JP2006164572A - I/o connector and cable provided with i/o connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an I/O connector wherein a possibility of generating deformation and breakage is small even if a plug and a receptacle are relatively pried and a plug is not inserted in a receptacle in a wrong direction. <P>SOLUTION: This I/O connector is provided with a body part, a metal shell extended from the body part, and a contact arranged to be surrounded by the shell in a electrically insulated state and extended from a body part. A sectional shape orthogonal to a direction in which the shell is extended is unsymmetrical about a straight line extended in a height direction at a center in a width direction of the shell. An angle of an upper surface and a side surface of the shell and an angle of an undersurface and the side surface of the shell are nearly right angles. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an I / O connector and a fitting shape of a cable including the I / O connector.

  As a miniUSB (universal serial bus) connector and other I / O connectors, there are a receptacle fixed to a device and a plug provided at the end of a cable and inserted and fitted into the receptacle.

In the conventional I / O connector, in order to prevent erroneous insertion of the plug and the receptacle and to securely hold the fitting, for example, on one of the resin insulator of the plug and the metal shell of the receptacle, Some have adopted a fitting shape in which a protrusion extending in the insertion direction of the plug into the receptacle is formed and a notch is formed so as to correspond to the protrusion. In this I / O connector, the plug is inserted and fitted into the receptacle while sliding the protrusion into the notch.
Also known is a structure that prevents erroneous insertion by setting the shape of the corners (four corners) of the shell or insulator.
JP-A-11-185883 JP 2002-246114 A

  However, when the notch is formed in the shell or the insulator, the rigidity of the shell or the insulator in which the notch is formed is lowered, and particularly, it is weak against the operation of relatively squeezing the plug and the receptacle. Furthermore, if the protrusion is forcibly inserted at a position where there is no notch, that is, erroneously inserted, the protrusion may be destroyed.

  In addition, when the notch is provided in the shell and the protrusion is provided in the insulator, the protrusion provided in the plug needs to be higher in order to more securely hold the plug in the receptacle. The protrusion may exceed the entire outer shape of the I / O connector so far. In such an I / O connector, when the receptacle is arranged so that the notched side is on the board side of the device, a recess is formed on the board in order to accommodate the protrusion beyond the outer shape of the I / O connector. Need to be formed.

  In particular, in a miniaturized I / O connector such as a miniUSB connector, it is difficult to accurately form notches and protrusions in consideration of the manufacturing cost and the mounting cost of the device on the board. Furthermore, when the notch is formed to be large, the rigidity is reduced, and the strength against the bending operation and the breaking strength against erroneous insertion tend to be reduced. On the other hand, if the cutout is made small, the protrusions are inevitably small, and deformation or breakage due to a bending operation or incorrect insertion is likely to occur.

  These problems are the same even in the structure that prevents erroneous insertion due to the difference in shape of the corners of the shell and insulator, and there is sufficient difference in size and shape of the part that interferes during erroneous insertion, that is, prevents erroneous insertion. Therefore, deformation and breakage are likely to occur, and in the worst case, there is a risk of being erroneously inserted. In other words, it has been difficult to obtain high strength against a bending operation and high breaking strength against erroneous insertion in a miniaturized I / O connector.

  In addition, when the connector is downsized, if the structure prevents the wrong insertion due to the difference in the shape of the corner portion of the shell or insulator, the portion that prevents the wrong insertion formed in the corner portion is made small and accurate. Must. However, in the case of a metal such as a shell, it is difficult to form a step, a bent portion, or the like small and accurately in a part that prevents erroneous insertion, for example, due to workability problems. That is, it becomes difficult to make sufficient difference in shape, and erroneous insertion occurs, and rotation or rattling tends to occur after fitting. In addition, when a resin or the like is used, there is a problem that the size of a portion for preventing erroneous insertion becomes fine, and there is a high risk of chipping or breakage when there is a twisting operation or incorrect insertion.

  In addition, due to the diversification of usage forms of electronic devices and the like in recent years, a plurality of fitting selectivities are required. That is, it is required to have a form that can accommodate a plurality of fitting shapes. However, in a miniaturized I / O connector, it is difficult to set and form a difference in form so as to prevent erroneous insertion and to be compatible with a plurality of fitting shapes. Therefore, there is also a problem that it is difficult to easily obtain a plurality of fitting selectivity.

  In order to solve the above-mentioned problem, in the I / O connector of the present invention, a main body, a metal shell extending from the main body, and an electrically insulated state are disposed so as to be surrounded by the shell. An orthogonal cross-sectional shape in the extending direction of the shell is asymmetric with respect to a straight line extending in the height direction at the center in the width direction of the shell, and an upper surface of the shell. The angle formed between the side surface and the angle formed between the lower surface of the shell and the side surface is substantially a right angle.

  It is preferable that at least one of the side surfaces at both ends in the width direction of the shell includes a curved portion and a flat portion, and the curved portion may be formed at or near the center of the side surface of the shell.

  The side surfaces of the shell are preferably asymmetric with respect to a straight line extending in the height direction at the center in the width direction of the shell.

  The upper and lower surfaces of the shell are preferably parallel to each other.

  The angle formed by the upper and lower surfaces of the shell and the side surface is preferably substantially a right angle.

  The contacts can be used for power supply only, signal transmission only, or signal transmission and power supply.

  The I / O connector includes a miniUSB connector, a receptacle provided in an electronic device or a peripheral device of an electronic device, a plug fitted to an I / O connector provided in the electronic device or a peripheral device of the electronic device, and an AC adapter. Can be used as a plug.

  The cable of the present invention is a cable having I / O connectors at both ends, and at least one I / O connector is electrically insulated from a main body portion and a metal shell extending from the main body portion. An I / O connector including a contact disposed so as to be surrounded by the shell and extending from the main body, wherein a shape in a cross section orthogonal to the extending direction of the shell extends in the height direction at the center in the width direction of the shell. It is characterized by being asymmetric with respect to a straight line.

  According to the present invention, the plug and the receptacle can be relatively moved by improving the shell shape of the plug and the receptacle without adopting the fitting shape in which the notch is provided in one of the shell of the receptacle and the insulator of the plug and the protrusion is provided on the other. It is possible to provide an I / O connector that is less likely to be deformed or damaged even if it is squeezed, and that can cope with further downsizing without inserting the plug into the receptacle in the wrong direction. Furthermore, even a miniaturized I / O connector such as a miniUSB connector can be mounted without processing a substrate on which a receptacle is mounted, and can have high strength. In addition, since a plurality of combinations of plugs or receptacles can be easily set, whether or not the plug and the receptacle can be fitted can be arbitrarily set. In addition, since the use of the corner portion of the shell is not used as to whether or not to fit, that is, whether or not to fit can be set at a portion other than the corner portion of the shell, the shell can be manufactured easily and accurately. Since the flat portions of the upper and lower surfaces of the shell can be enlarged, the selectivity of whether or not the fitting is possible and the stability after the fitting can be further improved. This is more effective when the I / O connector is further downsized.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the drawings.
<First Embodiment>
1st Embodiment shows embodiment at the time of applying this invention to the cable (harness) 10 provided with the miniUSB connector 20 shown in FIG. 1, and the miniUSB connector 30 shown in FIG. The present invention can be applied not only to a miniUSB connector but also to a USB connector, an electronic device connector, a peripheral device connector, and other I / O connectors (input / output connectors). Here, the peripheral device means a device connected to an electronic device (for example, a computer) and a device connected to the device, and examples of the peripheral device connector include an AC adapter connector and a cradle connector. There is.

(1) Cable side connector (plug)
The miniUSB connector 20 shown in FIG. 1 or FIG. 2 is used as a plug that is inserted into and fitted into a receptacle, and includes a plug main body 21, a shell 22 extending from the plug main body 21, and a shell 22 disposed in the shell 22. In addition, an insulator 23 extending from the plug body 21 and a contact 24 connected to an electric wire (not shown) in the cable 10 and extending from the plug body 21 are included.

  The plug main body 21 is made of an insulating material, and a shell 22 and an insulator 23 fixed inside the miniUSB connector 20 extend outside from a substantially rectangular end surface 21a of both end surfaces in the longitudinal direction. . The cable 10 is inserted and fixed from the other end surface of the plug main body 21. A contact 24 connected to the electric wire in the cable 10 is inserted into the shell 22 and extends from the end surface 21a to the outside. The material used for the plug body 21 and the molding method of the plug body 21 are the same as those of the conventional miniUSB connector.

  The shell 22 has a height at the center in the width direction (left-right direction in FIG. 2) of the shell 22 in a cross section and an end surface orthogonal to the extending direction from the plug main body 21 (or the direction in which the miniUSB connector 20 is fitted to the receptacle). A straight line AA ′ extending in parallel with the direction (vertical direction in FIG. 2) and a straight line BB ′ extending in parallel with the width direction at the center in the height direction have an asymmetric shape. The shell 22 is formed by forming phosphor bronze with a progressive die (stamping) and then plating with Ni as a base and Sn—Cu, Sn—Pb or the like on the surface layer.

  That is, the upper surface 22 a and the lower surface 22 b of the shell 22 are arranged in parallel to each other along the width direction of the plug main body 21. On the other hand, the left side surface 22 c and the right side surface 22 d of the shell 22 are asymmetric with respect to the straight line A-A ′ of the plug main body 21.

  Specifically, the left side surface 22c extends downward in parallel to the straight line AA ′ from the intersection line 22c1 with the upper surface 22a (first flat surface portion 22c2), and approaches the straight line AA ′ from the vicinity of the straight line BB ′. (Curved portion 22c3), and then extends downward in parallel with the straight line AA ′ (second flat surface portion 22c4) to reach an intersection line 22c5 with the lower surface 22b. Here, an angle formed by the upper surface 22a and the first flat surface portion 22c2 of the left side surface 22c, an angle formed by the second flat surface portion 22c4 and the lower surface 22b, an angle formed by the upper surface 22a and the first flat surface portion 22d2 of the right side surface 22d, And the angle which the 2nd plane part 22d4 and the lower surface 22b make is a right angle or a substantially right angle, respectively.

  On the other hand, the right side surface 22d extends downward in parallel to the straight line AA ′ from the intersection line 22d1 with the upper surface 22a (first flat surface portion 22d2), and is curved so as to be separated from A ′ from the vicinity of the straight line BB ′ ( (Bending portion 22d3) and then extending downward in parallel with the straight line AA ′ (second flat portion 22d4) and reaching an intersection line 22d5 with the lower surface 22b.

  The insulator 23 has a space 22e surrounded by the intersection line 22c1, the first plane portion 22c2, the curved portion 22c3, the upper surface 22a, the intersection line 22d1, and the first plane portion 22d2. The right side surface 23c is fixed to the line 22c1, the first flat surface portion 22c2, and the curved portion 22c3 in contact with and fixed to the intersection line 22d1 and the first flat surface portion 22d2, respectively. The material used for the insulator 23 and the molding method of the insulator 23 are the same as those of the conventional miniUSB connector, and are heat resistant resin (for example, PA (polyamide), PPA (polyphthalamide), LCP (liquid crystal polymer)) or PBT (polyethylene). Butylene terephthalate) or the like.

  On the lower surface 23d of the insulator 23, five contacts 24a to 24e (contacts 24) having a predetermined shape and characteristics in accordance with the miniUSB connector standard are sequentially spaced from the left side 22c side to the right side 22d side. They are held and arranged parallel to each other and arranged on a straight line parallel to the width direction of the plug main body 21. The contact 24 is connected to the cable 10 by soldering or the like, and extends from the plug body 21 to the outside. The contact 24 surrounded by the shell 22 is electrically insulated from the upper surface 22a by the insulator 23, and the contact 24a and the contact 24e are arranged so as to be separated from the left side surface 22c and the right side surface 22d, respectively. The contacts 24a to 24e are arranged so that the straight line A-A 'is perpendicular to the arrangement direction of the contacts 24 (height direction) and passes through the center contact 24c. The contact 24 is formed of a copper alloy such as a spring copper alloy (for example, phosphor bronze or beryllium copper) by a progressive die (stamping), and then plated with Ni as a base and Sn—Cu, Sn—Pb, Au or the like on the surface layer. It forms by giving. The miniUSB connector 20 includes an insulator 23 in which a contact 24 is press-fitted in a shell 22, and the insulator 23 is fixed by bending or crushing a part of the shell 22. The insulator 23 is integrally formed with the contact 24 and the shell 22. Assemble by doing.

(2) Conventional cable side connector (plug)
In contrast to the miniUSB connector 20 to which the present invention is applied, in the conventional miniUSB connector 120 shown in FIG. 3, the shell 122 is symmetrical with respect to the straight line AA ′.

  That is, the left side surface 122c extends downward in parallel to the straight line AA ′ from the intersection line 122c1 with the upper surface 122a symmetrically with the left side surface 22c (first flat surface portion 122c2), and straight from the vicinity of the straight line BB ′. It curves so as to approach AA ′ (curved portion 122c3), and then extends downward in parallel with the straight line AA ′ (second flat surface portion 122c4) to reach the intersection line 122c5 with the lower surface 122b.

  On the other hand, the intersection line 122d extends downward from the intersection line 122d1 with the upper surface 122a in parallel to the straight line AA ′ (first plane portion 122d2), and approaches the straight line AA ′ from the vicinity of the straight line BB ′. It bends (curved portion 122d3) and then extends downward in parallel with the straight line AA ′ (second flat surface portion 122d4) to reach the intersection line 122d5 with the lower surface 122b.

  The plug main body 121 is made of an insulating material, like the plug main body 21, and has a shell 122 fixed inside the miniUSB connector 120 and an end surface 121 a having a substantially rectangular shape among both end surfaces in the longitudinal direction. An insulator 123 extends to the outside. The cable 10 is inserted and fixed from the other end face, and the contact 124 inserted into the cable 10 is inserted into the shell 122 and extends from the end face 121a to the outside.

  The insulator 123 has an upper surface 123a intersecting the upper surface 122a and a left side surface 123b intersecting in a space 122e surrounded by the intersection line 122c1, the first plane portion 122c2, the curved portion 122c3, the upper surface 122a, the intersection line 122d1, and the first plane portion 122d2. The right side surface 123c is fixed to the line 122c1, the first flat surface portion 122c2, and the curved portion 122c3 in contact with and fixed to the intersection line 122d1, the first flat surface portion 122d2, and the curved portion 122d3, respectively.

  Similar to the contacts 24a to 24e, five contacts 124a to 124e (contacts 124) having a predetermined shape and characteristics in accordance with the miniUSB connector standard are formed on the lower surface 123d of the insulator 123 from the left side 122c side. In order to the side, they are arranged and fixed on a straight line parallel to each other with a predetermined interval and parallel to the width direction of the plug main body 121. This contact 124 is inserted into the cable 10 and extends from the inside of the plug main body 121 to the outside. The contact 124 surrounded by the shell 122 is electrically insulated from the upper surface 122a by the insulator 123, and the contact 124a and the contact 124e are disposed so as to be separated from the left side surface 122c and the intersection line 122d, respectively. The contacts 124a to 124e are arranged so that the straight line A-A ′ is perpendicular (height direction) to the arrangement direction of the contacts 124 and passes through the center contact 24c.

(3) Device side connector (receptacle)
The miniUSB connector 30 shown in FIG. 4 is used as a receptacle into which a plug is inserted and fitted. An insulator 33 extending from 31 and a contact 34 extending from the receptacle body 31 are included. The miniUSB connector 30 is used in a state in which the receptacle main body 31 is fixed to a substrate, a cradle (connection base) or other device (substrate) in the portable information terminal, and a signal is received by fitting a plug to this. Or power can be supplied to the device placed on the cradle.

  The receptacle main body 31 includes an insulator 33 and a contact 34 that are inserted and fixed inside a hollow, substantially rectangular parallelepiped shape. The shell 32 extends continuously from the outer surface of the receptacle body 31. The material used for the receptacle body 31 and the molding method of the receptacle body 31 are the same as those of the conventional miniUSB connector.

  The shell 32 has a cross-section and an end surface orthogonal to the direction extending from the receptacle body 31 (or the direction in which the plug is fitted to the miniUSB connector 30), and the height direction at the center in the width direction (left-right direction in FIG. 4) of the shell 32 ( It has an asymmetric shape with respect to a straight line CC ′ extending in parallel with the vertical direction in FIG. 4 and a straight line DD ′ extending in parallel with the width direction at the center in the height direction.

  In other words, the upper surface 32 a and the lower surface 32 b of the shell 32 are arranged in parallel to each other along the width direction of the receptacle main body 31. The left side surface 32 c of the shell 32 extends parallel to the height direction of the receptacle main body 31. On the other hand, the right side surface 32d extends downward from a line of intersection 32d1 with the upper surface 32a in parallel to the straight line CC ′ (first flat surface portion 32d2), and extends from the vicinity of the straight line DD ′ to the straight line CC ′. It curves so as to approach (curved portion 32d3), and then extends downward in parallel with the straight line CC ′ (second flat surface portion 32d4) to reach an intersection line 32d5 with the lower surface 32b. Here, the angle formed between the upper surface 32a and the left side surface 32c, the angle formed between the left side surface 32c and the lower surface 32b, the angle formed between the upper surface 32a and the first plane portion 32d2 of the right side surface 32d, and the second plane portion 32d4 The angles formed with the lower surface 32b are each a right angle or a substantially right angle.

  The insulator 33 is surrounded by the shell 32 and is disposed with a predetermined gap with respect to the shell 32 so that the contact 34 disposed on the insulator 33 does not contact the shell 32, and is fixed to the receptacle main body 31. ing. The material used for the insulator 33 and the molding method of the insulator 33 are the same as those of the conventional miniUSB connector, and heat-resistant resin (for example, PA (polyamide), PPA (polyphthalamide), LCP (liquid crystal polymer)) or PBT (polyethylene). Butylene terephthalate) or the like.

  In the insulator 33, five contacts 34a to 34e (contacts 34) having a predetermined shape and characteristics in accordance with the miniUSB connector standard hold a predetermined interval in order from the left side 32c side to the right side 32d side. In parallel with each other, they are fitted and arranged on a straight line parallel to the width direction of the receptacle body 31. The contacts 34a to 34e surrounded by the shell 32 are exposed from the upper surface 33a of the insulator 33 so that the contacts 24e, 24d, 24c, 24b, and 24a can be elastically contacted with each other when the miniUSB connector 20 is fitted. is doing. Further, the contacts 34a to 34e are not exposed from the side surfaces 33b and 33c and the lower surface 33d of the insulator 33, and even if the shell 22 and the insulator 33 slide when they are fitted to the miniUSB connector 20, they are in contact with the shell 22. 34 does not conduct. Contacts 34a to 34e penetrate receptacle body 31 and are electrically coupled to signal lines connected to the device. The contact 34 is formed by forming a spring copper alloy (for example, phosphor bronze, beryllium copper) with a progressive die (stamping), and then plating Ni such as Sn—Cu, Sn—Pb, Au, etc. on the surface layer. Form.

  The distance from the intersection line 32c1 between the upper surface 32a and the left side surface 32c of the shell 32 to the intersection line 32d1 corresponds to the maximum distance between the left side surface 22c and the right side surface 22d, and the shape of the right side surface 32d is the shape of the left side surface 22c. It corresponds to. Thereby, the miniUSB connector 20 can be fitted to the miniUSB connector 30 while the outer surface of the shell 22 is slid on the inner surface of the shell 32.

  The distance from the intersection line 32c1 between the upper surface 32a and the left side surface 32c of the shell 32 to the intersection line 32d1 corresponds to the maximum distance between the left side surface 122c and the intersection line 122d, and the shape of the right side surface 32d is the left side surface 122c. It corresponds to the shape of. Accordingly, the conventional miniUSB connector 120 can be fitted into the miniUSB connector 30 while the outer surface of the shell 122 slides on the inner surface of the shell 32.

  The miniUSB connector 30 is assembled by fixing the insulator 33 by incorporating an insulator 33 into which the contact 34 is press-fitted into the shell 32 and bending or crushing a part of the shell 32. The miniUSB connector 30 is formed at a part of the bottom surface portion 32 b of the shell 32, a tail portion 31 a (see FIG. 4B) extending in parallel with the straight line DD ′ from the receptacle body portion 31, and an end portion of the contact 34. The tail portion (in the case of the contact 34c, the tail portion 34c1 (see FIG. 4C), and the tail portions are similarly formed in the contacts 34a, 34b, 34d, and 34e) is connected to the SMT (Surface Mount Technology) and DIP are mounted by soldering to a substrate or the like.

(4) Conventional device side connector (receptacle)
In contrast to the miniUSB connector 30 to which the present invention is applied, in the conventional miniUSB connector 130 shown in FIG. 5, the shell 132 is symmetric with respect to the straight line CC ′.

  That is, the left side surface 132c extends downward in parallel to the straight line CC ′ from the intersection line 132c1 with the upper surface 132a symmetrically with the right side surface 32d (first flat surface portion 132c2), and straight from the vicinity of the straight line DD ′. It bends so as to approach CC ′ (curved portion 132c3), and then extends downward in parallel with the straight line CC ′ (second flat portion 132c4) to reach an intersection line 132c5 with the lower surface 132b.

  On the other hand, the right side surface 132d extends downward in parallel with the straight line CC ′ from the intersection line 132d1 with the upper surface 132a (first flat surface portion 132d2), and approaches the straight line CC ′ from the vicinity of the straight line DD ′. (Curved portion 132d3), and then extends downward in parallel with the straight line CC ′ (second flat portion 132d4) to reach the intersection line 132d5 with the lower surface 132b.

  Similar to the receptacle body 31, the receptacle body 131 includes an insulator 133 and a contact 134 that are inserted and fixed inside a hollow, substantially rectangular parallelepiped shape. The shell 132 extends continuously from the outer surface of the receptacle body 131.

  Like the insulator 33, the insulator 133 is surrounded by the shell 132, and is disposed with a predetermined gap with respect to the shell 132 so that the contact 134 disposed on the insulator 133 does not contact the shell 132. It is fixed to the main body 131.

  In the insulator 133, like the contacts 134, five contacts 134a to 134e (contacts 134) having a predetermined shape and characteristics in accordance with the miniUSB connector standard are sequentially provided from the left side 132c side to the right side 132d side. The receptacle body 131 is fitted and arranged on a straight line that is parallel to each other while maintaining a predetermined interval.

  The shapes of the left side surface 132c and the right side surface 132d correspond to the shapes of the intersection line 122d and the left side surface 122c, respectively. Thereby, the miniUSB connector 120 can be fitted to the miniUSB connector 130 while sliding the outer surface of the shell 122 on the inner surface of the shell 132.

  On the other hand, although the shape of the right side surface 132d corresponds to the shape of the left side surface 22c, the shape of the curved portion 132c3, the second plane portion 132c4, and the intersection line 132c5 of the left side surface 132c is the right side surface. It does not correspond to the shape of 22d. Therefore, even if the miniUSB connector 20 is to be fitted to the miniUSB connector 130, the right side surface 22d collides with the left side surface 132c, so that the shell 22 cannot be inserted into the shell 132.

  As described above, in the miniUSB connector 20 as the plug and the miniUSB connector 30 and the miniUSB connector 40 as the receptacle, the cross-sectional shape (end face shape) of the shell is asymmetric with respect to the straight line AA ′ or the straight line CC ′. As a result, the plug can be easily inserted into the receptacle without mistakes in the insertion direction. Further, by forming at least one of the left side surface 22c, 32c, 42c and the right side surface 22d, 32d, 42d with a curved portion and a flat portion, the fitting between the plug and the receptacle can be securely held, and a conventional projection In addition, since it is not necessary to provide a notch or notch, it is possible to provide an I / O connector that can be easily manufactured and mounted, has high strength, and can be further reduced in size. In addition, there is little risk of deformation or breakage even if the plug and the receptacle are relatively twisted or inserted incorrectly.

  In addition, since the curved portion is formed at or near the center of the side surface of the shell, when it is erroneously inserted, it abuts so as to cross each other near the central portion, so that excessive erroneous insertion force is applied. Even so, deformation and breakage are unlikely to occur, and the possibility of erroneous insertion can be greatly reduced. Further, even when the connector is downsized, the curved portion is formed at or near the center of the side surface of the shell. While being able to manufacture, since the plane part of the upper and lower surfaces of a shell can be enlarged, the selectivity of the possibility of fitting and the stability after fitting can be made more excellent.

  Further, by selecting a combination of plugs or receptacles, it is possible to arbitrarily set whether or not the plug and the receptacle can be fitted. This is effective in preventing an I / O connector used for other purposes from being erroneously connected when it is desired to transmit only a signal or when it is desired to be used only for power supply.

Second Embodiment
Next, a second embodiment of the present invention will be described with reference to FIG. The miniUSB connector 40 of the second embodiment differs from the miniUSB connector 30 of the first embodiment in that the shell 42 includes a curved portion 42c3. Other configurations are the same as those of the first embodiment, and the same reference numerals are used for the same members.

  The shell 42 has a height at the center in the width direction (left-right direction in FIG. 6) of the receptacle body 31 in a cross section and an end surface orthogonal to the direction extending from the receptacle body 31 (or the direction in which the plug is fitted to the miniUSB connector 40). It has an asymmetric shape with respect to a straight line CC ′ extending parallel to the direction (vertical direction in FIG. 6) and a straight line DD ′ extending parallel to the width direction at the center in the height direction.

  That is, the upper surface 42 a and the lower surface 42 b of the shell 42 are arranged in parallel to each other along the width direction of the receptacle main body 31. On the other hand, the left side surface 42c extends downward in parallel to the straight line CC ′ from the intersection line 42c1 with the upper surface 42a (first flat surface portion 42c2), and from the vicinity of the straight line DD ′ to the straight line CC ′. It curves so as to be separated (curved portion 42c3), and then extends downward in parallel with the straight line CC ′ (second flat surface portion 42c4) to reach an intersection line 42c5 with the lower surface 42b. On the other hand, like the right side surface 32d, the right side surface 42d extends downward from the intersection line 42d1 with the upper surface 42a in parallel to the straight line CC ′ (first flat surface portion 42d2), and the straight line C from the vicinity of the straight line DD ′. It curves so as to approach −C ′ (curved portion 42d3), and then extends downward in parallel with the straight line CC ′ (second flat surface portion 42d4) to reach an intersection line 42d5 with the lower surface 42b.

  The shapes of the left side surface 42c and the right side surface 42d correspond to the shapes of the left side surface 22c and the right side surface 22d, respectively. Thereby, the miniUSB connector 20 can be fitted to the miniUSB connector 40 while sliding the outer surface of the shell 22 on the inner surface of the shell 42.

On the other hand, although the shape of the right side surface 42d corresponds to the shape of the left side surface 122c, the shapes of the curved portion 42c3, the second flat surface portion 42c4, and the intersection line 42c5 of the left side surface 42c are intersecting lines. It does not correspond to the shape of 122d. Therefore, even if the miniUSB connector 120 is fitted to the miniUSB connector 40, the intersecting line 122d collides with the left side surface 42c, so that the shell 22 cannot be inserted into the shell 42.
Other configurations, operations, and effects are the same as those in the first embodiment.

  Although the present invention has been described with reference to the above embodiment, the present invention is not limited to the above embodiment, and can be improved or changed within the scope of the purpose of the improvement or the idea of the present invention.

It is a top view which shows the structure of the miniUSB connector which concerns on embodiment of this invention. It is a front view which shows the structure of the cable side connector of the miniUSB connector which concerns on 1st Embodiment of this invention. It is a front view which shows the structure of the cable side connector of the conventional miniUSB connector. (A) is a front view which shows the structure of the apparatus side connector of the miniUSB connector which concerns on 1st Embodiment of this invention, (b) is the perspective view, (c) is along the straight line CC 'in (a). It is sectional drawing. (A) is a front view which shows the structure of the apparatus side connector of the conventional miniUSB connector, (b) is the perspective view. (A) is a front view which shows the structure of the apparatus side connector of the miniUSB connector which concerns on 2nd Embodiment of this invention, (b) is the perspective view.

Explanation of symbols

10 Cable (harness)
20 miniUSB connector (I / O connector)
21 Plug body (body)
22 Shell 23 Insulator 24 Contact 30 miniUSB connector (I / O connector)
31 Receptacle body (body)
32 Shell 33 Insulator 34 Contact 40 miniUSB connector (I / O connector)
42 Shell 120 miniUSB connector (I / O connector)
121 Plug body (body)
122 Shell 123 Insulator 124 Contact 130 miniUSB connector (I / O connector)
131 Receptacle body (body)
132 Shell 133 Insulator 134 Contact

Claims (13)

The main body,
A metal shell extending from the main body,
A contact which is disposed so as to be surrounded by the shell in an electrically insulated state and extends from the main body,
An I / O connector comprising:
The orthogonal cross-sectional shape of the extending direction of the shell is a straight line extending in the height direction at the center in the width direction of the shell.
Asymmetric,
The I / O connector characterized in that an angle formed between the upper surface and the side surface of the shell and an angle formed between the lower surface and the side surface of the shell are substantially right angles. The I / O connector according to claim 1, wherein at least one of the side surfaces at both ends in the width direction of the shell includes a curved portion and a flat portion. The I / O connector according to claim 2, wherein the curved portion is formed at or near the center of the side surface of the shell. 4. The I / O connector according to claim 1, wherein the side surfaces of the shell are asymmetric with respect to a straight line extending in the height direction at the center in the width direction of the shell. 5. The I / O connector according to claim 1, wherein an upper surface and a lower surface of the shell are parallel to each other. The I / O connector according to claim 1, wherein the contact is used only for power supply. The I / O connector according to claim 1, wherein the contact is used only for signal transmission. The I / O connector according to claim 1, wherein the contact is used for signal transmission and power supply. The I / O connector according to claim 1, wherein the I / O connector is a miniUSB connector. The I / O connector according to claim 1, wherein the I / O connector is a receptacle provided in an electronic device or a peripheral device of the electronic device. The I / O connector according to claim 1, wherein the I / O connector is a plug fitted to an I / O connector provided in an electronic device or a peripheral device of the electronic device. The I / O connector according to any one of claims 1 to 9, wherein the I / O connector is a plug provided in an AC adapter. A cable with I / O connectors at both ends,
At least one I / O connector has a main body,
A metal shell extending from the main body,
A contact which is disposed so as to be surrounded by the shell in an electrically insulated state and extends from the main body,
An I / O connector comprising:
The shape of the cross section orthogonal to the extending direction of the shell is asymmetric with respect to a straight line extending in the height direction at the center in the width direction of the shell.

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