This application is based on Japanese Patent Application No. 2012-257764 filed on Nov. 26, 2012, the disclosure of which is incorporated herein by reference.
The present disclosure relates to a fuse assembly and more particularly to a structure for a fuse mounting portion of an electric connector box to which a fuse sub-assembly is mounted.
A fuse assembly is known in the art, for example, as disclosed in Japanese Patent No. 4,238,783, which discloses a structure for a fuse mounting portion of an electric connector box, to which fuse sub-assemblies are mounted. According to the structure for the fuse mounting portion of the above prior art, it is possible to mount two kinds of fuse sub-assemblies to the electric connector box, wherein outer dimensions of the fuse sub-assemblies in a fuse-insertion direction (more exactly, a length in a height direction of the fuse sub-assembly) are different from each other. A pair of ribs is provided in a cavity of a housing for the electric connector box in a width direction of the cavity, wherein each of the ribs is projecting into an inside of the cavity. An upper end surface of each rib, namely an end surface of the rib on a side to an opening end of the cavity, is inclined with respect to the fuse-insertion direction.
When the fuse sub-assembly is inserted into the cavity, a stepped portion of the fuse sub-assembly is brought into contact with the inclined surfaces of the ribs, so that the fuse sub-assembly is positioned in the fuse mounting portion.
The housing of the electric connector box of the above prior art is generally made of resin. When thermal shock is applied to the housing made of resin, the fuse mounting portion is thermally expanded or contracted. Then, a relative positional relationship between the ribs and female terminals (made of, for example, copper alloy) provided in the cavity may be changed. For example, when the cavity is thermally expanded, the fuse sub-assembly is pushed in the width direction of the cavity (perpendicular to the fuse-insertion direction) by the inclined surface of the rib.
As a result, the fuse sub-assembly is relatively moved in the cavity whenever the thermal expansion and contraction are repeated in the cavity. In other words, sliding movement of a male terminal with respect to the female terminal is repeatedly carried out in the cavity. As a result, contact failure is likely to occur between the male terminal and female terminal provided in the cavity due to abrasion powder of the terminals and/or decrease of contact pressure between the terminals. When the contact failure occurs in the fuse sub-assembly, voltage drop may occur at the terminals of the contact failure and operation of an electric or electronic devices connected to the fuse sub-assembly may be adversely affected due to such voltage drop.
The present disclosure is made in view of the above problem. It is an object of the present disclosure to provide a structure of a fuse mounting portion made of resin, according to which contact failure of a fuse sub-assembly to be caused by thermal expansion and contraction can be avoided.
According to a feature of the present disclosure, a fuse sub-assembly having a pair of male terminals is inserted into a fuse mounting portion in a fuse-insertion direction. The fuse mounting portion has a cavity portion made of resin and has an opening end, through which the fuse sub-assembly is mounted to the cavity portion. The fuse mounting portion has a pair of female terminals, which is electrically connected to the respective male terminals when the fuse sub-assembly is inserted into the cavity portion. The female terminals hold the fuse sub-assembly in the cavity portion.
The cavity portion has a stopper portion, with which the fuse sub-assembly is brought into contact in a fuse-mounted condition. The cavity portion further has a pair of projecting portions projecting into an inside of the cavity portion. The projecting portions are arranged in a width direction of the cavity portion.
Guide surfaces are formed at each projecting portion for guiding the male terminals toward the female terminals when the fuse sub-assembly is inserted into the cavity portion. A distance between the pair of the guide surfaces in the width direction becomes larger in the fuse-insertion direction toward the opening end of the cavity portion.
A gap is formed between the fuse sub-assembly and the guide surfaces in the fuse-mounted condition, in which the fuse sub-assembly is inserted into the cavity portion until the fuse sub-assembly is brought into contact with the stopper portion.
According to the above structure, the fuse sub-assembly mounted to the fuse mounting portion hardly moves in the cavity portion, even when the cavity portion is thermally expanded and contracted due to thermal shock. As a result, it is possible to prevent contact failure of the fuse sub-assembly.
According to another feature of the present disclosure, multiple fuse mounting portions are integrally formed in a housing of the fuse assembly and arranged with one another in the width direction, in which the projecting portions of each pair are respectively arranged in a line.
When the multiple fuse mounting portions are arranged in the line, an outside dimension of the housing made of resin becomes larger in the width direction of the cavity portion. As a result, an amount of the thermal expansion and the thermal contraction caused by the thermal shock in the cavity portion becomes correspondingly larger in the width direction. Then, the guide surfaces formed at the projecting portions are more likely to move in the width direction, in which the fuse sub-assembly may be moved. Accordingly, the effect of the present disclosure for preventing the contact failure caused by the thermal expansion and contraction can be more remarkably produced in such fuse assembly having the multiple fuse mounting portions.
According to a further feature of the present disclosure, the gap is made to be larger in the fuse mounting portion, which is more separated from an intermediate fuse mounting portion in the width direction.
According to such a structure, the gap between the fuse sub-assembly and the guide surfaces can be designed by a proper value so as to prevent the contact failure of the fuse sub-assembly, which may be caused by thermal expansion and/or thermal contraction of the cavity portion 16. In addition, since it is not necessary to make the gap larger than needs at a center of the housing or at the intermediate fuse mounting portion, it is possible to make an outside dimension of the housing at a proper value. For example, when compared with a case in which the gap is made equal to one another among the fuse mounting portions, the outside dimension of the housing can be made smaller in the above structure.
The above and other objects, features and advantages of the present disclosure will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:
The present disclosure will be explained hereinafter by way of an embodiment with reference to the drawings.
As shown in
A structure of the fuse mounting portion 14 of the electric connector box 10 will be explained. Although the electric connector box 10 has multiple fuse mounting portions 14 arranged in a line, each of the fuse mounting portions 14 has the same structure to one another. In
The fuse mounting portion 14 is symmetrical with respect to a center point “O” in
As shown in
A pair of through-holes 20e is formed in the bottom wall 20a of the fuse accommodating hole 20. Each of the female terminals 18 is inserted from the outside of the cavity portion 16 into the cavity portion 16 through the corresponding through-hole 20e. Each of the through-holes 20e is formed at an almost longitudinal end of the bottom wall 20a in the third direction DR3 (as seen from
In the cavity portion 16, a stopper portion 22 is formed in the bottom wall 20a (
The stopper portion 22 as well as the projecting portions 24 form a part of the housing 15 made of the resin. The stopper portion 22 is projected in the first direction DR1, that is, in a direction to the cavity portion 16 from a center of the bottom wall 20a of the fuse accommodating hole 20. As shown in
The fuse contacting surface 22a is brought into contact with the fuse sub-assembly 12 in the first direction DR1, when the fuse sub-assembly 12 is inserted into the fuse accommodating hole 20, namely when the fuse sub-assembly 12 is mounted to the fuse mounting portion 14. In other words, the fuse contacting surface 22a is in contact with the fuse sub-assembly 12 in a fuse-mounted condition.
Each of the projecting portions 24 (24a1, 24b1, 24a2, 24b2) is projected into the cavity portion 16. Since each of the projecting portions 24 is formed at each corner of the cavity portion 16, at which side walls 20c and 20d of the fuse accommodating hole 20 intersect with each other, each of the projecting portions 24 is projected into the cavity portion 16 from the side walls 20c and 20d of the fuse accommodating hole 20. The first pair of the projecting portions 24 (24a1 and 24b1) is formed at a longitudinal end of the fuse accommodating hole 20 in the third direction DR3 (in the upper-side portion in
The projecting portions 24 (24a1 and 24b1, or 24a2 and 24b2) of each pair are arranged in a thickness direction of a male terminal 60 (
Guide surfaces 26a1, 26b1, 26a2 and 26b2 are formed at each projecting portion 24 (24a1, 24b1, 24a2 and 24b2) in order to smoothly guide the male terminals 60 of the fuse sub-assembly 12 into the fuse accommodating hole 20 (namely, into the cavity portion 16), so that each of the male terminals 60 is inserted into the respective female terminals 18 when the fuse sub-assembly 12 is mounted to the fuse mounting portion 14. The guide surfaces 26a1, 26b1, 26a2 and 26b2 are collectively referred to guide surfaces 26. More in detail, each of the guide surfaces 26 is formed at an upper end surface of each projecting portion 24, wherein the upper end surface is a surface of the projecting portion 24 on a side closer to the opening end 20b of the fuse accommodating hole 20 in the first direction DR1. As shown in
Each of the guide surfaces 26a1 and 26b1 is tapered in the first direction DR1. More in detail, each of the guide surfaces 26a1 and 26b1 is formed with an inclined surface (a tapered surface), which extends in parallel to the third direction DR3 and is inclined with respect to the first direction DR1, so that the male terminals 60 of the fuse sub-assembly 12 can be smoothly guided to the female terminals 18. As shown in
As shown in
As shown in
The female terminal 18 is made of copper alloy, which is generally used as material for terminals. As shown in
As shown in
When the male terminal 60 of the fuse sub-assembly 12 is inserted into the press-insert gap 40a of the female terminal 18 in the fuse insertion direction X, the male terminal 60 and the female terminal 18 are electrically connected to each other. At the same time, the female terminal 18 physically holds the male terminal 60 inserted into the press-insert gap 40a. In other words, the pair of the female terminals 18 holds the fuse sub-assembly 12 in the fuse accommodating hole 20 (that is, in the cavity portion 16).
As shown in
The fuse sub-assembly 12 will be explained with reference to
Each of the male terminals 60 is made of metal and formed in a plate shape. In the fuse-mounted condition, a thickness direction of the male terminals 60 corresponds to the second direction DR2 and the male terminals 60 of each male-terminal pair are aligned in the third direction DR3 (in the longitudinal direction of the fuse sub-assembly 12).
The fuse main body 62 is made of resin, for example, polyamide resin. The fuse main body 62 includes inside thereof a fuse element (not shown), which is provided between the male terminals 60 of the pair and respectively connected to the male terminals 60. As shown in
A pair of shoulder portions 63 and 64 is integrally formed with the base body portion 62b at both longitudinal sides of the intermediate portion 62c in the third direction DR3. In other words, the shoulder portion 63 is formed at a longitudinal end of the base body portion 62b (in a left-hand side in
A thickness of the base body portion 62b is larger than that of the male terminals 60 in the second direction DR2. A contacting portion 62a is formed at a lower end of the intermediate portion 62c. The contacting portion 62a is brought into contact with the fuse contacting surface 22a of the stopper portion 22 in the fuse-mounted condition. The contacting portion 62a is formed by a flat surface perpendicular to the fuse insertion direction X (the first direction DR1).
The fuse sub-assembly 12 is inserted into the fuse accommodating hole 20 of the fuse mounting portion 14 so that the fuse sub-assembly 12 is mounted to the fuse mounting portion 14. In the fuse-mounted condition, each of the male terminals 60 is interposed between the pair of the forked ends 40 of the respective female terminals 18, so that the fuse sub-assembly 12 is firmly supported in the fuse mounting portion 14. The contacting portion 62a of the fuse main body 62 is in contact with the fuse contacting surface 22a of the stopper portion 22 in the first direction DR1, so that the fuse sub-assembly 12 is positioned in the fuse mounting portion 14 in the first direction DR1.
As shown in
The first lower edge P1a corresponds to a most neighboring point of the fuse sub-assembly 12 to the guide surface 26a1, at which the first lower edge P1a is closest to the guide surface 26a1 in the fuse-mounted condition. In a similar manner, the second lower edge P1b corresponds to a most neighboring point of the fuse sub-assembly 12 to the guide surface 26b1, at which the second lower edge P1b is closest to the guide surface 26b1 in the fuse-mounted condition.
As above, even in the fuse-mounted condition, in which a part of the fuse main body 62 (the first and/or second lower edges P1a and/or P1b) is located at the position closest to the guide surface 26a1 and/or 26b1, the gaps CLS-a and CLS-b are formed between the first and second lower edges P1a and P1b and the guide surfaces 26a1 and 26b1. In other words, any part of the fuse main body 62 is not brought into contact with the guide surfaces 26a1 and 26b1, when the fuse sub-assembly 12 is inserted into the fuse accommodating hole 20.
The first gap CLS-a and the second gap CLS-b are collectively referred to as the gap(s) CLS. A value of the gap CLS is determined based on a positional relationship between the fuse contacting surface 22a of the stopper portion 22 and the guide surfaces 26a1 and 26b1 as well as a positional relationship between the contacting portion 62a of the fuse main body 62 and the most neighboring points P1a and P1b of the fuse sub-assembly 12 to the guide surfaces 26a1 and 26b1 in the fuse-mounted condition. Since the contacting portion 62a is in contact with the fuse contacting surface 22a in the fuse-mounted condition, the fuse sub-assembly 12 is not allowed to further move in the fuse insertion direction X from the position shown in
Each of the gaps CLS-a and CLS-b, shown in
If the fuse main body 62 is in contact with the guide surface 26b1 at a contacting point A1, as shown in
According to the present embodiment, however, as shown in
In
In
According to the present embodiment, multiple fuse mounting portions 14 are aligned in a straight line, in which the pairs of the projecting portions 24 (24a1, 24b1 or 24a2, 24b2) are arranged, as shown in
Therefore, an amount of thermal expansion and/or thermal contraction of the cavity portions 16 may become correspondingly larger in the second direction DR2. Then, the guide surfaces 26 formed on the projecting portions 24 are likely to move in the direction, in which the fuse sub-assembly 12 is forced to swing. According to the present embodiment (having the multiple fuse mounting portions 14 in the line), the effect for preventing the contact failure of the fuse sub-assembly 12 caused by the thermal fluctuation can become more remarkable, when compared with a case having one fuse mounting portion.
In the fuse-mounted condition of the present embodiment, the contacting portion 62a of the fuse sub-assembly 12 is brought into contact with the fuse contacting surface 22a of the cavity portion 16 in order to position the fuse sub-assembly 12 in the fuse mounting portion 14 in the first direction DR1. When the cavity portion 16 as well as the fuse main body 62 is thermally expanded, the fuse sub-assembly 12 is pushed back in the opposite direction to the fuse-insertion direction X.
When the fuse sub-assembly 12 is once pushed back, the fuse sub-assembly 12 is held at such a pushed-back position. When the thermally expanded cavity portion 16 of the fuse main body 62 is turned back to its initial condition, a gap is generated in the first direction DR1 between the contacting portion 62a and the fuse contacting surface 22a. As a result, even when the cavity portion 16 and the fuse main body 62 thereafter repeat the thermal expansion and the thermal contraction, the male terminal 60 does not repeatedly slide on the female terminal 18 in the first direction DR1. The contact failure of the fuse sub-assembly 12 can be thus avoided.
The present disclosure should not be limited to the above embodiment but can be modified in various manners, for example, in the following manners.
(1) In the above embodiment, as shown in
(2) In the above embodiment, each of the guide surfaces 26a1, 26b1, 26a2 and 26b2 is formed by the flat surface. However, the guide surface (s) can be formed by a curved surface of a concave or a convex.
(3) In the above embodiment, the fuse sub-assembly 12 is composed of so-called a low-type fuse having a small height. However, any type of fuses, such as, so-called a mini-type fuse, can be used. In the above embodiment, as shown in
(4) In the above embodiment, each of the male terminals 60 is composed of the plate-type terminal. The male terminal 60 may not be always made of the plate-type terminal.
(5) In the above embodiment, the female terminal 18 of the fuse mounting portion 14 is composed of the press-insert type terminal. However, the female terminal 18 maybe made of any other types, such as a tongue-shaped terminal, a faston terminal, and so on.
(6) In the above embodiment, the guide surfaces 26 are so made that the gap CLS in one fuse mounting portion 14 is made to be identical to the gap CLS in the other fuse mounting portion 14. However, the gaps CLS may be different from the fuse mounting portion 14 to the fuse mounting portion 14.
For example, the gap CLS in each fuse mounting portion 14 can be made larger in a direction from a center of the housing 15 toward an outer side thereof in the second direction DR2 or in a direction from an intermediate fuse mounting portion 14 toward an outer-most fuse mounting portion 14 in the second direction DR2. In other words, the gap CLS defined in
According to such a modification, the gap CLS between the fuse sub-assembly 12 and the guide surfaces 26a1 and 26b1 (as well as 26a2 and 26b2) can be designed by a proper value so as to prevent the contact failure of the fuse sub-assembly, which may be caused by thermal expansion and/or thermal contraction of the cavity portion 16.
In addition, since it is not necessary to make the gap CLS larger than needs at the center of the housing 15 or at the intermediate fuse mounting portion 14, it is possible to make an outside dimension of the housing 15, namely an outside dimension of the electric connector box 10, at a proper value. For example, when compared with a case in which the gap CLS is made equal to one another among the fuse mounting portions, the outside dimension of the housing 15 can be made smaller in the above modification.
As above, the present disclosure should not be limited to the above-explained embodiment but can be modified in various manners within scopes of protection in the following claims.
Number | Date | Country | Kind |
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2012-257764 | Nov 2012 | JP | national |