.

It is the appearance perspective view showing the state where the connector and connection object concerning one embodiment were connected from the top view. It is the appearance perspective view showing the state where the connector and connection object concerning one embodiment were separated from the top view. FIG. 2 is an external perspective view showing the connector according to the embodiment as viewed from above. FIG. 4 is an exploded perspective view of the connector of FIG. 3 as viewed from above. FIG. 5 is a sectional perspective view taken along the line VV of FIG. 3. FIG. 6 is an enlarged view of a VI section in FIG. 5. FIG. 5 is a sectional view taken along the line VV of FIG. 3. It is the front view which showed a pair of contacts. FIG. 9 is an enlarged view of a portion IX in FIG. 8. FIG. 5 is a schematic diagram illustrating a state of impedance change in a first elastic portion, an adjusting portion, and a second elastic portion of a contact. FIG. 4 is an external perspective view showing a connection target connected to the connector of FIG. 3 as viewed from above. FIG. 12 is an exploded perspective view of the connection target in FIG. 11 as viewed from above. FIG. 3 is a cross-sectional view taken along the line XIII-XIII of FIG. 1. It is the schematic diagram which showed the 1st example in which a pair of contact deforms elastically. It is the schematic diagram which showed the 2nd example in which a pair of contact deforms elastically. It is a schematic diagram which shows the 1st example of the shape of the adjustment part of a contact. It is a schematic diagram which shows the 2nd example of the shape of the adjustment part of a contact. It is a schematic diagram which shows the 3rd example of the shape of the adjustment part of a contact. It is a schematic diagram which shows the 4th example of the shape of the adjustment part of a contact.

  Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings. The front, rear, left, right, and up and down directions in the following description are based on the directions of arrows in the drawings. The directions of the arrows are aligned with each other in different drawings in FIGS. 1 to 9, FIG. 13, and FIGS. 16A to 16D. The directions of the arrows are aligned with each other in FIGS. The directions of the arrows are aligned with each other in FIGS. 14 and 15. In some drawings, illustration of the circuit boards CB1 and CB2 is omitted for the purpose of simple illustration.

  In the following description, the connector 10 according to one embodiment is described as a receptacle connector, and the connection target 60 is a plug connector. That is, when the connector 10 is connected to the connection target 60, the connector 10 in which the contact portion of the contact 50 is elastically deformed is referred to as a receptacle connector, and the connection target 60 in which the contact 90 is not elastically deformed is referred to as a plug connector. The types of the connector 10 and the connection target 60 are not limited thereto. The connector 10 may serve as a plug connector, and the connection target 60 may serve as a receptacle connector.

  In the following description, the connector 10 and the connection target 60 are connected to the circuit boards CB1 and CB2, respectively, and are described as being connected to each other in the vertical direction. That is, the connector 10 and the connection target 60 are connected along the up-down direction as an example. The “fitting direction” used in the following description is assumed to indicate the vertical direction as an example. The connection method is not limited to this. The connector 10 and the connection target 60 may be connected to the circuit boards CB1 and CB2 in parallel directions, respectively, or one may be connected in a vertical direction and the other may be connected in a parallel direction. The circuit boards CB1 and CB2 may be rigid boards or any other circuit boards. For example, the circuit board CB1 or CB2 may be a flexible printed circuit board (FPC).

  FIG. 1 is an external perspective view showing a state in which a connector 10 and a connection target 60 according to an embodiment are connected, as viewed from above. FIG. 2 is an external perspective view showing a state in which the connector 10 and the connection target 60 according to the embodiment are separated from each other when viewed from above.

  The connector 10 according to one embodiment has a floating structure. The connector 10 allows relative movement of the connected connection object 60 with respect to the circuit board CB1. That is, the connection target 60 can move within a predetermined range with respect to the circuit board CB1 even when the connection target 60 is connected to the connector 10.

  FIG. 3 is an external perspective view illustrating the connector 10 according to the embodiment as viewed from above. FIG. 4 is an exploded perspective view of the connector 10 of FIG. 3 as viewed from above. FIG. 5 is a cross-sectional perspective view taken along the line VV of FIG. FIG. 6 is an enlarged view of the VI section in FIG. FIG. 7 is a cross-sectional view taken along the line VV of FIG. FIG. 8 is a front view showing a pair of contacts 50. FIG. 9 is an enlarged view of a portion IX in FIG.

  As shown in FIG. 4, the connector 10 includes a first insulator 20, a second insulator 30, a metal fitting 40, and a contact 50 as large components. The connector 10 is assembled by, for example, the following method. That is, the fitting 40 is press-fitted from below the first insulator 20, and the second insulator 30 is arranged inside the first insulator 20 into which the fitting 40 is press-fitted. The contacts 50 are press-fitted from below each.

  The detailed structure of the connector 10 in a state where the contact 50 is not elastically deformed will be described mainly with reference to FIGS.

  As shown in FIGS. 4 and 5, the first insulator 20 is a rectangular tubular member obtained by injection molding an insulating and heat-resistant synthetic resin material. The first insulator 20 is hollow and has openings 21A and 21B on the upper surface and the lower surface, respectively. The first insulator 20 is constituted by four side surfaces, and has an outer peripheral wall 22 surrounding an internal space. The first insulator 20 has a fitting mounting groove 23 that is recessed inside the first insulator 20 along the vertical direction at both left and right end portions of the outer peripheral wall 22. A metal fitting 40 is mounted in the metal fitting groove 23.

  The first insulator 20 has a plurality of contact mounting grooves 24 formed from the lower edges of the front and rear surfaces of the outer peripheral wall 22 to the lower surface and the inner surface. The plurality of contacts 50 are respectively mounted in the plurality of contact mounting grooves 24. The number of the contact mounting grooves 24 is the same as the number of the contacts 50. The plurality of contact mounting grooves 24 are recessed side by side in the left-right direction. The contact mounting groove 24 extends vertically in the inner surface of the first insulator 20.

  The second insulator 30 is a member extending in the left-right direction, which is formed by injection-molding an insulating and heat-resistant synthetic resin material. The second insulator 30 is formed in a substantially convex shape in a front view from the front. The second insulator 30 has a bottom portion 31 that constitutes a lower portion, and a fitting protrusion 32 that projects upward from the bottom portion 31 and fits with the connection target 60. The bottom 31 is longer than the fitting projection 32 in the left-right direction. In other words, the left and right ends of the bottom 31 protrude outward from the left and right ends of the fitting projection 32, respectively. The second insulator 30 has a fitting concave portion 33 provided on the upper surface of the fitting convex portion 32. The second insulator 30 has a guiding portion 34 formed so as to surround the fitting concave portion 33 over the upper edge of the fitting convex portion 32. The guiding portion 34 is formed by an inclined surface that is inclined obliquely inward and upward at the upper edge of the fitting projection 32.

  The second insulator 30 has a plurality of contact mounting grooves 35 formed side by side in the left-right direction. The plurality of contacts 50 are respectively mounted in the plurality of contact mounting grooves 35. The number of the contact mounting grooves 35 is the same as the number of the contacts 50. The plurality of contact mounting grooves 35 extend in the up-down direction. The lower part of the contact mounting groove 35 is formed by recessing the lower part of the front surface and the rear surface of the second insulator 30. The center of the contact mounting groove 35 is formed inside the second insulator 30. The upper part of the contact mounting groove 35 is formed by recessing both inner surfaces of the fitting recess 33 in the front-rear direction.

  The second insulator 30 has a wall portion 36 that extends internally from the bottom surface of the fitting recess 33 downward. The wall portions 36 are located between a pair of contacts 50 attached to the second insulator 30 in a state of being arranged in the front-rear direction. That is, the wall portion 36 faces each of the pair of contacts 50. The upper portion of the wall portion 36 is formed to be the widest. The central portion of the wall portion 36 is formed narrower than the upper portion. The lower portion of the wall portion 36 is formed to be narrower than the central portion. The front and rear surfaces of the wall portion 36 constitute a part of the contact mounting groove 35. The central portion of the contact mounting groove 35 formed inside the second insulator 30 becomes narrower in the front-rear direction from the lower side to the upper side as the width of the central portion and the upper portion of the wall portion 36 changes.

  The metal fitting 40 is obtained by forming a thin plate of an arbitrary metal material into a shape shown in FIG. 4 using a progressive die (stamping). The metal fittings 40 are press-fitted into the metal fitting mounting grooves 23, and are disposed at both left and right ends of the first insulator 20. Each of the metal fittings 40 is formed in a substantially H shape in a front view from the left and right directions. The metal fitting 40 has a mounting part 41 extending outward in a substantially U-shape at lower ends on both front and rear sides thereof. The metal fitting 40 has a continuous part 42 extending in the front-rear direction at a substantially central part in the vertical direction. The metal fitting 40 has a retaining portion 43 that protrudes inward in the left-right direction from the lower edge portion substantially in the front-rear direction in the continuous portion 42. The retaining portion 43 suppresses the second insulator 30 from coming off the first insulator 20 upward. The metal fitting 40 has locking portions 44 for locking with respect to the first insulator 20 at upper end portions on both front and rear sides thereof.

  The contact 50 is formed by molding a thin plate of a copper alloy having spring elasticity (for example, phosphor bronze, beryllium copper, or titanium copper) or a Corson-based copper alloy into a shape shown in FIGS. 4 to 9 using a progressive die (stamping). It is processed. The contact 50 is formed only by punching. The processing method of the contact 50 is not limited to this, and may include a step of bending in the plate thickness direction after performing the punching processing. The contact 50 is formed of a metal material having a small elastic coefficient so that the shape change accompanying elastic deformation is large. The surface of the contact 50 is plated with gold or tin or the like after forming a base by nickel plating.

  As shown in FIG. 4, a plurality of contacts 50 are arranged along the left-right direction. As shown in FIG. 7, the contacts 50 are attached to the first insulator 20 and the second insulator 30. As shown in FIGS. 7 and 8, the pair of contacts 50 arranged at the same left and right positions are formed and arranged symmetrically along the front-rear direction. That is, the pair of contacts 50 are formed and arranged so as to be substantially line-symmetric with each other with respect to the vertical axis passing through the center therebetween.

  The contact 50 has a first base 51 extending in the up-down direction and supported by the first insulator 20. The upper end of the first base 51 is locked to the first insulator 20. The contact 50 is formed continuously with the lower end of the first base 51, and has a locking portion 52 that locks with the first insulator 20. The first base portion 51 and the locking portion 52 are housed in the contact mounting groove 24 of the first insulator 20. The contact 50 has a mounting portion 53 extending outward in a substantially L-shape from the outside of the lower end of the locking portion 52.

  As shown in FIG. 9, the contact 50 has a first elastic portion 54 </ b> A that is elastically deformable and extends inward from the first base portion 51 in the front-rear direction. The first elastic portion 54A extends obliquely downward and inward from the first base portion 51, then bends obliquely upward, and extends linearly as it is. The first elastic portion 54A bends downward again at its inner end, and is connected to the upper end of the adjusting portion 54B. The first elastic portion 54A is formed narrower than the first base portion 51. As described above, the first elastic portion 54A can adjust a portion that is elastically displaced.

  The contact 50 has an adjusting portion 54B formed continuously with the first elastic portion 54A. The adjusting portion 54B is wider than the first elastic portion 54A as a whole, that is, is formed to have a larger cross-sectional area, and thus has higher electrical conductivity than the first elastic portion 54A. The adjusting portion 54B extends in the fitting direction with the connection target 60, that is, in the up-down direction when the contact 50 is not elastically deformed.

  The adjusting unit 54B includes a first adjusting unit 54B1 forming the upper part, a second adjusting unit 54B2 forming the central part, and a third adjusting unit 54B3 forming the lower part. The upper end of the first adjusting portion 54B1 is connected to the first elastic portion 54A. The first adjusting portion 54B1 has a larger sectional area than the first elastic portion 54A. The first adjusting portion 54B1 projects one step outward from the second adjusting portion 54B2 along the front-rear direction. The second adjusting portion 54B2 has a smaller sectional area than the first adjusting portion 54B1 and a larger sectional area than the first elastic portion 54A. For example, the second adjustment portion 54B2 is formed narrower in the front-rear direction than the first adjustment portion 54B1 and wider in the front-rear direction than the first elastic portion 54A. The third adjusting unit 54B3 has a larger cross-sectional area than the second adjusting unit 54B2. The third adjusting portion 54B3 projects one step inward from the second adjusting portion 54B2 along the front-rear direction. As described above, the adjusting unit 54B has high electric conductivity in the first adjusting unit 54B1 and the third adjusting unit 54B3, and has lower electric conductivity in the second adjusting unit 54B2. The first adjusting portion 54B1 and the third adjusting portion 54B3 are formed symmetrically. That is, the first adjustment unit 54B1 and the third adjustment unit 54B3 are formed so as to be substantially point-symmetric with respect to the center of the adjustment unit 54B.

  The contact 50 extends from the lower end of the third adjusting portion 54B3 to the second insulator 30, and has a second elastic portion 54C that can be elastically deformed. The second elastic portion 54C bends obliquely upward from the lower end of the third adjusting portion 54B3, and extends straight as it is. The second elastic portion 54C bends obliquely downward again and is connected to an outer end of a second base portion 55 described later. The second elastic portion 54C is formed to be narrower than the adjusting portion 54B, like the first elastic portion 54A. As described above, the second elastic portion 54C can adjust a portion that is elastically displaced.

  The first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C are integrally formed in a substantially crank shape. The first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C are arranged sequentially from the fitting side along the fitting direction. The first elastic portion 54A and the second elastic portion 54C are formed symmetrically with respect to the adjusting portion 54B. That is, the first elastic portion 54A and the second elastic portion 54C are formed so as to be substantially point-symmetric with respect to the center of the adjusting portion 54B.

  The first elastic portion 54A and the second elastic portion 54C extend from both ends in the fitting direction in the adjusting portion 54B. More specifically, the first elastic portion 54A extends from the inner end of the upper edge of the first adjusting portion 54B1. On the other hand, the second elastic portion 54C extends from the outer end of the lower edge of the third adjusting portion 54B3. As described above, the connection point between the first elastic portion 54A and the adjustment portion 54B and the connection point between the second elastic portion 54C and the adjustment portion 54B are formed at symmetrical positions with respect to the center of the adjustment portion 54B. I have.

  As shown in FIGS. 7 and 8, the contact 50 has a second base 55 continuous with the second elastic portion 54C. The second base portion 55 is formed wider than the second elastic portion 54C to increase its rigidity. The contact 50 has an elastically deformable third elastic portion 56 extending upward from the second base portion 55 and arranged along the inner wall of the second insulator 30. The third elastic portion 56 extends in a fitting direction with the connection target 60, that is, in a vertical direction in a state where the third elastic portion 56 is not elastically deformed. The entire third elastic portion 56 faces the wall portion 36 of the second insulator 30 formed inside the third elastic portion 56. The contact 50 has a cutout portion 57 formed on the surface of the third elastic portion 56 so as to form a bending point when the third elastic portion 56 elastically deforms. The cutout portion 57 is formed at a substantially central portion of the outer surface of the third elastic portion 56 in the front-rear direction with its surface cut out. The contact 50 is formed continuously above the third elastic portion 56 and has a locking portion 58 that locks with the second insulator 30. The locking portion 58 is formed wider than the third elastic portion 56. The contact 50 is formed continuously above the locking portion 58 and has an elastic contact portion 59 that comes into contact with the contact 90 of the connection target 60 at the time of fitting. The elastic contact portion 59 is formed at the tip of a portion of the contact 50, for example, a portion that continues from the second adjustment portion 54B2 to the opposite side to the first adjustment portion 54B1.

  As shown in FIG. 7, the second base portion 55, the third elastic portion 56, the cutout portion 57, and the locking portion 58 are accommodated in the contact mounting groove 35 of the second insulator 30. The second base portion 55, the third elastic portion 56, and the locking portion 58 substantially entirely oppose the wall portion 36 of the second insulator 30 formed therein. As shown in FIG. 6, the second base 55 connecting the second elastic portion 54 </ b> C and the third elastic portion 56 is arranged at a position facing the lower end of the wall portion 36.

  As shown in FIG. 7, the lower halves of the second base portion 55 and the third elastic portion 56 are accommodated in the lower portions of the contact mounting grooves 35 configured as concave portions on the front and rear surfaces of the second insulator 30. The upper half of the third elastic portion 56 and the locking portion 58 are accommodated in the center of the contact mounting groove 35 formed inside the second insulator 30. The notch portion 57 is formed on the surface of the third elastic portion 56 so as to be located near the boundary between the lower portion of the contact mounting groove 35 and the center thereof.

  The elastic contact portion 59 is substantially accommodated in an upper part of the contact mounting groove 35 configured as a concave portion on the inner surface of the fitting concave portion 33 of the second insulator 30. The tip of the elastic contact portion 59 is exposed from the contact mounting groove 35 into the fitting recess 33.

  FIG. 10 is a schematic diagram showing a state of impedance change in the first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C of the contact 50. The function of the adjustment unit 54B will be described with reference to FIG. In FIG. 10, the vertical axis indicates the magnitude of impedance. The horizontal axis indicates the position in the contact 50. The solid line graph shows the measured value of the impedance. The two-dot chain line graph shows the theoretical value of impedance. Although two graphs, a thick line and a thin line, are shown for each graph, the thick line indicates that the adjusting unit 54B is the first adjusting unit 54B1, the second adjusting unit 54B2, and the third adjusting unit 54B like the contact 50 according to the embodiment. FIG. 14 shows an impedance change in a case where the adjusting section 54B3 has three components. On the other hand, the thin line indicates a temporary impedance change in which, for example, the adjustment unit 54B does not have these three components and is substantially the same as the width of the second adjustment unit 54B2 as a whole. The broken line graph shows the ideal value of the impedance. First, for comparison with the function of the adjustment unit 54B of the contact 50 according to the embodiment, an impedance change when the width of the adjustment unit 54B is substantially the same will be described with reference to a thin line graph.

  The impedance of the entire first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C is adjusted by the adjusting portion 54B. The impedance in each component theoretically changes discretely according to its width, that is, the cross-sectional area, but it is considered that it actually changes continuously in actuality. In the contact 50, since the first elastic portion 54A is formed to be narrow (narrow in cross-sectional area) in order to obtain a large amount of elastic deformation, the impedance adjusted to the ideal value increases in the first elastic portion 54A. . By forming the adjusting portion 54B wide (having a large cross-sectional area) continuously with the first elastic portion 54A, the impedance increased in the first elastic portion 54A is intentionally made lower than the ideal value in the adjusting portion 54B. . Since the second elastic portion 54C that is continuous with the adjusting portion 54B is formed narrow (has a small cross-sectional area) in the same manner as the first elastic portion 54A, the impedance below the ideal value is reduced in the second elastic portion 54C. Again exceeds the ideal value. As described above, the adjustment unit 54B plays a role of offsetting an increase in impedance in the first elastic portion 54A and the second elastic portion 54C to make the impedance close to an ideal value over the whole.

  Subsequently, an impedance change in the case where the adjustment unit 54B has three components, such as the contact 50 according to an embodiment, will be described based on a thick line graph while comparing with a thin line graph. In the contact 50 according to the embodiment, the first adjustment portion 54B1 formed wider than the second adjustment portion 54B2 as compared with the case where the width of the adjustment portion 54B is substantially the same, the upper portion of the adjustment portion 54B. , The impedance is further reduced. This allows the impedance increased from the ideal value in the first elastic portion 54A to intentionally fall below the ideal value earlier. In other words, the increase width of the impedance in the first elastic portion 54A is intentionally suppressed. In the contact 50, the impedance is increased in the central portion of the adjusting portion 54B, that is, in the second adjusting portion 54B2, and as an example, its theoretical value is made substantially the same as the theoretical value indicated by a thin line. That is, the minimum value of the measured impedance value in the adjustment unit 54B is set to be substantially the same as the minimum value of the measured impedance value when the width of the adjustment unit 54B is substantially the same. With such a design, an excessive decrease in impedance in the second adjustment unit 54B2, that is, an extreme divergence between the ideal value and the measured value is suppressed. In the contact 50, the impedance is further reduced at the lower portion of the adjustment unit 54B by the third adjustment unit 54B3 formed wide similarly to the first adjustment unit 54B1. As a result, the impedance that is lower than the ideal value in the adjustment unit 54B is intentionally delayed more than the ideal value in the second elastic unit 54C. In other words, the increase width of the impedance in the second elastic portion 54C is intentionally suppressed. As described above, by adjusting the impedance by dividing the adjusting unit 54B into three components, the adjusting unit 54B cancels the increase in impedance in the first elastic unit 54A and the second elastic unit 54C to reduce the impedance. It can be closer to the ideal value.

  In the connector 10 having the above structure, the mounting portion 53 of the contact 50 is soldered to the circuit pattern formed on the mounting surface of the circuit board CB1. The mounting portion 41 of the metal fitting 40 is soldered to a ground pattern or the like formed on the mounting surface. As described above, the connector 10 is mounted on the circuit board CB1. On the mounting surface of the circuit board CB1, another electronic component (for example, a CPU, a controller, a memory, or the like) other than the connector 10 is mounted.

  The structure of the connection target 60 will be described mainly with reference to FIGS. 11 and 12.

  FIG. 11 is an external perspective view showing the connection target 60 connected to the connector 10 of FIG. 3 as viewed from above. FIG. 12 is an exploded perspective view of the connection target 60 in FIG. 11 as viewed from above.

  As shown in FIG. 12, the connection target 60 has an insulator 70, a metal fitting 80, and a contact 90 as large components. The connection target 60 is assembled by press-fitting the metal fitting 80 and the contact 90 from below the insulator 70.

  The insulator 70 is a quadrangular prism-shaped member obtained by injection-molding an insulating and heat-resistant synthetic resin material. The insulator 70 has a fitting recess 71 formed on the upper surface. The insulator 70 has a fitting projection 72 formed inside the fitting recess 71. The insulator 70 has a guiding part 73 formed so as to surround the fitting recess 71 over the upper edge of the fitting recess 71. The inviting portion 73 is formed by an inclined surface which is inclined obliquely outward and upward at an upper edge portion of the fitting concave portion 71. The insulator 70 has a fitting mounting groove 74 that is recessed inside the insulator 70 along the vertical direction at both left and right ends of the bottom surface (see FIG. 2). The metal fitting 80 is mounted in the metal fitting mounting groove 74.

  The insulator 70 has a plurality of contact mounting grooves 75 formed on the front and rear sides of the bottom and the front and rear surfaces of the fitting projection 72. The plurality of contacts 90 are respectively mounted in the plurality of contact mounting grooves 75. The number of the contact mounting grooves 75 is the same as the number of the contacts 90. The plurality of contact mounting grooves 75 are recessed side by side in the left-right direction.

  The metal fitting 80 is formed by forming a thin plate of an arbitrary metal material into a shape shown in FIG. 12 using a progressive die (stamping). The metal fittings 80 are arranged on both right and left ends of the insulator 70. The metal fitting 80 has a mounting portion 81 that extends outward in a substantially U-shape at the lower end thereof. The metal fitting 80 is formed continuously above the mounting part 81 and has a locking part 82 that locks with the insulator 70.

  The contact 90 is formed by forming a thin plate of a copper alloy having spring elasticity (for example, phosphor bronze, beryllium copper or titanium copper) or a Corson-based copper alloy into a shape shown in FIG. 12 using a progressive die (stamping). It is. The surface of the contact 90 is plated with gold, tin, or the like after forming a base by nickel plating.

  A plurality of contacts 90 are arranged along the left-right direction. The contact 90 has a mounting portion 91 extending outward in a substantially L-shape. The contact 90 has a contact portion 92 formed at an upper end thereof and which comes into contact with the elastic contact portion 59 of the contact 50 of the connector 10 at the time of fitting.

  In the connection object 60 having the above structure, the mounting portion 91 of the contact 90 is soldered to the circuit pattern formed on the mounting surface of the circuit board CB2. The mounting portion 81 of the metal fitting 80 is soldered to a ground pattern or the like formed on the mounting surface. As described above, the connection target 60 is mounted on the circuit board CB2. On the mounting surface of the circuit board CB2, another electronic component (for example, a camera module or a sensor) other than the connection target 60 is mounted.

  The operation of the connector 10 having a floating structure when the connection target 60 is connected to the connector 10 will be described.

  FIG. 13 is a sectional view taken along the line XIII-XIII in FIG.

  The contacts 50 of the connector 10 support the second insulator 30 in a state where the second insulator 30 is separated from the first insulator 20 and floats inside the first insulator 20. At this time, the lower part of the second insulator 30 is surrounded by the outer peripheral wall 22 of the first insulator 20. The upper part of the second insulator 30 including the fitting recess 33 protrudes above the opening 21A of the first insulator 20.

  By mounting the mounting portion 53 of the contact 50 to the circuit board CB1, the first insulator 20 is fixed to the circuit board CB1. The second insulator 30 is movable with respect to the fixed first insulator 20 by the first elastic portion 54A, the second elastic portion 54C, and the third elastic portion 56 of the contact 50 being elastically deformed.

  At this time, the peripheral portion of the opening 21A regulates excessive movement of the second insulator 30 with respect to the first insulator 20. That is, when the second insulator 30 largely moves beyond the design value due to the elastic deformation of the contact 50, the fitting protrusion 32 of the second insulator 30 comes into contact with the peripheral portion of the opening 21A. As a result, the second insulator 30 does not move any further outward.

  In a state where the vertical direction of the connection object 60 is reversed with respect to the connector 10 having such a floating structure, the connector 10 and the connection object 60 are vertically Facing each other. Thereafter, the connection target 60 is moved downward. At this time, even if the mutual positions are slightly shifted in the front-rear and left-right directions, for example, the inviting portion 34 of the connector 10 and the inviting portion 73 of the connection target 60 are in contact with each other. As a result, the second insulator 30 moves relatively to the first insulator 20 due to the floating structure of the connector 10. More specifically, the fitting projection 32 of the connector 10 is led into the fitting recess 71 of the connection target 60.

  When the connection object 60 is further moved downward, the fitting projection 32 of the connector 10 and the fitting recess 71 of the connection object 60 are fitted. At this time, the fitting concave portion 33 of the connector 10 and the fitting convex portion 72 of the connection target 60 are fitted. In a state where the second insulator 30 of the connector 10 and the insulator 70 of the connection target 60 are fitted, the contact 50 of the connector 10 and the contact 90 of the connection target 60 come into contact with each other. More specifically, the elastic contact portion 59 of the contact 50 and the contact portion 92 of the contact 90 contact each other. At this time, the tip of the elastic contact portion 59 of the contact 50 is slightly elastically deformed outward and elastically displaced inside the contact mounting groove 35.

  As described above, the connector 10 and the connection target 60 are completely connected. At this time, the circuit board CB1 and the circuit board CB2 are electrically connected via the contact 50 and the contact 90.

  In this state, the pair of elastic contact portions 59 of the contact 50 sandwich the pair of contacts 90 of the connection target 60 from both the front and rear sides by the inward elastic force along the front and rear direction. When the connection object 60 is removed from the connector 10 due to the reaction of the pressing force of the connection object 60 to the contact 90 caused by this, the second insulator 30 applies a force in the removal direction, that is, the upward direction via the contact 50. Receive. Thus, even if the second insulator 30 moves upward, the retaining portion 43 of the metal fitting 40 press-fitted into the first insulator 20 shown in FIG. 4 prevents the second insulator 30 from coming off. The retaining portion 43 of the metal fitting 40 press-fitted into the first insulator 20 is located immediately above the left and right ends of the bottom portion 31 of the second insulator 30 inside the first insulator 20. Therefore, when the second insulator 30 attempts to move upward, the left and right end portions of the bottom portion 31 projecting outward come into contact with the retaining portions 43. As a result, the second insulator 30 does not move further upward.

  FIG. 14 is a schematic diagram illustrating a first example in which the pair of contacts 50 is elastically deformed. FIG. 15 is a schematic diagram illustrating a second example in which the pair of contacts 50 is elastically deformed.

  The operation of each component when the pair of contacts 50 elastically deforms will be described in detail with reference to FIGS. 14 and 15. Hereinafter, for the sake of simplicity, the contact 50 disposed on the right side of each drawing is referred to as a contact 50A, and the contact 50 disposed on the left side of each drawing is referred to as a contact 50B. 14 and 15, a state where the contacts 50A and 50B are not elastically deformed is indicated by a two-dot chain line.

  In FIG. 14, as an example, it is assumed that the second insulator 30 has moved rightward due to some external factor.

  When the second insulator 30 moves rightward, the locking portion 58 of the contact 50A is pushed rightward by the wall portion 36 of the second insulator 30. At this time, the third elastic portion 56 of the contact 50A bends inward starting from the vicinity of the notch 57. That is, the third elastic portion 56 of the contact 50 </ b> A is elastically deformed further inward below the vicinity of the cutout portion 57 than in the upper portion. The locking portion 58 of the contact 50A in contact with the wall 36 of the second insulator 30 hardly changes the relative position with respect to the second insulator 30, while the second base portion 55 of the contact 50A changes its relative position. Vary inward.

  When the third elastic portion 56 of the contact 50A moves rightward, the connection point between the second elastic portion 54C and the adjusting portion 54B also moves rightward while the second elastic portion 54C is elastically deformed. On the other hand, the change in the left / right position of the connection point between the first elastic portion 54A and the adjustment portion 54B is small. Therefore, the first elastic portion 54A is elastically deformed, the bent portion at the inner end thereof is bent outward, and the adjusting portion 54B is inclined obliquely rightward from above to below.

  When the second insulator 30 moves rightward, the locking portion 58 of the contact 50B is pushed rightward by the inner wall of the second insulator 30. At this time, the third elastic portion 56 of the contact 50B bends outward starting from the vicinity of the notch 57. That is, the third elastic portion 56 of the contact 50 </ b> B is elastically deformed outward below the vicinity of the cutout portion 57 as compared with the upper portion. The locking portion 58 of the contact 50B in contact with the inner wall of the contact mounting groove 35 hardly changes the relative position with respect to the second insulator 30, while the second base portion 55 of the contact 50B moves the relative position outward. Change.

  When the third elastic portion 56 of the contact 50B moves rightward, the connection point between the second elastic portion 54C and the adjustment portion 54B also moves rightward while the second elastic portion 54C is elastically deformed. On the other hand, the change in the left / right position of the connection point between the first elastic portion 54A and the adjustment portion 54B is small. Accordingly, the first elastic portion 54A is elastically deformed, the bent portion at the inner end thereof is bent inward, and the adjusting portion 54B is inclined obliquely rightward from above to below.

  In FIG. 15, as an example, it is assumed that the second insulator 30 has moved leftward due to some external factor.

  When the second insulator 30 moves leftward, the locking portion 58 of the contact 50A is pushed leftward by the inner wall of the second insulator 30. At this time, the third elastic portion 56 of the contact 50A bends outward starting from the vicinity of the notch 57. That is, the third elastic portion 56 of the contact 50 </ b> A is elastically deformed outward below the vicinity of the cutout portion 57 as compared with the upper portion. The locking portion 58 of the contact 50A that is in contact with the inner wall of the contact mounting groove 35 hardly changes the relative position with respect to the second insulator 30, while the second base portion 55 of the contact 50A moves the relative position outward. Change.

  When the third elastic portion 56 of the contact 50A moves leftward, the connection point between the second elastic portion 54C and the adjusting portion 54B also moves leftward while the second elastic portion 54C is elastically deformed. On the other hand, the change in the left / right position of the connection point between the first elastic portion 54A and the adjustment portion 54B is small. Therefore, the first elastic portion 54A is elastically deformed, the bent portion at the inner end thereof is bent inward, and the adjusting portion 54B is inclined obliquely leftward from above to below.

  When the second insulator 30 moves leftward, the locking portion 58 of the contact 50B is pushed leftward by the wall portion 36 of the second insulator 30. At this time, the third elastic portion 56 of the contact 50B bends inward starting from the vicinity of the notch 57. That is, the third elastic portion 56 of the contact 50B is elastically deformed further inward below the vicinity of the cutout portion 57 as compared to the upper portion. The locking portion 58 of the contact 50B in contact with the wall portion 36 of the second insulator 30 hardly changes the relative position with respect to the second insulator 30, while the second base portion 55 of the contact 50B changes its relative position. Vary inward.

  When the third elastic portion 56 of the contact 50B moves to the left, the connection point between the second elastic portion 54C and the adjusting portion 54B also moves to the left while the second elastic portion 54C is elastically deformed. On the other hand, the change in the left / right position of the connection point between the first elastic portion 54A and the adjustment portion 54B is small. Therefore, the first elastic portion 54A is elastically deformed, the bent portion at the inner end thereof is bent outward, and the adjusting portion 54B is inclined obliquely leftward from above to below.

  The connector 10 according to one embodiment as described above has good transmission characteristics in signal transmission. In the connector 10, since the contact 50 has the first adjustment unit 54B1 and the second adjustment unit 54B2, the impedance, that is, the electrical conductivity is adjusted according to the width of each transmission path, that is, the cross-sectional area of the transmission path. For example, the electric conductivity of the first adjusting portion 54B1 is higher than that of the first elastic portion 54A, and the electric conductivity of the second adjusting portion 54B2 is lower than that of the first adjusting portion 54B1 and higher than that of the first elastic portion 54A. . Thereby, the impedances of the first elastic portion 54A, the first adjusting portion 54B1, and the second adjusting portion 54B2 approach an ideal value. That is, the connector 10 can contribute to impedance matching. Therefore, in the connector 10, desired transmission characteristics can be obtained even in large-capacity and high-speed transmission, and the transmission characteristics are further improved as compared with a conventional electric connector that does not have the first adjustment unit 54B1 and the second adjustment unit 54B2. .

  In the connector 10, since the contact 50 further includes the third adjusting portion 54B3, the impedance of the entire first elastic portion 54A, the adjusting portion 54B and the second elastic portion 54C, that is, the electric conductivity is adjusted. For example, the electric conductivity of the third adjusting portion 54B3 is made higher than that of the second adjusting portion 54B2 and the second elastic portion 54C. Thereby, the impedance of the first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C approaches the ideal value. That is, the connector 10 can contribute to impedance matching. Therefore, the connector 10 exhibits the above effects more remarkably.

  As described below, the connector 10 can realize a good floating structure in addition to the above-described good transmission characteristics in signal transmission.

  In the connector 10, since the contact 50 further includes the second elastic portion 54 </ b> C, the amount of movement of the second insulator 30 with respect to the first insulator 20 can be further increased. That is, the amount of movement of the second insulator 30 with respect to the first insulator 20 increases due to the elastic deformation of the second elastic portion 54C in addition to the elastic deformation of the first elastic portion 54A.

  In the connector 10, since the contact 50 further includes the third elastic portion 56, the amount of movement of the second insulator 30 with respect to the first insulator 20 can be further increased. That is, in addition to the elastic deformation of the first elastic portion 54A and the second elastic portion 54C, the amount of movement of the second insulator 30 with respect to the first insulator 20 increases due to the elastic deformation of the third elastic portion 56. Conversely, the connector 10 can allocate a part of the amount of elastic deformation of the contact 50 necessary for obtaining the predetermined amount of movement to the third elastic portion 56, and thus the first elastic portion 54A and the The amount of elastic deformation of the two elastic portions 54C can be reduced. Accordingly, the overall length of the first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C is reduced, and the width of the connector 10 in the front-rear direction is reduced. Therefore, the connector 10 can contribute to downsizing while securing the required amount of movement of the second insulator 30.

  The transmission characteristics of the connector 10 are further improved by reducing the overall length of the first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C. That is, the connector 10 can transmit a high-frequency signal with reduced transmission loss by shortening the signal transmission path.

  Since the connector 10 has the wall portion 36 at the position where the second insulator 30 faces the second base portion 55, the contact between the pair of contacts 50 symmetrically arranged in the front-rear direction in FIG. 7 can be suppressed. As described above, the second base portion 55 connecting the second elastic portion 54C and the third elastic portion 56 is, for example, in the front-rear direction in FIG. 7 with the elastic deformation of the second elastic portion 54C and the third elastic portion 56. Move along. At this time, if the wall portion 36 is not formed on the second insulator 30, the second base portions 55 of the pair of front and rear contacts 50 may be in contact with each other depending on the respective elastic deformation states. The connector 10 suppresses such contact between the second base portions 55 by the formation of the wall portion 36, and can suppress a problem caused electrically such as a short circuit and a problem caused mechanically such as breakage. In other words, the connector 10 can restrict excessive elastic deformation of the third elastic portion 56 by forming the wall portion 36. The connector 10 can ensure the reliability as a product even in a situation where the second base portion 55 moves with the elastic deformation of the second elastic portion 54C and the third elastic portion 56.

  In the connector 10, the first adjustment portion 54B1 protrudes one step outside the second adjustment portion 54B2 along the front-rear direction, and the third adjustment portion 54B3 protrudes one step inside the second adjustment portion 54B2 along the front-rear direction. . According to such a forming method, as shown in FIGS. 14 and 15, even when the contact 50 is elastically deformed, both the first adjusting portion 54B1 and the third adjusting portion 54B3 do not include the other portions of the contact 50 and It does not contact the second insulator 30. Therefore, the connector 10 realizes the smooth movement of the second insulator 30 without the projecting portions of the first adjusting portion 54B1 and the third adjusting portion 54B3 hindering the elastic deformation of the contact 50, and has a favorable floating structure. Can contribute to

  In the connector 10, the required amount of movement of the adjusting portion 54B can be secured by the first elastic portion 54A and the second elastic portion 54C extending from both ends in the fitting direction in the adjusting portion 54B. Therefore, the connector 10 can secure a required movement amount of the second insulator 30. Since the connector 10 has the first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C integrally formed in a substantially crank shape, the connector 10 can achieve the above-described effect and also reduce the front-rear length in FIG. Can contribute. For example, the first elastic portion 54A extends from the inner edge of the upper edge of the adjusting portion 54B, and the second elastic portion 54C extends from the outer edge of the lower edge of the adjusting portion 54B. As a result, the front-back length of the entire connector 10 is reduced. Furthermore, the elastically deformable portions of the first elastic portion 54A and the second elastic portion 54C can be lengthened in a limited area in the first insulator 20, and a good floating structure can be obtained.

  Since the first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C are arranged in this order from the fitting side along the fitting direction, the second base portion 55 connected to the second elastic portion 54C is located at the lowest position. It is located below. Thereby, the third elastic portion 56 extends, and can be elastically deformed to a greater extent. As a result, the amount of movement of the second insulator 30 with respect to the first insulator 20 increases.

  In the connector 10, since the contact 50 further has the cutout portion 57, when the second insulator 30 moves, the force applied to the locking portion 58 that comes into contact with the inner wall of the second insulator 30 can be suppressed. Similarly, the connector 10 can suppress the force applied to the elastic contact portion 59 located above the contact mounting groove 35. That is, the connector 10 can bend the third elastic portion 56 below the vicinity of the cutout portion 57. More specifically, in the connector 10, in the third elastic portion 56, the lower half portion has a larger amount of elastic deformation than the upper half portion from the lower end portion of the locking portion 58 to the vicinity of the cutout portion 57. . As described above, in a state where the locking of the locking portion 58 to the second insulator 30 and the contact of the elastic contact portion 59 to the contact portion 92 are stable, the third elastic portion 56 is moved by the movement of the second insulator 30 to the first insulator 20. Can contribute.

  Since the contact 50 is formed of a metal material having a small elastic coefficient, the connector 10 can secure a required movement amount of the second insulator 30 even when the force applied to the second insulator 30 is small. . That is, the second insulator 30 can move smoothly with respect to the first insulator 20. Thereby, the connector 10 can easily absorb a positional shift when the connector 10 is fitted to the connection object 60. In the connector 10, each elastic portion of the contact 50 absorbs vibration generated by some external factor. Thereby, since a large force is not applied to the mounting portion 53, the connector 10 can prevent the connection portion with the circuit board CB1 from being damaged. Therefore, even when the connector 10 is connected to the connection target 60, the connection reliability can be maintained.

  Since the connector 10 has the second base portion 55 in which the contact 50 is formed wide, the assemblability of a product can be improved. That is, since the second base portion 55 is formed wide, the rigidity of the portion is increased. Thus, the contact 50 is stably inserted from below the first insulator 20 and the second insulator 30 by the assembling device or the like with the second base 55 as a fulcrum.

  By fitting the fitting 40 into the first insulator 20 and soldering the mounting portion 41 to the circuit board CB1, the fitting 40 can stably fix the first insulator 20 to the circuit board CB1. That is, the mounting strength of the first insulator 20 to the circuit board CB1 is improved by the metal fitting 40.

  It will be apparent to one skilled in the art that the present invention may be embodied in other predetermined forms than those described above without departing from its spirit or essential characteristics. Accordingly, the foregoing description is by way of example and not limitation. The scope of the invention is not defined by the foregoing description, but by the appended claims. Some of the changes that come within their equivalents are intended to be embraced therein.

  For example, the shape, arrangement, number, and the like of each of the components described above are not limited to the contents described above and illustrated in the drawings. The shape, arrangement, number and the like of each component may be arbitrarily configured as long as the function can be realized. The method of assembling the connector 10 and the connection target 60 described above is not limited to the above description. The method of assembling the connector 10 and the connection target 60 may be any method as long as it can be assembled so that the respective functions are exhibited. For example, the metal fitting 40 or the contact 50 may be formed integrally with the first insulator 20 or the second insulator 30 by insert molding instead of press fitting.

  The connector 10 has been described as a connector having a floating structure, but is not limited to this. The connector 10 may be any connector to which the contact 50 having the above-described configuration is attached. In this case, the connector 10 may include only one insulator. For example, the insulator supports the first base 51 of the contact 50 and fits with the connection target 60.

  In the adjustment unit 54B, the width of the transmission path, that is, the cross-sectional area of the transmission path is increased and the impedance is reduced, and the electrical conductivity is improved. However, the configuration of the adjustment unit 54B that improves the electrical conductivity is as follows. It is not limited to. Adjustment unit 54B may have any configuration that improves electrical conductivity. For example, the adjusting portion 54B may be formed thicker than the first elastic portion 54A while keeping the same width. For example, the adjustment portion 54B may be formed of a material having higher electrical conductivity than the first elastic portion 54A while keeping the same cross-sectional area. For example, the adjusting section 54B may have plating on the surface to improve the electrical conductivity while maintaining the same cross-sectional area as the first elastic section 54A.

  The adjustment unit 54B has been described as adjusting the electrical conductivity by changing the cross-sectional areas of the first adjustment unit 54B1, the second adjustment unit 54B2, and the third adjustment unit 54B3 in order from the fitting side. Is not limited to this. The adjusting portion 54B may have an arbitrary configuration including components having high, low, and high electrical conductivity in order from the fitted side. For example, in the adjustment unit 54B, as described above, the electrical conductivity may be adjusted by changing at least one of the width, the thickness, the cross-sectional area, the material, and the type of plating.

  FIG. 16A is a schematic diagram illustrating a first example of the shape of the adjustment unit 54B of the contact 50. FIG. 16B is a schematic diagram illustrating a second example of the shape of the adjustment unit 54B of the contact 50. FIG. 16C is a schematic diagram illustrating a third example of the shape of the adjustment unit 54B of the contact 50. FIG. 16D is a schematic diagram illustrating a fourth example of the shape of the adjustment unit 54B of the contact 50.

  The shape of the adjusting section 54B is not limited to the shape as shown in FIG. The adjustment unit 54B may have any shape that can realize the above-described functions. For example, the adjusting section 54B may have a shape as shown in FIGS. 16A to 16D. Referring to FIG. 16A, in the adjusting unit 54B, the first adjusting unit 54B1 projects upward from the second adjusting unit 54B2, and the third adjusting unit 54B3 projects downward from the second adjusting unit 54B2. Referring to FIG. 16B, in the adjustment unit 54B, the first adjustment unit 54B1 protrudes upward from the second adjustment unit 54B2, and protrudes one step outside of the second adjustment unit 54B2 along the front-rear direction. The third adjusting portion 54B3 protrudes downward from the second adjusting portion 54B2, and protrudes one step inward from the second adjusting portion 54B2 along the front-rear direction. Referring to FIG. 16C, the adjustment portion 54B is formed in a rectangular shape as a whole, and has an opening at the center thereof. Referring to FIG. 16D, the adjusting section 54B is formed so as to be tapered from the first adjusting section 54B1 to the second adjusting section 54B2, and to be tapered from the second adjusting section 54B2 to the third adjusting section 54B3. ing.

  The adjusting portion 54B extends in the fitting direction with the connection target 60 in a state where the first elastic portion 54A and the second elastic portion 54C are not elastically deformed, and the first elastic portion 54A and the second elastic portion 54C are 54B, it has been described as extending from both ends in the fitting direction. The present invention is not limited to this, and the overall shape of the first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C can contribute to the downsizing of the connector 10 while securing the required amount of movement of the second insulator 30. , Any shape may be used. For example, the adjusting portion 54B may extend in a state shifted from the fitting direction. For example, the first elastic portion 54A and the second elastic portion 54C may extend from both ends in the front-rear direction of FIG. 7 in the adjusting portion 54B. For example, the shapes of the first elastic portion 54A and the second elastic portion 54C may be arbitrary, and each may have more bent portions. For example, the overall shape of the first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C may be substantially U-shaped instead of substantially crank-shaped.

  As illustrated in FIG. 8, the first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C have been described as being sequentially arranged from the fitting side along the fitting direction, but the present invention is not limited to this. The first elastic portion 54A, the adjusting portion 54B, and the second elastic portion 54C are arranged in order from the opposite side as long as the necessary amount of movement of the second insulator 30 can be secured and the connector 10 can be reduced in size. May be done.

  Although the first elastic portion 54A and the second elastic portion 54C have been described as being formed narrower than the first base portion 51, the present invention is not limited to this. The first elastic portion 54A and the second elastic portion 54C may have any configuration that can secure a required amount of elastic deformation. For example, the first elastic portion 54A or the second elastic portion 54C may be formed of a metal material having a smaller elastic coefficient than other portions of the contact 50.

  The connector 10 does not need to have the second elastic portion 54C and the third elastic portion 56 as long as the connector 10 can contribute to the miniaturization of the connector 10 while securing the required movement amount of the second insulator 30. .

  Although the second base portion 55 has been described as being formed wider than the second elastic portion 54C, the present invention is not limited to this. The second base 55 may not be wide as long as the assemblability of the connector 10 can be maintained. The wall portion 36 has been described as extending downward from the bottom surface of the fitting concave portion 33, but is not limited to this. The wall portion 36 may be formed only at a position facing the second base portion 55, for example, as long as the contact between the pair of contacts 50 can be suppressed.

  The connector 10 does not have the cutout portion 57 if the third elastic portion 56 can contribute to the movement of the second insulator 30 in a state where the engagement of the engagement portion 58 and the contact of the elastic contact portion 59 are stable. Is also good.

  Although the contact 50 has been described as being formed of a metal material having a small elastic coefficient, it is not limited to this. The contact 50 may be formed of a metal material having an arbitrary elastic coefficient as long as the required amount of elastic deformation can be secured.

  The connection target 60 is described as a plug connector connected to the circuit board CB2, but is not limited to this. The connection object 60 may be any object other than the connector. For example, the connection target 60 may be an FPC, a flexible flat cable (FFC), a rigid board, or the like.

  The connector 10 as described above is mounted on an electronic device. The electronic device includes, for example, any on-vehicle device such as a camera, a radar, a drive recorder, or an engine control unit. The electronic device includes, for example, any vehicle-mounted device used in a vehicle-mounted system such as a car navigation system, an advanced driving assistance system, or a security system. The electronic device includes, for example, any information device such as a personal computer, a copier, a printer, a facsimile, or a multifunction peripheral. In addition, the electronic devices include any industrial devices.

  Such an electronic device has good transmission characteristics in signal transmission. Since the misalignment between the substrates is absorbed by the favorable floating structure of the connector 10, workability in assembling the electronic device is improved. That is, the manufacture of the electronic device becomes easy. Since the connector 10 suppresses the breakage of the connection portion with the circuit board CB1, the reliability of the electronic device as a product is improved.

10 connector 20 1st insulator (insulator)
21A, 21B Opening 22 Outer peripheral wall 23 Metal fitting mounting groove 24 Contact mounting groove 30 Second insulator (insulator)
31 bottom part 32 fitting convex part 33 fitting concave part 34 guiding part 35 contact mounting groove 36 wall part 40 fitting 41 mounting part 42 continuous part 43 retaining part 44 locking part 50, 50A, 50B contact 51 first base part 52 locking part 53 Mounting part 54A First elastic part 54B Adjusting part 54B1 First adjusting part 54B2 Second adjusting part 54B3 Third adjusting part 54C Second elastic part 55 Second base 56 Third elastic part 57 Notch 58 Lock part 59 Elastic contact Part (contact part)
Reference Signs List 60 Connection target 70 Insulator 71 Fitting concave portion 72 Fitting convex portion 73 Attracting portion 74 Fitting mounting groove 75 Contact mounting groove 80 Fitting 81 Mounting portion 82 Locking portion 90 Contact 91 Mounting portion 92 Contact portion CB1, CB2 Circuit board

Claims (9)

A first insulator formed in a frame shape,
A second insulator that is disposed inside the first insulator, is relatively movable with respect to the first insulator, and fits with a connection target;
A contact having a first base disposed along the first insulator and a second base disposed along the second insulator;
With
The contact includes a first elastic portion that can be elastically deformed, an adjusting portion, and a second elastic portion that can be elastically deformed between the first base portion and the second base portion,
The first elastic portion extends from the first base toward the second insulator,
A first adjusting portion connected to the first elastic portion, the first adjusting portion being arranged in order from a fitting side along a fitting direction of the second insulator and the object to be connected , the first adjusting portion; A second adjustment unit connected to the second adjustment unit , and a third adjustment unit connected to the second adjustment unit .
The first adjusting portion is wider in the extending direction of the first elastic portion than the width of the first elastic portion in the fitting direction and the width of the second elastic portion in the fitting direction, and Projecting toward the first base portion from the second adjustment portion along an extending direction;
The third adjusting portion is wider in the extending direction of the first elastic portion than the width of the first elastic portion in the fitting direction and the width of the second elastic portion in the fitting direction, and Projecting toward the second base portion from the second adjusting portion along an extending direction;
The second elastic portion extends in the extending direction from the third adjusting portion to the second insulator.
connector. The first elastic portion, the adjusting portion, and the second elastic portion are sequentially formed from a fitting side along the fitting direction,
The connector according to claim 1. Before the second adjusting portion SL is Ru narrow der in the extending direction from the first adjuster and the third adjuster,
The connector according to claim 1. The contact further includes a third elastic portion that is arranged along an inner wall of the second insulator and extends in the fitting direction and is elastically deformable.
Connector according to any one of claims 1 to 3. The second base connects the second elastic portion and the third elastic portion,
The connector according to claim 4 . In a fitting state in which the second insulator and the connection target are fitted, the electronic device further includes a contact portion that is in electrical contact with the connection target,
The contact portion is formed at an end of a portion continuous from the third elastic portion in the fitting direction.
The connector according to claim 4 . The second insulator includes a wall formed at a position facing the second base.
The connector according to any one of claims 1 to 6 . The contact is orthogonal to the fitting direction and the extending direction, and is formed to be flat in a thickness direction of the contact.
Connector according to any one of claims 1 to 7. Electronic apparatus including the connector according to any one of claims 1 to 8.

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