JP2011083105A - Spacer and electrical junction box with the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a spacer for preventing a poor connection and falling-off of an electric component, and an unusual noise caused by a wobble, and to provide an electrical junction box including the spacer. <P>SOLUTION: The electric component box 1 includes a box body 2, a cylindrical component mount unit 16 that is provided in the box body 2, houses an integration 7 inside, and allows the integration 7 to be mounted, and a spacer 3 inserted between the inside of the component mount unit 16 and the integration 7. The spacer 3 includes a regulation unit 32 for regulating the release of locking to a lock projection 27 of the integration 7 in a portion 21 of the component mount unit 16, and an elastic press unit 34. The elastic press unit 34 is elastically deformed freely. The elastic press unit 34 biases the integration 7 toward the inside of the component mount unit 16. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a spacer inserted between a component mounting portion of an electrical connection box mounted on an automobile or the like as a moving body and an electrical component mounted to the component mounting portion, and an electrical connection box including the spacer About.

  In general, automobiles as moving bodies are equipped with a wide variety of electronic devices such as lamps such as head lamps and tail lamps, and motors such as motors for starter motors and air conditioners.

  In order to supply electric power to the various electronic devices described above, the automobile has arranged junction blocks at appropriate locations. The junction block is composed of various electric circuit units such as a large number of fuses and relays.

  In addition, since a junction block may have a fuse, a relay, a bus bar, etc., it is also called a fuse block, a relay box, or an electrical connection box (for example, refer patent document 1) generically. In the present specification, the above-described fuse block, relay box, and junction block are collectively referred to as an electrical connection box.

  The electrical junction box disclosed in Patent Document 1 described above includes a box body that forms an outer shell, and a wiring block. The box body is made of an insulating synthetic resin and is formed in a box shape. The box body is provided with a component mounting portion on which electrical components such as relays and fuses and power integration as a power distribution unit are mounted, and a connector fitting portion into which a connector of the wire harness is fitted.

  The wiring block is accommodated in the box body. A terminal fitting attached to a terminal of a cable connected to a power source such as a battery or a generator is attached to the wiring block. The wiring block consists of the above-mentioned terminal fittings attached to the end of the cable, electrical parts such as relays and fuses attached to the part mounting part, power integration, etc., and the connector of the wire harness that fits into the connector fitting part. The terminals are electrically connected to each other according to a predetermined pattern in which power from the power source is branched to each wire of the wire harness via a relay, a fuse, or power integration.

  The power integration includes a box-shaped casing made of insulating synthetic resin, a plurality of fuses attached to the casing, a plurality of relays housed in the casing, and the fuses. A bus bar for connecting the relays in accordance with a predetermined pattern. The bus bar is provided with a power input unit to which power is supplied from the power source described above and a plurality of power output units, and the power input to the power input unit is branched to a plurality of power output units through fuses and relays. To do. Various electronic devices are connected to the power output unit of the power integration bus bar via a wire harness.

  In the electrical junction box described above, the wiring block electrically connects the power source, the electrical component, the power integration, and each wire of the wire harness to each other according to a predetermined pattern. The electrical junction box supplies power from the power source to each electronic device connected to the wire harness.

JP 2008-199840 A

  In the electrical junction box shown in Patent Document 1 described above, the component mounting portion to which the power integration is attached includes a lock arm, and the power integration includes a locking protrusion that is locked to the lock arm. The power integration is attached to the component attachment part by locking. In this type of electrical junction box, there is a gap between them due to tolerances when molding the component mounting part and the power integration housing, and the power integration is caused by the vibration during the running of the automobile described above. As a result, the lock arm may be elastically deformed in a direction to release the engagement with the engagement protrusion, and the power integration may fall out of the box body. In addition, even if the power integration does not drop off from the box body, it is conceivable that a connection failure such as conduction between the power integration and the component mounting portion may occur.

  In order to prevent such power integration from falling off, the conventional electrical junction box described in Patent Document 1 described above includes a component mounting portion, and power integration as an electrical component accommodated in the component mounting portion. A spacer to be inserted is provided.

  The spacer of this type includes an attachment portion attached to the box body, a restriction portion that is connected to the attachment portion and restricts elastic deformation of the lock arm in a direction of releasing the engagement with the engagement protrusion, A locking protrusion that is continuous with the mounting portion and that engages with the locking protrusion is provided. The spacer described above restricts the power integration from dropping from the box body by the restricting portion restricting the lock arm from being elastically deformed in the direction of releasing the engagement with the engaging protrusion.

  However, the above-described spacer merely restricts the restricting portion from elastically deforming in the direction in which the lock arm releases the engagement with the engagement protrusion. For this reason, in the electrical junction box described above, a gap is generated between the power integration and the component mounting portion. In addition, the power integration described above has a larger mass than electric components such as other relays and fuses because a plurality of fuses are attached to the casing and a plurality of relays are accommodated. For this reason, the electrical junction box shown in the above-mentioned Patent Document 1 or the like causes the gap described above even if the above-described spacer is used. In contrast, rattling and abnormal noise are generated.

  Accordingly, an object of the present invention is to provide a spacer that can prevent electrical components attached to the component mounting portion due to rattling from being poorly connected or dropped, and causing abnormal noise, and an electrical junction box including the spacer. It is in.

  In order to solve the problems and achieve the object, the spacer of the present invention according to claim 1 is accommodated in a cylindrical component mounting portion provided in a box body of an electric connection box and the component mounting portion. A restricting portion that is inserted between the electric component and restricts the lock of the lock receiving portion that is locked with the lock portion of the electric component of the component mounting portion from being released. If the spacer is configured to be elastically deformable and the spacer is inserted between the inside of the component mounting portion and the electrical component, the electrical component is directed toward the inside of the component mounting portion. It is characterized by having an elastic pressing part that urges it.

  A spacer according to a second aspect of the present invention is the spacer according to the first aspect, further comprising a fixed portion fixed to the box body, wherein the elastic pressing portion has one end connected to the fixed portion and the other end. Is connected to the restricting portion, and the central portion is curved so as to be closer to the outer surface of the electric component than the both ends, and is formed in a cross-sectional arc shape, and the spacer is arranged on the inner side of the component mounting portion and the electric component. When inserted between the parts, the central part is elastically deformed to urge the electric part toward the inside of the part attaching part.

  The electrical junction box according to the third aspect of the present invention includes a box body, a cylindrical component mounting portion that is provided in the box body, accommodates the electrical component inside, and is attached to the electrical component, and the component mounting It is inserted between the inside of the part and the electrical component, and the latching of the latch receiving portion that latches with the latching portion of the electrical component of the component mounting portion is restricted from being released. An electrical junction box including a spacer having a regulating portion to perform, wherein the spacer according to claim 1 or 2 is provided as the spacer.

  According to the spacer of the present invention described in claim 1, even if a gap is generated between the electrical component and the component mounting portion, the elastic pressing portion biases the electrical component toward the inside of the component mounting portion. It becomes difficult for the electrical component to move in the component mounting portion.

  According to the spacer of the present invention described in claim 2, since the elastic pressing portion is formed in an elastically deformable cross-sectional arc shape, the elastic pressing portion surely moves the electrical component toward the inside of the component mounting portion. Can be energized.

  According to the electrical junction box of the present invention described in claim 3, since the above-described spacer is provided, the electrical component is difficult to move within the component mounting portion.

  As described above, according to the first aspect of the present invention, since the electrical component is difficult to move in the component mounting portion, even if a gap is generated between the electrical component and the component mounting portion, the electrical component is in the component mounting portion. It becomes difficult to rattle. Therefore, it is possible to prevent the electrical component from rattling in the component mounting portion and causing poor connection, dropout, and abnormal noise of the electrical component mounted on the component mounting portion.

  According to the second aspect of the present invention, the elastic pressing portion can positively urge the latching portion of the electrical component toward the latch receiving portion of the component mounting portion, and the outer surface of the electrical component is inside the component mounting portion. It can be energized reliably. Therefore, it is difficult for the electrical component to move reliably in the component mounting portion, and it is reliably prevented that the electrical component rattles in the component mounting portion and the electrical component attached to the component mounting portion is poorly connected, dropped, or generates abnormal noise. it can.

  According to the third aspect of the present invention, since the above-described spacer is provided, the electrical component is rattled in the component mounting portion, and the connection failure or dropping of the electrical component attached to the component mounting portion and abnormal noise occur. Can be prevented.

It is a perspective view of the electrical junction box concerning one embodiment of the present invention. FIG. 2 is an exploded perspective view of the electrical junction box shown in FIG. 1. It is a perspective view which shows the integration of the electrical junction box shown by FIG. It is sectional drawing of the principal part along the IV-IV line in FIG. It is sectional drawing which follows the VV line in FIG. It is a perspective view of the spacer of the electrical junction box shown in FIG. FIG. 7 is a side view of the spacer shown in FIG. 6. It is sectional drawing which follows the VIII-VIII line in FIG. FIG. 6 is a perspective view of a main part showing a state in which the integration shown in FIG. 4 is accommodated in the component mounting part shown in FIG. 5. It is sectional drawing of the principal part which follows the XX line in FIG. It is a perspective view of the principal part which shows the state by which the spacer was inserted between the component attachment part shown by FIG. 9, and integration. It is sectional drawing of the principal part which follows the XII-XII line | wire in FIG.

  Hereinafter, a spacer and an electrical junction box according to an embodiment of the present invention will be described with reference to FIGS. The electrical junction box 1 shown in FIG. 1 according to the present embodiment is mounted on an automobile as a moving body.

  As shown in FIG. 1, the electrical junction box 1 includes a box body 2, a power integration (hereinafter simply referred to as integration) 7 as an electrical component, and a spacer 3.

  As shown in FIG. 1, the box body 2 includes a body portion 4, a cassette block 5, an upper cover (not shown), and a lower cover 6. The main body 4 is made of an insulating synthetic resin and is molded by a known injection molding. As shown in FIG. 2, the main body 4 is formed in a cylindrical shape by a plurality of outer walls 8 that are continuous with each other. Further, the main body portion 4 is provided with a partition wall 9 that partitions the main body portion 4.

  Further, an upper surface (hereinafter referred to as an upper surface) in FIG. 2 of the main body portion 4 accommodates a mounting portion on which a relay 15 or a fuse as an electrical component is mounted and an integration 7. A component fitting portion 16 (shown in FIGS. 1 and 2) is provided, and a connector fitting for fitting a wire harness connector (not shown) to the lower surface (hereinafter referred to as the lower surface) in FIG. Is provided.

  As shown in FIGS. 1 and 2, the component mounting portion 16 is formed in a substantially rectangular tube shape, and on its inner surface, a lock arm 17, a pair of integration guide grooves 18 (shown in FIG. 2), and a pair of Spacer guide grooves 19 (shown in FIG. 5) are provided.

  The lock arm 17 is formed in the shape of a cantilever having an end on the lower surface side connected to an inner surface of the component mounting portion 16 and an end on the upper surface side having a free end. Further, the lock arm 17 is provided with a through hole 20 at the center thereof. The lock arm 17 is elastically deformable so that the end portion on the upper surface side is in contact with and away from the inner surface of the component mounting portion 16, and a lock protrusion 27 described later of the integration 7 is positioned inside the through-hole 20. A portion 21 closer to the upper surface than the through hole 20 is engaged with the lock protrusion 27.

  Furthermore, as shown in FIG. 5, an arm inclined surface 22 facing the inner surface of the component mounting portion 16 is provided at the upper end of the lock arm 17. The arm inclined surface 22 is inclined with respect to the direction from the upper surface to the lower surface in a direction gradually approaching the inside of the component mounting portion 16 as it goes from the lower surface side to the upper surface side. The portion 21 closer to the upper surface than the through-hole 20 of the lock arm 17 described above constitutes a locking receiving portion described in the claims.

  The pair of integration guide grooves 18 is formed in a concave shape from the inner surface of the component mounting portion 16 and is provided at a position where the lock arm 17 is positioned between them. The integration guide groove 18 extends linearly from the upper surface side end of the component mounting portion 16 toward the lower surface.

  The pair of spacer guide grooves 19 are recessed from the inner surface of the component mounting portion 16 and are provided at positions where the lock arm 17 is positioned between them. The pair of spacer guide grooves 19 are provided at positions closer to the lock arm 17 than the pair of integration guide grooves 18 and away from the integration 7 mounted in the component mounting portion 16. The pair of spacer guide grooves 19 extend linearly from the upper surface side end of the component mounting portion 16 toward the lower surface.

  The component attachment portion 16 accommodates the integration 7 by accommodating the integration 7 therein, and the aforementioned portion 21 of the lock arm 17 is engaged with the lock protrusion 27.

  Further, the main body 4 is a bus bar that electrically connects the electrical component mounted on the mounting section described above and the terminal of the connector of the wire harness fitted to the connector fitting section according to a predetermined pattern. And so on.

  The cassette block 5 is made of an insulating synthetic resin and is formed in a box shape having a size that can be accommodated in the main body 4 as shown in FIG. The cassette block 5 is accommodated in the main body 4 through an opening on the lower side of the main body 4 in FIG.

  2 and 3 of the cassette block 5 (hereinafter referred to as the upper surface) is provided with a mounting portion 23 to which a relay or fuse as an electrical component is mounted. On the lower surface (hereinafter referred to as “lower surface”), a connector fitting portion for fitting the connector and terminal fitting of the wire harness described above is provided. Further, the cassette block 5 is made of a conductive metal (not shown), and a terminal fitting 11 attached to a terminal attaching portion 12 described later, an electrical component such as a relay and a fuse attached to the attaching portion 23, and a connector fitting. A bus bar for connecting a terminal of the connector of the wire harness to be fitted to the part, a connector part 26 to be described later, and a bus bar accommodated in the main body part 4 in a predetermined pattern is accommodated.

  Of course, the wire harness includes a plurality of electric wires and a connector attached to the end of the electric wires. The connector is fitted to various electronic devices mounted on a connector fitting portion or an automobile.

  Further, two terminal mounting portions 12 are provided on the upper surface of the cassette block 5. A nut (not shown) is embedded in the terminal mounting portion 12.

  The terminal mounting portion 12 has an end portion of the bus bar described above on the surface thereof and an electric contact portion 13 of a terminal fitting 11 (shown in FIG. 2) connected to a power source such as an automobile battery or a generator, in order. The bolt 10 that has passed through the through hole provided in the end portion of the bus bar and the hole 13a of the electric contact portion 13 is screwed into the nut, so that the electric contact portion 13 of the terminal fitting 11 is connected to the end portion of the bus bar and the bolt 10. The terminal fitting 11 is attached between the head and the head.

  Further, the cassette block 5 is provided with a connector portion 26 that is connected to the integration 7 described above. The cassette block 5 having such a configuration branches the power supplied from the power source and supplies it to the integration 7, and the fuse, relay, and connector fitted in the connector fitting portion described above, The electric power described above is supplied to various electronic devices mounted on the automobile via the electric wires of the wire harness.

  The upper cover is made of an insulating synthetic resin and is molded by a known injection molding. The upper cover includes a plurality of outer walls that are continuous with each other, and is formed in a bottomed cylindrical shape. The upper cover is attached to the main body 4 in a state of covering the upper surface of the main body 4.

  The lower cover 6 is made of an insulating synthetic resin and is molded by a known injection molding. As shown in FIG. 1, the lower cover 6 includes a plurality of outer walls 14 that are continuous with each other, and is formed in a bottomed cylindrical shape. The lower cover 6 is attached to the main body 4 while covering the lower surface of the main body 4.

  The box body 2 mounts electrical components such as the relay 15 and the fuse described above on the body section 4 and the cassette block 5 mounted on the body section 4, and also fits the connector of the wire harness into the connector fitting section. Then, by attaching the terminal metal fitting 11 to the terminal attaching portion 12 described above and attaching the upper cover and the lower cover 6 to the main body portion 4 as described above, the above-described electrical components such as the relay 15 and the fuse and the terminal metal fitting 11 are attached. Accommodate.

  As shown in FIG. 3 or the like, the integration 7 includes a case 24, a plurality of fuses (not shown), a plurality of relays (not shown), and a bus bar.

  The case 24 is made of an insulating synthetic resin and is formed in a flat box shape. A fuse mounting portion 25 to which a fuse is mounted is provided on the upper surface of the case 24 located in the upper part in FIG. A lower surface of the case 24 located below in FIG. 5 is provided with a connector fitting portion into which the connector of the wire harness described above is fitted and a fitting portion into which the connector portion 26 described above is fitted. Further, the case 24, that is, the integration 7 is accommodated in the component mounting portion 16 provided in the main body portion 4 of the box main body 2 and attached to the main body portion 4.

  Further, a lock protrusion 27 as a locking portion and a pair of guide protrusions 28 are provided on the outer surface of the component mounting portion 16 of the case 24 facing the inner surface where the lock arm 17 is provided.

  As shown in FIG. 4, the lock protrusion 27 is formed to protrude from the center of the outer surface of the case 24 described above. The lock protrusion 27 enters into the through-hole 20 of the lock arm 17, thereby engaging with the aforementioned portion 21 of the lock arm 17. Further, when the integration 7 of the lock protrusion 27 is inserted into the component mounting portion 16, a protrusion inclined surface 29 is provided on the lower surface side. The protrusion inclined surface 29 forms a part of the outer surface of the lock protrusion 27, and gradually approaches the inner surface on which the lock arm 17 of the component mounting portion 16 is provided from the lower surface side toward the upper surface side. It is inclined with respect to the direction toward the lower surface.

  The guide protrusion 28 is formed so as to protrude from the outer surface described above and is provided at a position where the lock protrusion 27 is sandwiched between them. The guide protrusions 28 extend linearly and are arranged in parallel to each other. The guide protrusion 28 has a vertical portion 30 projecting in a direction perpendicular to the outer surface from the outer surface described above, and an outer surface in a direction away from the end of the vertical portion 30 away from the outer surface. And a parallel portion 31 projecting in parallel with each other.

  The guide protrusion 28 described above guides the integration 7 inserted into the component mounting portion 16 to a proper position by the parallel portion 31 entering the integration guide groove 18 provided on the inner surface of the component mounting portion 16. To do.

  The fuse is attached to the fuse mounting portion 25. The relay is attached to the bus bar and accommodated in the case 24. The fuse and the relay correspond to each other on a one-to-one basis.

  The bus bar is made of conductive sheet metal and is accommodated in the case 24. Each of the bus bars is fitted with a fuse connection terminal portion that is located in the fuse mounting portion 25 and connected to the fuse, and a connector connection terminal portion that is located in the connector fitting portion and is connected to the connector of the wire harness. The connector part connection terminal which is located in the part and is connected to the connector part 26 is provided.

  The bus bar, that is, the integration 7 having the above-described configuration further divides the power from the power source supplied via the connector portion 26 and passes through each relay wire, that is, the wire, via the relay, the fuse, and the connector connection terminal portion. Supply to each electronic device connected to the harness. In this way, the integration 7 distributes the power supplied from the above-described power supply to each electronic device.

  The spacer 3 is made of an insulating synthetic resin, and integrally includes a restricting portion 32, a fixed portion 33, and an elastic pressing portion 34 as shown in FIGS. The restricting portion 32 includes a restricting portion main body 35 formed on a thick flat plate and a pair of guide protrusions 36. When the spacer 3 is inserted between the inner surface of the component mounting portion 16 on which the lock arm 17 is provided and the outer surface of the integration 7 on which the lock protrusion 27 is provided, the spacer 3 is opposed to the lock arm 17 of the regulating portion main body 35. The regulating portion inclined surface 37 is provided on the side to be operated. The restricting portion inclined surface 37 forms a part of the outer surface of the restricting portion main body 35, and gradually approaches the inside of the component mounting portion 16 from the lower surface side toward the upper surface side, with respect to the direction from these upper surface to the lower surface. Is inclined. When the spacer 3 is inserted between the inner surface where the lock arm 17 of the component mounting portion 16 is provided and the outer surface where the lock protrusion 27 of the integration 7 is provided, the restricting portion inclined surface 37 is locked. It closely overlaps with the arm inclined surface 22.

  The guide protrusion 36 protrudes from both edges of the restricting portion main body 35 and extends linearly. When the spacer 3 is inserted between the inner surface where the lock arm 17 of the component mounting portion 16 is provided and the outer surface where the lock protrusion 27 of the integration 7 is provided, the guide protrusion 36 is a spacer guide groove 19. The spacer 3 is inserted into the component mounting portion 16 and guided to a proper position.

  In the restricting portion 32 described above, the guide protrusion 36 penetrates into the spacer guide groove 19 and the restricting portion inclined surface 37 closely overlaps the arm inclined surface 22, so that The release of the lock is regulated.

  The fixed portion 33 is formed in a thin flat plate shape, and the spacer 3 is inserted between the inner surface provided with the lock arm 17 of the component mounting portion 16 and the outer surface provided with the lock projection 27 of the integration 7. Then, the spacer 3 enters the spacer guide groove 19 and cooperates with the guide projection to guide the spacer 3 inserted into the component mounting portion 16 to a proper position.

  The elastic pressing portion 34 is formed in an elastically deformable band plate shape, and has one end connected to the fixed portion 33 and the other end connected to the restricting portion main body 35 of the restricting portion 32. When the spacer 3 is inserted between the inner surface where the lock arm 17 of the component mounting portion 16 is provided and the outer surface where the lock protrusion 27 of the integration 7 is provided, the elastic pressing portion 34 has a central portion described above. The curved portion is formed so as to be closer to the inside of the component mounting portion 16, that is, the outer surface of the integration 7, than both ends connected to the fixed portion 33 and the regulating portion main body 35.

  As shown in FIGS. 9 and 10, the spacer 3 described above has the integration 7 accommodated in the component mounting portion 16, the lock arm 17 is engaged with the lock protrusion 27, and the integration 7 is attached to the box body 2. In the mounted state, it is inserted between the outer surface of the integration 7 provided with the lock protrusion 27 and the inner surface of the component mounting portion 16 provided with the lock arm 17. First, in the spacer 3, the fixed portion 33 is inserted into the spacer guide groove 19 with the restricting portion inclined surface 37 provided on the restricting portion main body 35 facing the inside of the component mounting portion 16. Then, when the elastic pressing portion 34 comes into contact with the lock arm 17 and the spacer 3 is further inserted into the interior of the component mounting portion 16, the elastic pressing portion 34 is elastically deformed in a direction approaching the inner surface of the component mounting portion 16. .

  When the elastic pressing portion 34 gets over the lock protrusion 27, the elastic pressing portion 34 moves away from the inner surface of the component mounting portion 16 by the elastic restoring force and enters the through hole 20. Then, as shown in FIG. 12, the elastic pressing portion 34 is in close contact with the outer surface provided with the protrusion inclined surface 29 of the lock protrusion 27 and the lock protrusion 27 of the integration 7, and presses them by its elastic restoring force. . Further, when the elastic pressing part 34 gets over the lock protrusion 27, the guide protrusion 28 of the restricting part 32 enters the spacer guide groove 19, and the spacer 3 is connected to the component mounting part 16 as shown in FIG. Is inserted between the inner surface and the integration 7 and fixed at a normal position.

  Here, since the protrusion inclined surface 29 is inclined in the above-described direction, the elastic pressing portion 34 biases the lock protrusion 27 toward the above-described portion 21 of the lock arm 17. When the integration 7 is accommodated in the component mounting portion 16, since the inner surface of the component mounting portion 16 and the outer surface of the integration 7 are parallel to each other, the elastic pressing portion 34 causes the integration 7 to be integrated. It urges | biass toward the inner side of the components attachment part 16 along the direction orthogonal to the outer surface. Thus, as shown in FIG. 11, when the spacer 3 is inserted between the inner surface of the component mounting portion 16 and the integration 7, the elastic pressing portion 34 closely contacts the protrusion inclined surface 29 and the outer surface of the integration 7. Then, the central portion is elastically deformed and urges the integration 7 toward the inside of the component mounting portion 16.

  In the electrical junction box 1 described above, the cassette block 5 and the integration 7 are attached to the main body 4, various fuses and relays 15 are attached to the attachment portion 23 and the fuse attachment portion 25, and a wire is connected to the connector fitting portion. When the connector of the harness is fitted, the power source, the integration 7, the fuse, the relay 15, and various electronic devices connected to the wire harness are electrically connected according to a predetermined pattern. The electrical junction box 1 supplies power from the power source to various electronic devices via the integration 7, the fuse, and the relay 15.

  According to the present embodiment, even if a gap is generated between the integration 7 and the component mounting portion 16, the elastic pressing portion 34 causes the lock protrusion 27 of the integration 7 to be placed on the aforementioned portion 21 of the lock arm 17 of the component mounting portion 16. The integration 7 is urged toward the inside of the component mounting portion 16, so that the integration 7 is difficult to move in the component mounting portion 16. For this reason, even if a gap is generated between the integration 7 and the component mounting portion 16, the integration 7 is less likely to rattle within the component mounting portion 16. Therefore, it is possible to prevent the integration 7 from rattling in the component mounting portion 16 and causing the connection failure, dropout, and abnormal noise of the integration 7 mounted on the component mounting portion 16.

  Since the elastic pressing portion 34 is formed in an elastically deformable cross-sectional arc shape, the elastic pressing portion 34 reliably pushes the lock protrusion 27 of the integration 7 toward the aforementioned portion 21 of the lock arm 17 of the component mounting portion 16. The integration 7 can be biased toward the inside of the component mounting portion 16 with certainty. Therefore, it becomes difficult for the integration 7 to move reliably in the component mounting portion 16, and the integration 7 rattles in the component mounting portion 16, resulting in poor connection, dropout, and abnormal noise of the integration 7 attached to the component mounting portion 16. Can be surely prevented.

  Since the electrical junction box 1 having the above-described configuration includes the spacer 3 described above, the integration 7 is difficult to move in the component mounting portion 16, and the integration 7 rattles in the component mounting portion 16, so that the component mounting portion It is possible to prevent the integration 7 attached to 16 from being poorly connected, falling off, or generating abnormal noise.

  In addition, embodiment mentioned above only showed the typical form of this invention, and this invention is not limited to embodiment. That is, various modifications can be made without departing from the scope of the present invention. That is, for example, the spacer 3 is not limited to the integration 7, and the spacer 3 may be used between various electrical components and the component mounting portion 16.

1 Electrical Junction Box 2 Box Body 3 Spacer 7 Power Integration (Electric Parts)
16 parts mounting part 21 part (locking receiving part)
27 Locking projection (locking part)
32 Restricting part 33 Fixed part 34 Elastic pressing part

Claims (3)

Inserted between the cylindrical component mounting portion provided in the box body of the electrical connection box and the electrical component housed in the component mounting portion, the locking portion of the electrical component of the component mounting portion, In the spacer having a restricting portion that restricts the release of the lock receiving portion to be locked with the locking portion,
An elastic press configured to be elastically deformable and biasing the electrical component toward the inside of the component mounting portion when the spacer is inserted between the inside of the component mounting portion and the electrical component A spacer comprising a portion. A fixed portion fixed to the box body,
The elastic pressing portion has one end connected to the fixed portion and the other end connected to the restricting portion, and the central portion is curved so as to be closer to the outer surface of the electrical component than the both ends, and is formed in a cross-sectional arc shape When the spacer is inserted between the inside of the component mounting portion and the electrical component, the central portion is elastically deformed to urge the electrical component toward the inside of the component mounting portion. The spacer according to claim 1. The box body,
A cylindrical component mounting portion that is provided in the box body and accommodates the electrical component on the inside and to which the electrical component is mounted,
Inserted between the inside of the component mounting portion and the electrical component, and the locking of the locking receiving portion that locks with the locking portion of the electrical component of the component mounting portion is released. In an electrical junction box provided with a spacer having a regulating part that regulates that,
An electrical junction box comprising the spacer according to claim 1 or 2 as the spacer.

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