This application is based on and incorporates herein by reference Japanese Patent Application No. 2009-173419 filed on Jul. 24, 2009.
The present invention relates to a card edge connector and a method of manufacturing the card edge connector.
JP-U-6-86366 discloses a card edge connector in which connector terminals are located at different position's in a direction perpendicular to a surface of a board. The board is a multilayer board in which multiple substrates are stacked on top of each other. An end portion of an inner substrate of the multilayer board extends beyond an end portion of an outermost substrate of the multilayer board. Multiple terminals are arranged in each of the end portions of the inner substrate and the outermost substrate. Thus, a step having a height corresponding to a thickness of one substrate is formed between an inner card edge portion provided by the end portion of the inner substrate and an outer card edge portion provided by the end portion of the outermost card edge. The step allows the terminals to be located at different positions in the direction perpendicular to the surface of the board.
According to the card edge connector disclosed in JP-U-6-86366, the height of the step depends on the thickness of one substrate. Therefore, the height of the step may be small. In such a case, since the terminals on the inner substrate are located close to the terminals on the outermost substrate, a short-circuit may occur.
U.S. Pat. No. 7,628,654, corresponding to JP-A-2009-176625, filed by the present inventors, discloses a card edge connector in which terminals are suitably spaced in a direction vertical to a surface of an electronic board. The card edge connector disclosed in U.S. Pat. No. 7,628,654 includes a housing, a first conductive part, a second conductive part, a supporting conductive part, and a connecting element. The housing has an insertion hole for receiving an end portion of the electronic substrate therein. The electronic substrate includes a first terminal and a second terminal disposed on a surface of the end portion. The first terminal is located in front of the second terminal in an insertion direction in which the end portion of the electronic substrate is inserted into the housing. The first conductive part is disposed in the insertion hole and is configured to come in contact with the first terminal when the end portion of the electronic substrate is received by the housing. The second conductive part is disposed in the insertion hole and is configured to come in contact with the second terminal when the electronic substrate is received by the housing. The first conductive part is located at a first distance from the surface of the electronic substrate in a direction approximately vertical to the planer direction of the electronic substrate when the electronic substrate is received by the housing. The supporting conductive part is disposed in the housing and is located at a second distance from the surface of the electronic substrate in the direction approximately vertical to the planer direction of the electronic substrate when the end portion of the electronic substrate is received by the housing. The second distance is larger than the first distance. The connecting element couples the second conductive part and the supporting conductive part.
Since the second distance is larger than the first distance, the first conductive part and the supporting conductive part are suitably spaced in the direction vertical to the surface of the electronic substrate.
However, the first conductive part and the supporting conductive part have different structures, and accordingly, manufacturing cost may be increased.
In view of the above, it is an object of the present invention to provide a card edge connector manufacturable at low cost. It is another object of the present invention is to provide a method of manufacturing the card edge connector.
According to a first aspect of the present invention, a card edge connector adapted to receive an electronic substrate includes a housing, harness terminals, relay terminals, and harnesses. Contact electrodes are formed on a surface of an end portion of the electronic substrate. The contact electrodes include a first contact electrode and a second contact electrode. The first contact electrode is located in front of the second contact electrode in an insertion direction in which the end portion of the electronic substrate is adapted to be inserted into the card edge connector. The housing defines an substrate insertion hole for receiving the end portion of the electronic substrate. The harness terminals are located in the housing and include a first harness terminal and a second harness terminal. The first harness terminal is located in a first distance from the surface of the end portion of the electronic substrate in a height direction perpendicular to the surface after insertion of the end portion into the substrate insertion hole. The second harness terminal is located in a second distance from the surface of the end portion in the height direction after insertion of the end portion into the substrate insertion hole, the second distance greater than the first distance. The relay terminals located in the housing. Each relay terminal has a first end in contact with a corresponding harness terminal and a second end in contact with a corresponding contact electrode after insertion of the end portion into the substrate insertion hole. The relay terminals include a first relay terminal and a second relay terminal. The first relay terminal electrically connects the first harness terminal to one of the first contact electrode and the second contact electrode after insertion of the end portion into the substrate insertion hole. The second relay terminal electrically connects the second harness terminal to the other of the first contact electrode and the second contact electrode after insertion of the end portion into the substrate insertion hole. Each harness has a first end connected to a corresponding harness terminal and a second end exposed outside the housing. The harnesses include a first harness connected to the first harness terminal and a second harness connected to the second harness terminal.
According to a second aspect of the present invention, a method of manufacturing the card edge connector includes preparing the housing. The housing is formed by resin injection molding so as to have the substrate insertion hole on a housing surface, harness terminal holes, and relay terminal holes. Each relay terminal hole extends from the housing surface to a corresponding harness terminal hole. The method further includes inserting the first end of each relay terminal into a corresponding relay terminal hole in such a manner that the first end of each relay terminal is partially located in the corresponding harness terminal, a middle part between the first end and the second end of each relay terminal is located on the housing surface, and the second end of each relay terminal projects into the substrate insertion hole. The method further includes inserting each harness terminal into the corresponding harness terminal hole.
According to a third aspect of the present invention, a method of manufacturing the card edge connector includes preparing the housing. The housing is formed by resin injection molding so as to have the substrate insertion hole, harness terminal holes, and the relay terminals that are insert-molded. The method further includes inserting each harness terminal into a corresponding harness terminal hole.
The above and other objectives, features and advantages of the present invention will become more apparent from the following detailed description made with check to the accompanying drawings. In the drawings:
Embodiments of the present invention are described below with reference to the drawings.
(First Embodiment)
A card edge connector 100 according to a first embodiment of the present invention is described below with reference to
The harness 10 includes a metal wire 11 and a cover 12 for covering the metal wire 11. As shown in
The terminal 13 has a first terminal 13a and a second terminal 13b. The first terminal 13a is located at a first distance from a front surface 30a (or a back surface 30b) of the electronic substrate 30 in a height direction. The second terminal 13b is located at a second distance from the front surface 30a (or the back surface 30b) of the electronic substrate 30 in the height direction. The second distance is greater than the first distance so that the second terminal 13b can be located farther away from the front surface 30a (or the back surface 30b) of the electronic substrate 30 than the first terminal 13a in the height direction. Each of the first terminal 13a and the second terminal 13b is configured as a female terminal and includes a crimp portion 14, a tubular body (i.e., sleeve) portion 15 extending from the crimp portion 14, and a contact portion 16 located inside the body portion 15. The crimp portion 14 is crimped so that the crimp portion 14 can be joined to the cover 12 of the harness 10. The contact portion 16 is elastically deformable. When the relay terminal 58 is inserted in the body portion 15, the contact portion 16 is elastically deformed and comes in contact with the relay terminal 58 at a predetermined contact pressure so that the contact portion 16 and the relay terminal 58 can be electrically connected together. Further, the body portion 15 is crimped so that the body portion 15 can be electrically and mechanically connected to the metal wire 11 of the harness 10.
The electronic substrate 30 includes electronic devices (not shown) and a pattern of conductive traces (not shown) electrically connected to the electronic devices. As shown in
Multiple first contact electrodes 32a are arranged on both of the front and back surfaces 30a, 30b of the electronic substrate 30 at predetermined intervals in a lateral direction perpendicular to the insertion direction. Likewise, multiple second contact electrodes 32b are arranged on both of the front and back surfaces 30a, 30b of the electronic substrate 30 at substantially the same intervals as the first contact electrodes 32a in the lateral direction. Thus, the first contact electrode 32a and the second contact electrode 32b are aligned with each other in the insertion direction. Further, the first contact electrode 32a on the front surface 30a is located directly opposite the first contact electrode 32a on the back surface 30b across the electrode substrate 30. Likewise, the second contact electrode 32b on the front surface 30a is located directly opposite the second contact electrode 32b on the back surface 30b across the electronic substrate 30. That is, the contact electrode 32 on one surface of the electrode substrate 30 is located directly below or above the contact electrode 32 on the other surface of the electronic substrate 30 in the height direction.
The housing 50 electrically connects the terminal 13 and the contact electrode 32 through the relay terminal 58 while holding the harness 10 and the electronic substrate 30. The housing 50 is formed by resin injection molding. The housing 50 has a substrate insertion hole 51 for receiving the electronic substrate 30 and a terminal insertion hole 52 for receiving the terminal 13 of the harness 10. The relay terminal 58 for electrically connecting the terminal 13 and the contact electrode 32 is formed to the housing 50 in such a manner that a first end of the relay terminal 58 projects into the substrate insertion hole 51 and that a second end of the relay terminal 58 projects into the terminal insertion hole 52.
As shown in
The first and second inner walls 53a, 53b are connected together through a first housing surface 54a of the housing 50. The first housing surface 54a is substantially perpendicular to the insertion direction and recessed in the insertion direction to form the first insertion hole 51a. The first inner wall 53a and the first housing surface 54a form a corner portion 55a. As described later, the corner portion 55a comes in contact with a joint portion between a connecting portion 60 and an electrode contact portion 61 of a first relay terminal 58a.
A second housing surface 54b of the housing 50 is connected to the second inner wall 53b. The second housing surface 54b is substantially perpendicular to the insertion direction and recessed in the insertion direction to form the second insertion hole 51b. The second inner wall 53b and the second housing surface 54b form a corner portion 55b. As described later, the corner portion 55b comes in contact with a joint portion between a connecting portion 60 and an electrode contact portion 61 of a second relay terminal 58b.
A distance between the front surface 30a of the electronic substrate 30 and the top surface of the first inner wall 53a is equal to a distance between the back surface 30b of the electronic substrate 30 and the bottom surface of the first inner wall 53a. Likewise, a distance between the front surface 30a of the electronic substrate 30 and the top surface of the second inner wall 53b is equal to a distance between the back surface 30b of the electronic substrate 30 and the bottom surface of the second inner wall 53b. The second inner wall 53b and the first housing surface 54a form a substantially right-angle corner.
As shown in
The relay terminal 58 can be formed by stamping and bending a metal sheet or plate. The relay terminal 58 includes the first relay terminal 58a and the second relay terminal 58b. The first relay terminal 58a is configured to electrically connect the first terminal 13a to the first contact electrodes 32a on both surfaces 30a, 30b of the electronic substrate 30. The second relay terminal 58b is configured to electrically connect the second terminal 13b to the second contact electrodes 32b on both surfaces 30a, 30b of the electronic substrate 30.
Each of the first relay terminal 58a and the second relay terminal 58b includes a terminal contact portion 59, a connecting portion 60, and an electrode contact portion 61.
In the first relay terminal 58a, the terminal contact portion 59 extends through the housing 50 from the first terminal 13a (i.e., first terminal insertion hole 52a) to the first housing surface 54a and is joined to the connecting portion 60. The connecting portion 60 extends to the corner portion 55a along the first housing surface 54a and is joined to the electrode contact portion 61. The electrode contact portion 61 projects into the first insertion hole 51a.
In the second relay terminal 58b, the terminal contact portion 59 extends through the housing 50 from the second terminal 13b (i.e., second terminal insertion hole 52b) to the second housing surface 54b and is joined to the connecting portion 60. The connecting portion 60 extends to the corner portion 55b along the second housing surface 54b and is joined to the electrode contact portion 61. The electrode contact portion 61 projects into the second insertion hole 51b.
As can be seen from
The connecting portion 60 and the electrode contact portion 61 are joined together at an obtuse angle so as to form a V-shape with an obtuse angle. An end of the electrode contact portion 61 of the first relay terminal 58a projecting into the first insertion hole 51a is electrically connected to the first contact electrode 32a by coming in contact with the first contact electrode 32a. An end of the electrode contact portion 61 of the second relay terminal 58b projecting into the second insertion hole 51b is electrically connected to the second contact electrode 32b by coming in contact with the second contact electrode 32b.
When the electronic substrate 30 is inserted into the substrate insertion hole 51 of the housing 50, the electrode contact portion 61 is pressed by the electronic substrate 30 so that the obtuse angle between the connecting portion 60 and the electrode contact portion 61 approaches a right angle. Further, the electrode contact portion 61 is elastically deformed due to the pressure from the electronic substrate 30 so that the electrode contact portion 61 can remain in contact with the contact electrode 32 at a predetermined contact pressure. As shown in
As shown in
As shown in
In contrast, according to the first embodiment, the fulcrum, with which the electrode contact portion 61 is deformed, can be fixed at the contact point between the projection 63 and the straight part of the electrode contact portion 61. Thus, the angle of the junction between the connecting portion 60 and the electrode contact portion 61 can be kept constant so that the contact pressure, at which the electrode contact portion 61 is in contact with the contact electrode 32, can be kept constant.
The casing 70 has a hollow box shape with an opening and a bottom. Guide slots (not shown) for guiding and the electronic substrate 30 to a predetermined position in the casing 70 are formed on an inner side surface and an inner bottom surface of the casing 70. Further, a supporting portion (not shown) for supporting the electronic substrate 30 is formed on the bottom surface of the casing 70. The electronic substrate 30 is inserted in the casing 70 from the opening along the guiding slots so that the electronic substrate 30 can be supported by the casing 70. When the housing 50 is inserted in the casing 70, the housing 50 is fitted with the casing 70 so that the electronic substrate 30 can be sealed in a space defined by the housing 50 and the casing 70.
When the card edge connector 100 is used in a vehicle, it is preferable that the card edge connector 100 should have a waterproof structure that prevents water from entering the card edge connector 100. For this reason, according to the first embodiment, the card edge connector 100 is waterproofed by the sealing member 64 that seals the clearance between the harness 10 and the housing 50. As shown in
Next, a method of manufacturing the card edge connector 100 according to the first embodiment is described below with reference to
As shown in
After the press-fitting process is finished, a removing process is performed to remove the tab 68.
After the removing process is finished, a first insertion process is performed to insert the terminal 13 connected to the harness 10 into the terminal insertion hole 52 through the sealing member 64. Specifically, in the first insertion process, the entire terminal 13 passes through the through hole of the sealing member 64 so that the sealing member 64 can be located around the harness 10. Thus, the clearance between the harness 10 and the housing 50 can be sealed by the sealing member 64. It is noted that a tip surface of the body portion 15 of the terminal 13 has an opening. Therefore, when the terminal 13 is completely inserted into the terminal insertion hole 52, the end of the terminal contact portion 59 of the relay terminal 58 attached to the housing 50 is inserted into the body portion 15 of the terminal 13 through the opening so that the terminal contact portion 59 can come in contact with the contact portion 16 that is located inside the body portion 15.
After the first insertion process is finished, a second insertion process is performed to insert the electronic substrate 30 into the substrate insertion hole 51. Specifically, in the second insertion process, the electronic substrate 30 is inserted into the substrate insertion hole 51 against elastic force from the relay terminal 58 (i.e., electrode contact portion 61). As a result, the electronic substrate 30 is sandwiched between the relay terminal 58 in contact with the contact electrode 32 on the front surface 30a and the relay terminal 58 in contact with the contact electrode 32 on the back surface 30b, so that the electronic substrate 30 can be held in the substrate insertion hole 51. Along with insertion of the electronic substrate 30 into the substrate insertion hole 51, the housing 50 is inserted into and fitted with the casing 70 so that the ring-shaped sealing member 65 can be located between the housing 50 and the casing 70. Thus, the space, where the electronic substrate 30 is located, is hermetically sealed by the housing 50, the casing 70, and the ring-shaped sealing member 65.
In this way, the card edge connector 100 according to the first embodiment is manufactured by performing the press-fitting process, the removing process, the first insertion process, and the second insertion process.
In the above-described method, the relay terminal 80 is attached to the housing 50 by the press-fitting process, in which the terminal contact portion 59 is press-fitted into the narrow hole 66. Alternatively, the relay terminal 58 can be attached to the housing 50 by insert molding. In such an approach, the press-fitting process and the removing process are omitted so that the manufacturing processes of the card edge connector 100 can be simplified. Even when the relay terminal 58 is attached to the housing 50 by insert molding, it is preferable that the terminal contact portion 59 have the tapered barb 67 to reinforce the attachment of the relay terminal 58 to the housing 50.
In the above-described method, the removing process is performed after the press-fitting process. Alternatively, the removing process can be performed after the first insertion process.
In the above-described method, the second insertion process is performed after the first insertion process. Alternatively, the second insertion process can be performed before the first insertion process.
As described above, according to the first embodiment, the terminal 13 has the first terminal 13a and the second terminal 13b that is located farther away from the electronic substrate 30 than the first terminal 13a in the height direction. Further, the contact electrode 32 has the first contact electrode 32a and the second contact electrode 32b that is located farther away from the tip of the end portion 31 of the electronic substrate 30 than the first contact electrode 32a in the insertion direction. In this way, according to the card edge connector 100, the first terminal 13a and the second terminal 13b are located at different positions in the height direction to form enough clearance to prevent a short-circuit.
Each of the first terminal 13a and the second terminal 13b has the same structure and is configured as a female terminal. The first and second terminals 13a, 13b are electrically connected to the first and second contact electrodes 32a, 32b through the relay terminals 58a, 58b, respectively, after insertion of the electronic substrate 30 into the substrate insertion hole 51 of the housing 50. Since the terminal 13 has the same structure, manufacturing cost of the terminal 13 can be reduced. Further, since the terminal 13 has the same structure, each harness 10 has the same structure so that manufacturing cost of the harness 10 can be reduced. Thus, manufacturing cost of the card edge connector 100 as a whole can be reduced.
The terminal 13 is configured as a female terminal in which the contact portion 16 is located in the body portion 15. Since the contact portion 16 is located in the body portion 15, the terminal 13 can be easily inserted into the terminal insertion hole 52.
The contact electrode 32 is formed on both surfaces 30a, 30b of the electronic substrate 30. In such an approach, the number of signal lines of the card edge connector 100 can be increased.
The contact electrode 32 has the rectangular shape with the long side in the insertion direction. In such an approach, the contact area between the contact electrode 32 and the relay terminal 58 is increased in the insertion direction so that electrical connection between the contact electrode 32 and the relay terminal 58 can be ensured.
(Second Embodiment)
A card edge connector 100 according to the second embodiment of the present invention is described below with reference to
Referring back to
Further, according to the second embodiment, as shown in
Like the first embodiment, the first contact electrode 32a on the front surface 30a is located directly opposite the first contact electrode 32a on the back surface 30b across the electrode substrate 30, and the second contact electrode 32b on the front surface 30a is located directly opposite the second contact electrode 32b on the back surface 30b across the electronic substrate 30.
An advantage of the second embodiment is discussed below.
Assuming that the first contact electrode 32a and the second contact electrode 32b are aligned with each other in the insertion direction and that the first relay terminal 58a and the second relay terminal 58b are aligned with each other in the insertion direction, the second relay terminal 58b may be temporarily electrically connected to the first contact electrode 32a during insertion of the electronic substrate 30 into the substrate insertion hole 51. As a result, an electric current may flow accidentally.
As described above, according to the second embodiment, the first contact electrode 32a and the second contact electrode 32b are located in different positions in the lateral direction not to be aligned with each other in the insertion direction. Further, the first relay terminal 58a and the second relay terminal 58b are alternately arranged at predetermined intervals in the lateral direction in such a manner that the first relay terminal 58a and the second relay terminal 58b can come in contact with the first contact electrode 32a and the second contact electrode 32b, respectively. Therefore, it is less likely that the second relay terminal 58b will be temporarily electrically connected to the first contact electrode 32a during insertion of the electronic substrate 30 into the substrate insertion hole 51. Thus, accidental current flow can be prevented. Details are described below.
For example, assuming that the card edge connector 100 according to the second embodiment is used in a vehicle and that the casing 70 having the electronic substrate 30 is configured as an electronic control unit (ECU), the electronic substrate 30 is electrically connected through the harness 10 to other devices (e.g., battery and another ECU) mounted on the vehicle. In such a case, when the ECU is replaced with new one, a worker (e.g., repair man at a car dealer) may detach the electronic substrate 30 from the housing 50 under a condition that the harness 10 remains electrically connected to a battery of the vehicle. Further, an ECU used in a vehicle generally has a backup power source such as a capacitor. Therefore, the electronic substrate 30 may be detached from the housing 50 under a condition that power supply is continued by the battery or the backup power source. According to the second embodiment, he first contact electrode 32a and the second contact electrode 32b are located in different positions in the lateral direction not to be aligned with each other in the insertion direction. Therefore, even if the electronic substrate 30 is detached from the housing 50 under the condition that power supply is continued, accidental current flow can be prevented during insertion of the electronic substrate 30 into the substrate insertion hole 51.
Assuming that the first terminals 13a (or the second terminals 13b), which are located in the same position in the height direction and arranged in the lateral direction, the lengths of the housing 50 and the electronic substrate 30 in the lateral direction needs to be increased so that adjacent first terminals 13a (or adjacent second terminals 13b) can be spaced from each other in the lateral direction by enough distance to prevent adjacent first relay terminals 58a (or adjacent second relay terminals 58b) from coming in contact with each other and to prevent the first relay terminal 58a (or the second relay terminal 58b) from coming in contact with a non-corresponding first contact electrode 32a (or a non-corresponding second relay terminal 58b). In this case, the size of the housing 50 in the lateral direction needs to be increased in order to keep the number of necessary terminals 13.
According to the second embodiment, the first and second terminals 13a, 13b are located in different positions in the height direction and alternately arranged in the lateral direction in the housing 50. Therefore, the first and second relay terminals 58a, 58b are located in different positions in the height direction and alternately arranged in the lateral direction in the housing 50. In such an approach, even when the distance between adjacent first and second terminals 13a, 13b in the lateral direction is small, it is less likely that adjacent first and second relay terminals 58a, 58b will come in contact with each other and the relay terminal 58 will come in contact with a non-corresponding contact electrode 32. Thus, the number of necessary terminals 13 can be kept without increasing the size of the housing 50.
According to the second embodiment, as shown in
In the modification shown in
As described above, according to the modification of the second embodiment, the contact electrode 32 further has the third contact electrode 32c in addition to the first contact electrode 32a and the second contact electrode 32b. In such an approach, the number of signal lines of the card edge connector 100 can be increased.
(Third Embodiment)
A card edge connector 100 according to the third embodiment of the present invention is described below with reference to
A difference of the third embodiment from the preceding embodiments is as follows.
In the first embodiment, the first contact electrode 32a on the front surface 30a is located directly opposite the first contact electrode 32a on the back surface 30b across the electrode substrate 30, and the second contact electrode 32b on the front surface 30a is located directly opposite the second contact electrode 32b on the back surface 30b across the electronic substrate 30.
In contrast, in the third embodiment, as shown in
Further, as shown in
The electrode contact portion 61 of the first relay terminal 58a to be connected to the first contact electrode 32a on the front surface 30a and the electrode contact portion 61 of the second relay terminal 58b to be connected to the second contact electrode 32b on the back surface 30b extend over the center line CL from the front surface 30a side to the back surface 30b side so that the vertex 62 of the electrode contact portions 61 can be located below the center Line CL in the height direction. Likewise, the electrode contact portion 61 of the second relay terminal 58b to be connected to the second contact electrode 32b on the front surface 30a and the electrode contact portion 61 of the first relay terminal 58a to be connected to the first contact electrode 32a on the back surface 30b extend over the center line CL from the back surface 30b side to the front surface 30a side so that the vertex 62 of the electrode contact portions 61 can be located above the center Line CL in the height direction.
An advantage of the third embodiment with respect to the preceding embodiments is discussed below.
In the structure shown in
Further, in the structure shown in
In contrast, according to the third embodiment, as shown in
Further, according to the third embodiment, the electrode contact portion 61 of the first relay terminal 58a to be connected to the first contact electrode 32a on the front surface 30a and the electrode contact portion 61 of the second relay terminal 58b to be connected to the second contact electrode 32b on the back surface 30b extend over the center line CL from the front surface 30a side to the back surface 30b side so that the vertex 62 of the electrode contact portions 61 can be located below the center Line CL in the height direction. Likewise, the electrode contact portion 61 of the second relay terminal 58b to be connected to the second contact electrode 32b on the front surface 30a and the electrode contact portion 61 of the first relay terminal 58a to be connected to the first contact electrode 32a on the back surface 30b extends over the center line CL from the back surface 30b side to the front surface 30a side so that the vertex 62 of the electrode contact portions 61 can be located above the center Line CL in the height direction. In such an approach, since the distance for allowing the electrode contact portion 61 to be elastically deformed can be greater than half of the thickness of the electronic substrate 30, it is ensured that the electrode contact portion 61 remains in contact with the corresponding contact electrode 32 at a sufficient contact pressure.
For foregoing reasons, according to the third embodiment, a reliable electrical connection between the electrode contact portion 61 and the contact electrode 32 can be ensured.
It is noted that when the electronic substrate 30 is inserted into the substrate insertion hole 51, the electrode contact portion 61 of the second relay terminal 58b is displaced in the insertion direction. Therefore, for example, as shown in
In contrast, according to the third embodiment, as shown in
The third embodiment described above can be modified, for example, as follows. In the third embodiment, the relay terminal 58 has the first relay terminal 58a for electrically connecting the first terminal 13a to the first contact electrode 32a on each of the front surface 30a and the back surface 30b and the second relay terminal 58b for electrically connecting the second terminal 13b to the second contact electrode 32b on each of the front surface 30a and the back surface 30b. Alternatively, for example, as shown in
According to the modification shown in
Alternatively, as shown in
Further, according to the modification shown in
(Fourth Embodiment)
A card edge connector 100 according to the fourth embodiment of the present invention is described below with reference to
A difference of the fourth embodiment from the preceding embodiments is as follows.
According to the fourth embodiment, the electrode contact portion 61 of the second relay terminal 58b is bent at a first position in a first direction along the insertion direction so that the electrode contact portion 61 can extend toward the inside of the substrate insertion hole 51 and then bent at a second position in a second direction opposite to the first direction along the insertion direction so that the electrode contact portion 61 can extend toward the outside of the substrate insertion hole 51. As shown in
The following discussion relates to the contact pressure at which the electrode contact portion 61 of the relay terminal 58 remains in contact with the contact electrode 32 after insertion of the electronic substrate 30 into the housing 50. The contact pressure is in proportion to a length of an elastically-deformed part of the electrode contact portion 61 and is in inverse proportion to a stroke of the elastically-deformed part. Therefore, when the length of the elastically-deformed part of the electrode contact portion 61 is short, a change in the contact pressure with the stroke is large. In contrast, when the length of the elastically-deformed part of the electrode contact portion 61 is long, the change in the contact pressure with the stroke is small. The contact pressure needs to be kept within a predetermined range that ensures reliability of electrical connection between the contact electrode 32 and the electrode contact portion 61. Increasing the length of the elastically-deformed part of the electrode contact portion 61 may keep the contact pressure within the predetermined range while absorbing manufacturing tolerances in the electronic substrate 30, the housing 50, and the contact electrode 32. It is noted that the length of the elastically-deformed part of the electrode contact portion 61 depends on a length of the end portion 31 that is inserted in the substrate insertion hole 51. For this reason, an increase in the length of the elastically-deformed part of the electrode contact portion 61 results in increases in the length of the substrate insertion hole 51 of the housing 50 and the length of the end portion 31 of the electronic substrate 30. Therefore, at least the housing 50 is increased in size. Further, due to a small clearance between the end portion 31 and the substrate insertion hole 51 after insertion of the end portion 31 into the substrate insertion hole 51, it is difficult to mount electronic devices on the end portion 31. Therefore, in order to maintain the number of electronic devices mounted on the electronic substrate 30, the size of the electronic substrate 30 is increased by the increase in the length of the end portion 31. In summary, the increase in the length of the elastically-deformed part of the electrode contact portion 61 results in not only the increase in the size of the housing 50 but also the increase in the size of the electronic substrate 30.
Regarding the issue of the contact pressure, according to the fourth embodiment, the electrode contact portion 61 of the second relay terminal 58b is bent in the first direction along the insertion direction toward the inside of the substrate insertion hole 51 and then bent in the second direction along the insertion direction toward the outside of the substrate insertion hole 51. That is, the electrode contact portion 61 is bent twice in opposite directions along the insertion direction. In such an approach, the contact pressure can be kept within the predetermined range without increasing the length of the electrode contact portion 61. That is, the contact pressure can be kept within the predetermined range without increasing the size of the housing 50 and the electronic substrate 30.
Further, according to the fourth embodiment, as shown in
The fourth embodiment described above can be modified, for example, as follows. In the fourth embodiment, the vertex 62 of two first relay terminals 58a are located opposite each other in the height direction, and the vertex 62 of two second relay terminals 58b are located opposite each other in the height direction. Alternatively, as shown in
In the card edge connector 100 shown in
In the card edge connector 100 shown in
In
For the same reason as described above, in
The embodiments described above can be modified in various ways. For example, the electrode contact portion 61 can be bent more than twice.
Such changes and modifications are to be understood as being within the scope of the present invention as defined by the appended claims.
Number | Date | Country | Kind |
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2009-173419 | Jul 2009 | JP | national |
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Number | Date | Country | |
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20110021080 A1 | Jan 2011 | US |