JP7520488B2 - Connector mounting structure - Google Patents

Description

The present invention relates to a connector mounting structure for fixing a connector to a housing.

Many housings for devices such as electrical and electronic devices are provided with connectors for connecting wire harnesses and the like. A conventional connector mounting structure for fixing such a connector to a housing is one in which a screw is screwed into a screw hole in the housing through a mounting hole in the connector, thereby fixing the connector to the housing (see, for example, Patent Document 1 and Patent Document 2). In this structure, a flange is provided so as to extend from the outer circumferential surface of the cylindrical housing of the connector, and a mounting hole is provided in this flange. A through hole is provided in the outer wall of the housing, through which the connector housing passes. When the connector housing passes through this through hole, the flange is placed on the wall surface surrounding the through hole. Then, a screw hole is provided in this wall surface so as to open and overlap with the mounting hole in the flange.

JP 2011-204597 A JP 2012-174506 A

In a structure in which the connector housing is fixed to the housing by passing through a through hole in the outer wall of the housing, a waterproofing member that prevents water from entering through the through hole may be provided between the connector and the outer wall of the housing. In this case, a rotational force may act on the connector around the central axis of the mounting hole through which the screw passes, due to the contact of the screw with the periphery of the mounting hole in the flange during screwing. When the connector rotates due to this rotational force, the waterproofing member may come into contact with one side of the connector or the outer wall of the housing, reducing the waterproofing performance.

Therefore, the present invention focuses on the above problems and aims to provide a connector mounting structure that can fix a connector to a housing while minimizing deterioration of waterproof performance.

In order to solve the above problems , a first connector mounting structure includes a connector having a cylindrical housing and a mounting portion provided with mounting holes extending from an outer peripheral surface of the housing in a plate-like shape and through which screws for fixing to a mounting object are inserted, a casing provided in an outer wall with through holes through which the housing penetrates and screw holes through which the screws are inserted, a waterproofing member interposed between the connector and the outer wall and preventing water from entering through the through holes, an engaging portion provided in the mounting portion at a position sandwiched between the mounting hole and the outer peripheral surface of the housing, and an engaged portion provided on the outer wall with which the engaging portion engages. and a regulating structure for regulating rotation of the connector around the central axis of the mounting hole through which the screw passes, wherein the mounting portion is a member formed as a separate part from the housing and fixed to the housing, a press-fit groove extending in the circumferential direction is formed on the outer peripheral surface of the housing, the mounting portion is formed in a shape that is cut out from a part of the outer peripheral edge of a plate member of a predetermined shape in accordance with the shape of a cross section perpendicular to the central axis of the housing, and the inner peripheral edge of the notch is pressed into the press-fit groove so that the housing fits inside the notch.

In order to solve the above problem , a second connector mounting structure includes a connector having a cylindrical housing and a mounting portion extending in a plate shape from an outer circumferential surface of the housing and provided with a plurality of mounting holes through which a plurality of screws pass for fixing the housing to an object to be mounted, a casing having an outer wall provided with a through hole through which the housing passes and a plurality of screw holes through which the plurality of screws are screwed, a waterproof member interposed between the connector and the outer wall and preventing water from entering through the through hole, a protrusion protruding from an inner edge of each of at least two of the plurality of mounting holes in the mounting portion, and a waterproof member provided on the outer wall. and a regulating structure that regulates rotation of the connector around the central axis of the mounting hole through which the screw passes, wherein the mounting portion is formed as a separate part from the housing and fixed to the housing, a press-fit groove extending in the circumferential direction is formed on the outer peripheral surface of the housing, the mounting portion is formed in a shape that is cut out from a part of the outer peripheral edge of a plate member of a predetermined shape in accordance with the shape of a cross section perpendicular to the central axis of the housing, and the inner peripheral edge of the notch is press-fitted into the press-fit groove so that the housing fits inside the notch.

According to the first and second connector mounting structures, the rotation of the connector around the central axis of the mounting hole through which the screw passes is restricted by a restricting structure having an engaging portion on the connector side and an engaged portion on the housing side, or a restricting structure having a convex portion on the connector side and a concave portion on the housing side. This restriction prevents the waterproof member from becoming misaligned, thereby preventing a decrease in waterproof performance. Thus, according to the first and second connector mounting structures of the present invention, the connector can be fixed to the housing while preventing a decrease in waterproof performance.

1 is a perspective view showing a connector mounting structure according to a first embodiment; FIG. 2 is an exploded perspective view of the connector shown in FIG. 1 . 1 is a perspective view, seen from outside the housing, showing a connector with an O-ring being attached to the housing from the outside and fixed with screws. FIG. This is a perspective view from inside the housing showing how a connector with an O-ring is attached to the housing from the outside and fixed with screws. 2 is a cross-sectional view of the connector mounting structure shown in FIG. 1 taken along line V11-V11 in FIG. 13 is a perspective view of a connector mounting structure according to a second embodiment, showing how a connector with an O-ring is attached to a housing from the outside and fixed with screws, as viewed from outside the housing. FIG. FIG. 7 is a perspective view of the connector mounting structure shown in FIG. 6, showing how a connector with an O-ring is mounted to a housing from the outside and fixed with screws, as viewed from inside the housing. FIG. 8 is a cross-sectional view showing a cross section similar to that of FIG. 5 for the connector mounting structure shown in FIGS. 6 and 7.

Below, one embodiment of the connector mounting structure will be described. First, the first embodiment will be described.

Figure 1 is a perspective view showing a connector mounting structure according to the first embodiment. Note that in this Figure 1, only a portion of the outer wall 121 of the housing 120 to which the connector 110 is attached is shown diagrammatically. This also applies to the other Figures 3 to 8 to be referred to later.

The connector mounting structure 1 of this embodiment is structured so that the connector 110 is fixed to the outer wall 121 of the housing 120 with two screws 130. In this connector mounting structure 1, the connector 110 has the following configuration. Although not specified here, the housing 120 may be, for example, a housing for an electric/electronic device such as an ECU (Electronic Control Unit) mounted on a vehicle. The connector 110 is used to electrically connect the internal circuitry of such an electric/electronic device to an external power source or external device.

Figure 2 is an exploded perspective view of the connector 110 shown in Figure 1.

The connector 110 includes a housing 111, a plurality of connector terminals 112, and an attachment portion 113.

The housing 111 is made of resin and formed into a rectangular tube shape, and accommodates and holds multiple connector terminals 112 inside. The connector terminals 112 are male terminals, with one end of a metal pin located inside the housing 111, which fits into a female terminal in the mating connector that is connected to the connector 110. The other end of the connector terminal 112 is bent into an L-shape and is inserted into a land on a circuit board installed inside the case 120 and fixed by soldering.

The mounting portion 113 is a portion that has two mounting holes 113a through which screws 130 extend from the outer peripheral surface 111a of the housing 111 in a plate shape and are fixed to the housing 120 to be attached. The mounting portion 113 is a metal member that is formed as a separate part from the resin housing 111 and fixed to the housing 111, in accordance with the fact that the outer wall 121 of the housing 120 is made of metal. A press-fit groove 111b into which the mounting portion 113 is press-fitted is formed on the outer peripheral surface 111a of the housing 111, extending over the top surface and a pair of side surfaces in FIG. 2. The mounting portion 113 is formed in a rectangular plate with one long side cut out in a rectangular shape, i.e., in a C-shape in a plan view, and is press-fitted into the press-fit groove 111b so that the housing 111 fits inside the cutout. The mounting portion 113 also has mounting holes 113a at both ends in the longitudinal direction, through which screws 130 pass.

Here, in addition to the above-mentioned press-fit groove 111b, an O-ring mounting groove 111c for mounting an O-ring 140 as a waterproof member is formed on the outer peripheral surface 111a of the housing 111. The O-ring mounting groove 111c is formed around the entire circumference of the outer peripheral surface 111a of the housing 111, and the O-ring 140 is fitted into this O-ring mounting groove 111c. The connector 110 with this O-ring 140 is attached from the outside to the housing 120 and fixed with screws 130.

Figure 3 is a perspective view from the outside of the housing, showing how a connector with an O-ring is attached to the housing from the outside and fixed with screws. Figure 4 is a perspective view from the inside of the housing, showing how a connector with an O-ring is attached to the housing from the outside and fixed with screws. Also, Figure 5 is a cross-sectional view of the connector attachment structure shown in Figure 1, taken along line V11-V11 in Figure 1.

The housing 120 in the connector mounting structure 1 has a metallic outer wall 121 provided with a rectangular through hole 121a through which the housing 111 of the connector 110 passes, and two screw holes 121b into which two screws 130 are screwed.

When mounting the connector 110 to the housing 120, first, the connector 110 with the O-ring 140 attached is inserted into the through hole 121a of the outer wall 121 until the housing 111 and the mounting portion 113 overlap the outer wall 121. As a result, the O-ring 140 is positioned around the entire circumference between the outer circumferential surface 111a of the housing 111 in the connector 110 and the inner circumferential surface 121a-1 of the through hole 121a, and acts as a waterproof member that prevents water from entering through the through hole 121a.

When the connector 110 is inserted as described above, the two mounting holes 113a in the mounting portion 113 overlap with the two screw holes 121b in a one-to-one correspondence. Then, two screws 130 are inserted through the two mounting holes 113a and screwed into the two screw holes 121b, fixing the connector 110 to the housing 120.

Here, in the final stage of threading of each screw 130, the screw 130 rotates while the screw head rubs against the periphery of the mounting hole 113a. At this time, friction between the screw 130 and the screw head causes the mounting part 113, i.e. the connector 110, to receive a rotational force about the central axis 113a-1 of the mounting hole 113a through which the screw 130 passes. When the connector 110 rotates in response to this rotational force, the O-ring 140 comes into contact with the outer peripheral surface 111a of the housing 111 or the inner peripheral surface 121a-1 of the through hole 121a in a biased manner, which may reduce the waterproof performance.

As described below, the connector mounting structure 1 is provided with a restricting structure 150 that restricts rotation of the connector 110 around the central axis 113a-1 of the mounting hole 113a through which the screw 130 passes. The restricting structure 150 includes an engaging portion 151 provided on the mounting portion 113 of the connector 110, and an engaged portion 152 provided on the outer wall 121 of the housing 120.

The engagement portion 151 is a protrusion that protrudes from the surface 113b of the mounting portion 113 on the housing 120 side, and is provided at a position different from the mounting holes 113a. Two engagement portions 151 are provided, one adjacent to each of the two mounting holes 113a. Each engagement portion 151 is provided at a position farther away from the edge portion 113d of the outer periphery 113c of the mounting portion 113 that is closest to the adjacent mounting hole 113a than the mounting hole 113a.

The engaged portion 152 is provided on the outer surface 121c of the outer wall 121 of the housing 120, and is an insertion hole into which the engaging portion 151 fits. Two engaged portions 152 are provided, one adjacent to each of the two screw holes 121b, so that the engaging portions 151 can be inserted into them.

In this restricting structure 150, when the connector 110 tries to rotate due to the rotational force described above when screwed, the two engaging portions 151 interfere with the two engaged portions 152, immediately stopping the rotation. The restricting structure 150 restricts the rotation of the connector 110 by such interference between the engaging portions 151 and the engaged portions 152.

As described above, according to the connector mounting structure 1 of the first embodiment, the restricting structure 150 restricts the rotation of the connector 110 around the central axis 113a-1 of the mounting hole 113a through which the screw 130 passes. This restriction prevents the O-ring 140 from becoming misaligned, thereby preventing a decrease in waterproof performance. In this way, according to the connector mounting structure 1 of this embodiment, the connector 110 can be fixed to the housing 120 while preventing a decrease in waterproof performance.

In this embodiment, the engaging portion 151 is a protrusion protruding from the mounting portion 113 of the connector 110, and the engaged portion 152 is a fitting hole provided in the outer wall 121 of the housing 120.

When comparing the connector 110 and the housing 120, the housing 120 tends to be more difficult to process than the connector 110 in terms of size, complexity of shape, etc. In this embodiment, the engaging portion 151 in the connector 110 is a protrusion, and the engaged portion 152 in the housing 120 is a fitting hole, which is easier to form than a protrusion. Therefore, according to this embodiment, the difficulty in providing the restricting structure 150 can be reduced.

In addition, in this embodiment, two engaging portions 151 are provided, one for each of the two mounting holes 113a, and two engaged portions 152 are provided, one for each of the two engaging portions 113a. According to this embodiment, the two engaging portions 151 and the two engaged portions 152 can firmly restrict the rotation of the connector 110, so that deterioration of the waterproof performance can be further suppressed.

In addition, in this embodiment, the engaging portion 151 is provided at a position farther from the edge portion 113d of the outer periphery 113c of the mounting portion 113 that is closest to the mounting hole 113a than the mounting hole 113a. According to this embodiment, the engaging portion 151 is provided at a position farther from the edge portion 113d of the mounting portion 113 than the mounting hole 113a, so there is no need for space to provide the engaging portion 151 between the mounting hole 113a and the edge portion 113d. Because such space is not needed, it is possible to prevent the mounting portion 113 (i.e., the connector 110) from becoming larger due to the installation of the engaging portion 151.

Next, the second embodiment will be described. This second embodiment differs from the first embodiment described above in terms of the restriction structure that restricts the rotation of the connector in the connector mounting structure. Below, the second embodiment will be described, focusing on the differences from the first embodiment.

Figure 6 is a perspective view of the connector mounting structure according to the second embodiment, in which a connector with an O-ring is attached to the housing from the outside and fixed with a screw, as viewed from the outside of the housing. Figure 7 is a perspective view of the connector mounting structure shown in Figure 6, in which a connector with an O-ring is attached to the housing from the outside and fixed with a screw, as viewed from the inside of the housing. Also, Figure 8 is a cross-sectional view of the connector mounting structure shown in Figures 6 and 7, showing a cross section similar to that of Figure 5. In Figures 6 to 8, components equivalent to those of the first embodiment shown in Figures 3 to 5 are given the same reference numerals as in Figures 3 to 5, and duplicate explanations of these equivalent components will be omitted below.

As in the first embodiment described above, although not specified in the second embodiment, the housing 220 may be, for example, a housing for an electric/electronic device such as an ECU (Electronic Control Unit) mounted on a vehicle. The connector 210 is used to electrically connect the internal circuit of such an electric/electronic device to an external power source or an external device.

In the second embodiment of the connector mounting structure 2, the restricting structure 250 that restricts the rotation of the connector 210 when the connector 210 is screwed to the housing 220 has a convex portion 251 on the connector 210 side and a concave portion 252 on the housing 220 side.

The convex portion 251 is a portion that protrudes from the inner edge of each of the two mounting holes 213a in the mounting portion 213, and specifically, is a cylindrical convex portion that protrudes from the entire circumference of the inner edge of each mounting hole 213a. One of the concave portions 252 is a portion that is provided in the outer wall 221 of the housing 220 and into which the convex portion 251 fits, and specifically, is a countersunk hole that expands the screw inlet of the screw 130 in each of the two screw holes 221b to a diameter that allows the cylindrical convex portion 251 to fit. The screw hole 221b is formed from the bottom of the countersunk recess 221b to the inner surface of the outer wall 221.

When attaching the connector 110 with the O-ring 140 to the housing 220, first, the housing 111 of the connector 110 is inserted into the through hole 121a in the outer wall 221 of the housing 220. Then, the two mounting holes 213a in the mounting portion 213 are aligned one-to-one with the two screw holes 221b, and the two protrusions 251 are fitted into the two recesses 221b. Then, the two screws 130 are inserted through the two mounting holes 213a and screwed into the two screw holes 221b to fix the connector 210 to the housing 220.

In the restricting structure 250, when one mounting hole 213a is screwed and the connector 210 attempts to rotate around the central axis 213a-1 of that mounting hole 213a, the convex portion 251 and the concave portion 252 provided for the other mounting hole 213a interfere with each other. This interference immediately stops the rotation of the connector 210. The restricting structure 250 restricts the rotation of the connector 210 by such interference between the convex portion 251 and the concave portion 252.

As described above, according to the connector mounting structure 2 of the second embodiment, the restricting structure 250 restricts the rotation of the connector 210 around the central axis 213a-1 of the mounting hole 213a through which the screw 130 passes. This restriction prevents the O-ring 140 from becoming misaligned, thereby preventing a decrease in waterproof performance. In this way, according to the connector mounting structure 2 of this embodiment, the connector 210 can be fixed to the housing 220 while preventing a decrease in waterproof performance.

Here, in this embodiment, the convex portion 251 of the regulating structure 250 is a cylindrical convex portion protruding from the entire circumference of the inner edge of each mounting hole 213a, and the concave portion 252 is a countersunk hole that widens the screw entrance of each screw hole 221b. With this regulating structure 250, it is possible to regulate rotation with a higher strength than, for example, a case in which a convex portion protruding in a rod shape from a part of the inner edge of the mounting hole 213a is provided. In addition, since the concave portion 252 as a countersunk hole is easy to process, it is possible to reduce the processing difficulty when providing the regulating structure 250.

In addition, in this embodiment, the restricting structure 250 has two protrusions 251 that protrude from the inner edges of the two mounting holes 213a, and two recesses 252 that correspond one-to-one to the two protrusions 251. With this restricting structure 250, the two protrusions 251 and the two recesses 252 can firmly restrict the rotation of the connector 210, further suppressing the deterioration of waterproof performance.

In addition, in both the first and second embodiments described above, the mounting portions 113, 213 of the connector mounting structures 1, 2 are formed as separate parts from the resin housing 111 and are fixed to the housing 111 by press-fitting. With this structure, the mounting portions 113, 213 that contact the outer walls 121, 221 of the housings 120, 220 can be made of metal, just like the outer walls 121, 221 of the housings 120, 220, so that wear and the like of both can be suppressed.

In both the first and second embodiments, an O-ring 140, which is a waterproof member, is interposed between the inner edge of the through hole 121a in the outer wall 121, 221 of the housing 120, 220 and the outer peripheral surface 111a of the housing 111. With this structure, when the connector 110, 210 is attached, the O-ring 140 fits into the through hole 121a, 221a in the outer wall 121, 221 of the housing 120, 220, making it possible to reduce the size of the connector attachment structure 2.

The above-described embodiment merely shows a typical form of the connector mounting structure, and the connector mounting structure is not limited to this and can be implemented in various modifications.

For example, in the first and second embodiments described above, the following connector mounting structures 1 and 2 are exemplified. That is, in these connector mounting structures 1 and 2, two mounting holes 113a and 213a are provided in the mounting portion 113 and 213 of the connector 110 and 210, and two screw holes 121a and 221a are provided in the outer wall 121 and 221 of the housing 120. However, the connector mounting structure is not limited to this, and the specific number of mounting holes in the mounting portion of the connector and the screw holes in the outer wall of the housing is not important.

In the first and second embodiments described above, as an example of a connector, the board-mounted connectors 110 and 210 are exemplified, in which one end of the connector terminal 112 bent into an L-shape is soldered to a land on a circuit board. However, the connector is not limited to the board-mounted type, and may be, for example, one end of the connector terminal connected to an internal device via an electric wire. Furthermore, even if the connector is board-mounted, the connector is not limited to one end bent into an L-shape, and may have a straight connector terminal over its entire length. In the first and second embodiments described above, as an example of a connector, the connectors 110 and 210 having a rectangular tubular housing 111 are exemplified. However, the shape of the housing in the connector is not limited to a rectangular tubular shape, and may be, for example, cylindrical. In this way, as long as the connector has a tubular housing and an attachment portion provided with an attachment hole through which a screw passes, there is no restriction on the specific connector form.

In the first embodiment described above, as an example of a regulating structure, a regulating structure 150 is exemplified in which the engaging portion 151 is a protrusion protruding from the mounting portion 113 of the connector 110 and the engaged portion 152 is an insertion hole provided in the outer wall 121 of the housing 120. However, the regulating structure is not limited to this, and may be, for example, a structure in which the engaging portion on the connector side is an insertion hole and the engaged portion on the housing side is a protrusion. However, as described above, by making the engaging portion 151 on the connector 110 side a protrusion and the engaged portion 152 on the housing 120 side an insertion hole, the difficulty of providing the regulating structure 150 can be reduced.

In the first embodiment described above, as an example of a regulating structure, a regulating structure 150 is illustrated in which one engaging portion 151 is provided for each of the two mounting holes 113a, and two engaged portions 152 are provided for each of the two engaging portions 151. However, the regulating structure is not limited to this, and the engaging portions may be provided only for some of the multiple mounting holes, and the engaged portions may be provided so that such engaging portions engage with them. In addition, the regulating structure may be provided with multiple engaging portions for one mounting hole, and the engaged portions may be provided so that such multiple engaging portions engage with them. However, as described above, by providing one engaging portion 151 for each mounting hole 113a and providing the engaged portions 152 so that such engaging portions 151 engage with them, the deterioration of waterproof performance can be further suppressed.

In the first embodiment described above, as an example of a regulating structure, a regulating structure 150 is exemplified in which the engaging portion 151 is provided at a position farther from the edge portion 113d closest to the mounting hole 113a than the mounting hole 113a. However, the regulating structure is not limited to this, and the engaging portion may be provided at a position closer to the edge portion closest to the mounting hole than the mounting hole. However, as described above, by providing the engaging portion 151 at a position farther from the edge portion 113d than the mounting hole 113a, it is possible to prevent the mounting portion 113 from becoming larger due to the installation of the engaging portion 151.

In the second embodiment described above, as an example of a restricting structure, a restricting structure 250 is illustrated in which the protrusion 251 is a cylindrical protrusion protruding from the entire circumference of the inner edge of the mounting hole 213a, and the recess 252 is a countersunk hole that widens the screw entrance of the screw hole 221b. However, the restricting structure is not limited to this, and may be, for example, a rod-shaped protrusion protruding from a part of the inner edge of the mounting hole, and the recess is an insertion hole into which such a rod-shaped protrusion fits. However, as described above, by making the protrusion 251 a cylindrical protrusion and the recess 252 a countersunk hole, it is possible to restrict the rotation of the connector with high strength and reduce the difficulty of processing.

In the second embodiment described above, as an example of a regulating structure, a regulating structure 250 is illustrated in which two protrusions 251 are provided to protrude from the inner edges of the two mounting holes 213a, and two recesses 252 are provided to correspond one-to-one to the two protrusions 251. However, the regulating structure is not limited to this, and protrusions may be provided only for some of the multiple mounting holes, and recesses may be provided to correspond to such protrusions. However, as described above, by providing one protrusion 251 for each mounting hole 213a and providing recesses 252 to correspond to such protrusions 251, the deterioration of waterproof performance can be further suppressed.

In the first and second embodiments described above, the mounting parts 113 and 213 are exemplified as an example of a mounting part, which is formed as a separate part from the housing 111 and fixed to the housing 111. However, the mounting part is not limited to this, and may be molded integrally with the housing from resin, for example. However, as described above, by forming the mounting parts 113 and 213 as a separate part from the housing 111, wear on the mounting parts can be reduced.

In addition, in the first and second embodiments described above, the mounting parts 113 and 213 formed to be C-shaped in a plan view are given as an example of a mounting part formed as a separate part from the housing. However, the mounting part is not limited to this, and the shape can be set as desired.

In the first and second embodiments described above, an O-ring 140 is exemplified as an example of a waterproof member, which is interposed between the inner edge of the through hole 121a in the outer wall 121, 221 of the housing 120, 210 and the outer peripheral surface 111a of the housing 111. However, the waterproof member is not limited to this, and may be, for example, a packing interposed between the surface of the mounting portion of the connector facing the housing and the outer surface of the outer wall of the housing, and the specific arrangement position and member type are not important. However, as described above, by adopting an O-ring 140 that fits into the through hole 121a in the outer wall 121, 221 of the housing 120, 210 as the waterproof member, the connector mounting structure 1, 2 can be made smaller.

Reference Signs List 1, 2 Connector mounting structure 110, 210 Connector 111 Housing 111a Outer peripheral surface 111b Press-fit groove 111c O-ring mounting groove 112 Connector terminal 113, 213 Mounting portion 113a, 213a Mounting hole 113a-1, 213a-1 Central axis 113b Surface 113c Outer peripheral edge 113d Edge portion 120, 220 Housing 121, 221 Outer wall 121a Through hole 121a-1 Inner peripheral surface 121b, 221b Screw hole 121c Outer surface 130 Screw 140 O-ring 150, 250 Regulating structure 151 Engaging portion 152 Engaged portion 251 Convex portion 252 Concave portion

Claims (5)

a connector having a cylindrical housing and a mounting portion extending from an outer circumferential surface of the housing in a plate-like shape and provided with mounting holes through which screws for fixing the connector to an object to be mounted are passed;
a housing having an outer wall provided with a through hole through which the housing passes and a screw hole into which the screw is screwed;
a waterproof member interposed between the connector and the outer wall to prevent water from entering through the through hole;
a restricting structure including an engaging portion provided at a position between the mounting hole in the mounting portion and an outer peripheral surface of the housing, and an engaged portion provided on the outer wall with which the engaging portion engages, the restricting structure restricting rotation of the connector about a central axis of the mounting hole through which the screw passes;
Equipped with
the mounting portion is a member formed as a separate part from the housing and fixed to the housing,
A press-fit groove is formed on an outer circumferential surface of the housing, the press-fit groove extending in a circumferential direction.
A connector mounting structure characterized in that the mounting portion is formed in a shape that is cut out from a portion of the outer peripheral edge of a plate member of a predetermined shape in accordance with the shape of a cross section perpendicular to the central axis of the housing, and the inner peripheral edge of the notch is pressed into the press-fit groove so that the housing fits inside the notch. the engaging portion is a protrusion protruding from the mounting portion,
2. The connector mounting structure according to claim 1, wherein the engaged portion is a fitting hole provided on the outer wall and into which the protrusion fits. A plurality of the screw holes are provided,
The mounting holes are provided in a plurality of positions so as to overlap the plurality of screw holes in a one-to-one correspondence,
The engaging portion is provided in a plurality of positions, one for each of the mounting holes,
3. The connector mounting structure according to claim 1, wherein a plurality of the engaged portions are provided for each of the plurality of engaging portions. The connector mounting structure according to any one of claims 1 to 3, characterized in that the engagement portion is provided at a position farther from the mounting hole than the edge portion of the outer periphery of the mounting portion that is closest to the mounting hole. 5. The connector mounting structure according to claim 1 , wherein the waterproof member is interposed between an inner edge of the through hole in the outer wall and an outer peripheral surface of the housing.

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