JP2017091803A - Interlock mechanism - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an interlock mechanism which maintains engagement of an interlock pin and an inlet reliably, even if a cover closing the opening of the enclosure vibrates.SOLUTION: An interlock pin 10 is supported by a cover 9 while being allowed to move a predetermined distance. A front stopper 21a regulates movement of the interlock pin 10 to the inlet side. A rear stopper 21b regulates movement of the interlock pin 10 to the side opposite from the inlet side. A spring 22 loads the interlock pin to the inlet side. The lance 5 of the enclosure 8 interferes with the traveling route of a protrusion 13 when the interlock pin 10 is inserted into the inlet 4. The lance 5 presses the interlock pin 10 against the inner side face and back face of the inlet, while abutting against the protrusion 13 of the interlock pin 10 inserted into the inlet 4. The interlock pin 10 inserted into the inlet is held in non-contact with any of the stoppers 21a, 21b.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an interlock mechanism provided between a cover that closes an opening of a casing of an electronic device and the casing.

  Electronic devices incorporating high-voltage components are often provided with an interlock mechanism that cuts off power supply to the high-voltage components when the cover that covers the opening of the housing is removed (for example, Patent Documents 1 and 2). . In the interlock mechanism of Patent Documents 1 and 2, the interlock is released when the interlock pin provided on the cover side is inserted into the insertion port provided in the housing, and power can be supplied to high-voltage components It becomes. At the same time that the cover is removed from the housing, the interlock pin is pulled out from the insertion port, the interlock is activated, and the power supply to the high voltage component is interrupted.

  In order to prevent poor engagement between the interlock pin and the insertion port, in Patent Document 1, a cylindrical portion is provided on the cover, and the interlock pin is firmly fixed to the cylindrical portion.

Japanese Patent Laying-Open No. 2015-027204 JP 2012-155943 A

  In an electronic device that is used in a vibration environment for a long time, such as an electronic device mounted on an automobile, it is necessary to improve the vibration resistance of the interlock mechanism. The technology disclosed in this specification provides an interlock mechanism that reliably maintains the engagement between the interlock pin and the insertion port even when the cover vibrates with respect to the housing of the electronic device.

  The interlock mechanism disclosed in this specification includes an interlock pin supported by a cover that covers an opening of the housing, and an insertion port provided in the housing. The interlock pin is inserted into the insertion port as the cover is attached to the housing. The interlock pin is supported by the cover while being allowed to move a predetermined distance in the insertion / extraction direction of the insertion port. The cover further includes a front stopper, a rear stopper, and a cover side elastic member. The front stopper regulates the movement of the interlock pin toward the insertion port. The rear stopper regulates the movement of the interlock pin to the side opposite to the insertion port. The cover side elastic member loads the interlock pin to the insertion port side. Further, the housing includes a housing-side elastic member arranged so as to interfere with the movement path of the protrusion when the interlock pin is inserted into the insertion port. The housing-side elastic member presses the interlock pin against the inner surface of the insertion port and presses it into the back of the insertion port while abutting the protrusion of the interlock pin inserted into the insertion port. And when an interlock pin is inserted in an insertion port, the state in which an interlock pin does not contact any of a front stopper and a rear stopper is hold | maintained. That is, when the interlock pin is inserted into the insertion port, there is a margin for movement in either the insertion direction of the insertion port or the opposite direction.

  In the interlock mechanism, the interlock pin is not fixed to the cover, and is supported so as to be movable by a predetermined distance in the insertion / extraction direction with respect to the insertion port. When the cover is attached to the housing, the housing-side elastic member keeps the state where the interlock pin is pressed to the inner surface and back of the insertion port, while the interlock pin is opposite to the insertion direction with respect to the cover. There is room for movement in either direction. Therefore, even when the cover vibrates, the interlock pin is kept engaged with the insertion port. The cover side elastic member is provided so that the protrusion on the side surface of the interlock pin can get over the housing side elastic member without the interlock pin coming into contact with the rear stopper. Details and further improvements of the technology disclosed in this specification will be described in the following “DETAILED DESCRIPTION”.

It is sectional drawing of a housing | casing opening and a cover (before interlock pin insertion). It is sectional drawing of a housing | casing opening and a cover (interlock pin insertion middle). It is sectional drawing of a housing | casing opening and a cover (after inserting an interlock pin). FIG. 4 is an enlarged view of FIG. 3. It is sectional drawing in the VV line of FIG. It is a perspective view of the cover of a modification (state in which the cover and the interlock pin separated). It is a perspective view of the cover of a modification (state where the interlock pin was supported by the cover). It is sectional drawing explaining the relationship between the insertion port, interlock pin, and lance in a modification.

  An interlock mechanism 2 according to the embodiment will be described with reference to the drawings. 1 to 5 are sectional views of an opening 6 provided in a housing 8 of the electronic device and a cover 9 that covers the opening 6. The electronic device is an inverter that is mounted on, for example, an electric vehicle and converts battery power into driving power for a driving motor. The opening 6 is provided for performing an operation of connecting an output terminal (not shown) of the inverter to a cable, and is usually covered with a cover 9. Since a high voltage of 100 volts or more is output from the output terminal of the inverter, it is desirable that the power supply to the inverter is reliably cut off when the cover 9 is removed. Therefore, the interlock mechanism 2 is provided between the housing 8 and the cover 9 of the electronic device. The interlock system including the interlock mechanism 2 cuts off the power supply to the electronic device when the cover 9 is removed from the housing 8. When the cover 9 is attached to the housing 8, the interlock is released. 1 to 4 show the structure of the interlock pin 10 and the insertion port 4. The electrical system of the interlock system will be described later with reference to FIG. 1 to 5 show a state in which the cover 9 faces the opening 6 of the housing 8.

  FIG. 1 is a cross-sectional view before the cover 9 is attached to the housing 8. In other words, FIG. 1 is a cross-sectional view before the interlock pin 10 supported by the cover 9 is inserted into the insertion port 4 provided in the opening 6. FIG. 2 is a cross-sectional view in the middle of inserting the interlock pin 10 into the insertion port 4. FIG. 3 is a cross-sectional view of the state where the cover 9 is attached to the housing 8, that is, the state where the interlock pin 10 is inserted into the insertion port 4. The X direction of the coordinate system in the drawing corresponds to the insertion / removal direction of the interlock pin 10 with respect to the insertion port 4.

  The interlock pin 10 is a columnar part made of resin, and a short-circuit terminal is embedded therein. Two interlock terminals are exposed inside the insertion port 4. When the interlock pin 10 is inserted, the short-circuit terminal shorts the two interlock terminals and the interlock is released. 1-4, illustration of the short-circuit terminal in the interlock pin 10 and the interlock terminal in the insertion port 4 is omitted. The short-circuit terminal and the interlock terminal will be described with reference to FIG. 1-4, the mechanical structure of the interlock mechanism 2 is demonstrated.

  The interlock pin 10 is supported by a guide 21 provided on the back surface of the cover 9. The guide 21 supports the interlock pin 10 while allowing movement of a predetermined distance in the insertion / extraction direction to the insertion port 4. The guide 21 is a cylinder, and the opening at the tip thereof is narrowed by the inner flange 211. Also on the rear side of the guide 21, that is, on the side far from the insertion port 4, the inner diameter of the cylinder is narrowed. The interlock pin 10 is housed inside the guide 21, that is, inside the cylinder. For convenience of explanation, the end of the columnar interlock pin 10 that is inserted into the insertion port 4 is referred to as a “front end”, and the opposite end is referred to as a rear end. In addition, for convenience of explanation, in the cover 9 facing the opening 6 (insertion port 4), the side near the insertion port 4 may be referred to as “front” and the side far from the insertion port 4 may be referred to as “rear”. is there. For convenience of explanation, the positive Z-axis direction in the drawing is referred to as “up”, and the negative Z-axis direction is referred to as “down”.

  A rib 14 is provided at the rear end of the interlock pin 10, and the interlock pin 10 can move to the insertion port 4 side until the rib 14 abuts against the inner flange 211. Further, the interlock pin 10 is movable until the rib 14 comes into contact with the location where the inner diameter of the rear side of the guide 21 is narrowed. The distance indicated by the symbol L1 in the drawing corresponds to the distance that the interlock pin 10 can move with respect to the cover 9. The surface of the inner flange 211 that contacts the rib 14 when the interlock pin 10 moves to a position closest to the insertion port 4 is referred to as a front stopper 21a. The surface of the guide 21 that contacts the rib 14 when the interlock pin 10 moves to the position farthest from the insertion port 4 is referred to as a rear stopper 21b. The interlock pin 10 is supported by the cover 9 so as to be movable between the front stopper 21a and the rear stopper 21b in the insertion / extraction direction of the insertion port 4. In other words, the cover 9 includes a front stopper 21a and a rear stopper 21b. The front stopper 21a regulates the movement of the interlock pin 10 toward the insertion port 4, and the rear stopper 21b The movement of the pin 10 to the side opposite to the insertion port 4 is restricted.

  A compression spring 22 is housed in the bottom of the cylindrical guide 21. The compression spring 22 loads the rear end surface 10 c of the interlock pin 10 housed in the guide 21 toward the insertion port 4. Therefore, as shown in FIG. 1, the interlock pin 10 is held in contact with the front stopper 21 a before the interlock pin 10 is inserted into the insertion port 4.

  A first protrusion 11 is provided at the tip of the columnar interlock pin 10, a second protrusion 12 is provided on the upper side surface 10a, and a third protrusion 13 is provided on the lower side surface 10b. The role of these protrusions will be described later.

  An insertion port 4 is provided in the opening 6 of the housing 8. The insertion port 4 is arranged such that the interlock pin 10 is inserted when the cover 9 is attached to the housing 8. A recess 7 is provided in the back surface 4 a of the insertion port 4. A lance 5 is provided next to the insertion port 4. The lance 5 is an elastic member extending in the insertion / extraction direction of the interlock pin from the vicinity of the base of the insertion port 4 and can be bent in a direction intersecting with the insertion / extraction direction (Z direction in the figure). The “lance” means a spear-like protrusion or “claw” for engaging the connector (pin) with the socket (insertion port) in the connector structure. The lance 5 is disposed so as to interfere with the movement path of the third protrusion 13 when the interlock pin 10 is inserted into the insertion port 4. An arrow broken line Path in FIG. 1 indicates a movement path of the third protrusion 13. The fact that the arrow broken line Path overlaps with the third protrusion 13 indicates that the lance 5 and the third protrusion 13 interfere with each other. FIG. 2 is a cross-sectional view in the middle of inserting the interlock pin 10 into the insertion port 4, and the lance 5 is pushed by the third protrusion 13 and bent downward (in a direction away from the insertion port 4). The state is drawn. A broken line in the vicinity of the lance 5 in FIG. 2 indicates the position of the lance before interfering with the third protrusion 13.

  While the interlock pin 10 is being inserted into the insertion port 4, the third protrusion 13 receives resistance from the lance 5 while the lance 5 and the third protrusion 13 interfere with each other. The resistance acts to push the interlock pin 10 back to the cover 9 side. The compression spring 22 generates a spring force sufficient to hold the interlock pin 10 at the front end of the movable range against the resistance of the lance 5. Therefore, the interlock pin 10 is kept in contact with the front stopper 21 a in the guide 21 during insertion into the insertion port 4.

  When the interlock pin 10 further advances from the state of FIG. 2, the third protrusion 13 gets over the lance 5. FIG. 3 shows a cross-sectional view of the state where the insertion is completed. FIG. 4 shows an enlarged view of FIG. When the insertion is completed, the first protrusion 11 at the tip of the interlock pin 10 is fitted into the recess 7 on the back surface 4 a of the insertion port 4. Immediately before the cover 9 comes into contact with the housing 8, the tip of the interlock pin 10 comes into contact with the back surface 4 a of the insertion port 4. When the cover 9 is further pressed against the housing 8 in order to attach the cover 9 to the housing 8, the interlock pin 10 moves backward relative to the cover 9. When the cover 9 comes into contact with the housing 8, the interlock pin 10 is held in a state where it does not come into contact with either the front stopper 21a or the rear stopper 21b. In other words, when the cover 9 comes into contact with the housing 8, the distance margins G1 and G2 remain before and after the rib 14 of the interlock pin 10 (see FIG. 4). In other words, when the interlock pin 10 is inserted into the insertion port 4 as the cover 9 is attached to the housing 8, the interlock pin 10 is relatively inserted into the insertion port 4. The length of the interlock pin 10 is determined so as to leave a movable margin in both the insertion direction to 4 and the opposite direction. Since the distance margin G2 in the opposite direction to the distance margin G1 in the insertion direction remains, the interlock pin 10 does not move relative to the insertion port 4 even if the cover 9 vibrates in the insertion / extraction direction.

  As shown in FIG. 4, when the interlock pin 10 is inserted into the insertion port 4, the inclined surface 5 a of the lance 5 is inclined with the third protrusion 13 of the interlock pin 10 facing the inner surface 4 a of the insertion port 4. To load. The load F in FIG. 4 indicates the force that the third protrusion 13 receives from the lance 5. The load F can be decomposed into an insertion / extraction direction component Fx and a component (vertical component Fz) in a direction orthogonal to the insertion / extraction direction. The insertion / extraction direction component Fx presses the interlock pin 10 against the back surface 4 a of the insertion port 4. The vertical component Fz presses the interlock pin 10 against the inner surface 4 b of the insertion port 4. The insertion / extraction direction component Fx is mainly transmitted to the first protrusion 11 at the tip of the interlock pin 10 and the contact surface of the recess 7 with which the first protrusion 11 is engaged. Further, the vertical component Fz is transmitted to a contact surface between the second protrusion 12 provided on the upper side surface 10 a of the interlock pin 10 and the inner side surface 4 b of the insertion port 4. Thus, the interlock pin 10 is pressed against the inner surface 4 b of the insertion port 4 and simultaneously with the inner surface 4 a by the elastic force of the lance 5. A lance 5 holds the engagement of the interlock pin 10 with the insertion port 4.

  As described above, even if the cover 9 vibrates, the interlock pin 10 does not vibrate. Then, the lance 5 presses the interlock pin 10 against the inner surface 4 b of the insertion port 4 and also against the inner surface 4 a of the insertion port 4 through the third protrusion 13. Even when the cover 9 vibrates, the lance 5 keeps the interlock pin 10 and the insertion port 4 firmly engaged.

  The compression spring 22 is provided so that the third protrusion 13 can get over the lance 5 without the interlock pin 10 coming into contact with the rear stopper 21b. As described with reference to FIG. 2, the interlock pin 10 receives a force pushed back from the lance 5 toward the cover 9 during the insertion. If the compression spring 22 is not provided, the interlock pin 10 exceeds the lance 5 while being in contact with the rear stopper 21b by the force received from the lance 5. When the insertion is completed while the interlock pin 10 is in contact with the rear stopper 21b, a state in which the interlock pin 10 does not contact either the front stopper 21a or the rear stopper 21b (FIG. 4) cannot be realized. In other words, when the insertion is completed while the interlock pin 10 is in contact with the rear stopper 21 b, the interlock pin 10 is moved relative to the cover 9 in either direction opposite to the insertion direction of the insertion port 4. The state in which a movable margin is left (FIG. 4) cannot be realized.

  The actions of the compression spring 22 and the lance 5 will be summarized. The lance 5 includes a protrusion that protrudes toward the insertion port 4. The lance 5 can be bent in a direction crossing the insertion / extraction direction of the interlock pin 10. While the interlock pin 10 is being inserted, the lance 5 abuts against the third protrusion 13 and applies a force to push back the interlock pin 10. The cover-side compression spring 22 applies a sufficient load to the interlock pin 10 to keep the interlock pin 10 in contact with the front stopper 21a while the third protrusion 13 gets over the protrusion of the lance 5. . When the interlock pin 10 is inserted into the insertion port 4, the third protrusion 13 stops when the peak of the protrusion of the lance 5 is overcome. The lance 5 abuts on the third protrusion 13 and is held in a bent state. The inclined surface 5 a of the projecting portion of the lance 5 that is bent presses the interlock pin 10 against the inner side surface 4 b of the insertion port 4 and against the inner surface 4 a of the insertion port 4 through the third projection 13. After the insertion of the interlock pin 10 is completed, the cover-side compression spring 22 also loads the interlock pin 10 to the back side of the insertion port 4. However, the lance 5 provided in the housing 8 maintains the interlock pin 10 in a state of being stably pressed against the inner side surface 4b and the back surface 4a of the insertion port 4 regardless of the movement of the cover 9. The

  The electrical system of the interlock mechanism 2 will be described with reference to FIG. FIG. 5 shows a cross section taken along line VV in FIG. Two interlock terminals 31 a and 31 b are exposed inside the insertion port 4. A recess 10d is provided at the tip of the interlock pin 10, and the short-circuit terminal 19 is exposed inside the recess 10d. If the interlock pin 10 is inserted in the insertion port 4, the two interlock terminals 31a and 31b and the short circuit terminal 19 will contact, and the interlock terminals 31a and 31b will short-circuit. The interlock terminals 31 a and 31 b are connected to the interlock circuit 32. The interlock circuit 32 cuts off the power supply to the housing 8 when the two interlock terminals 31a and 31b are short-circuited. In addition, illustration and description of the power interruption mechanism are omitted. The structure of the guide 21 including the interlock pin 10, the insertion port 4, the compression spring 22, the lance 5, the front stopper 21 a and the rear stopper 21 b is such that even when the cover 9 vibrates, the interlock terminals 31 a and 31 b and the short-circuit terminal 19 Hold contact securely. The cover 9 is provided with ribs 33 on both sides, and the ribs 33 are fixed to the housing 8 with bolts 34.

  A modified cover 109 will be described with reference to FIGS. 6 and 7. FIG. 6 is a perspective view in which the cover 109 and the interlock pin 110 are separated. FIG. 7 is a perspective view of the cover 109 with the interlock pin 110 attached thereto. 6 and 7, the housing is not shown, but the X axis in the coordinate system in the figure corresponds to the pin insertion / removal direction. For convenience of explanation, the positive direction of the X axis is referred to as “front”, the negative direction is referred to as “rear”, the positive direction of the Z axis is referred to as “up”, and the negative direction is referred to as “lower”. The cover 109 of the modification includes a guide 121 that supports the interlock pin 110 on the back surface thereof. The guide 121 is made of resin. The interlock pin 110 is inserted from below the guide 121. An arrow A <b> 1 in the drawing indicates the mounting direction of the interlock pin 110. A front stopper 121 a that restricts the movement of the interlock pin 110 in the forward direction is provided inside the front end of the guide 121. A rear stopper 121b that restricts the movement of the interlock pin 110 in the backward direction is provided behind the inside of the guide 121. A spring 122 is provided in the internal space of the guide 121 so as to face the rear end face 110 c of the interlock pin 110. The spring 122 is integrally formed with the guide 121, and abuts against the rear end face 110c of the interlock pin 110 using the rigidity of the resin that is the material of the guide 121, and loads the interlock pin 110 forward. Ribs 114 are provided on both sides of the rear end side of the interlock pin 110. When the interlock pin 110 is pressed by the spring 122, the rib 114 abuts against the front stopper 121a, and further moves forward. Is regulated. The interlock pin 110 is attached to the guide 121 so as to be movable between the front stopper 121a and the rear stopper 121b along the X direction (insertion / removal direction to the insertion port).

  Two second protrusions 112 are provided on the upper side surface of the interlock pin 110. The effect of the two second protrusions 112 will be described with reference to FIG. FIG. 8 is a cross-sectional view in which the insertion port 4, the interlock pin 110, and the lance 5 are cut in a cross section passing through the lance 5 and crossing the insertion / extraction direction (X direction in the drawing). As described above, the load applied by the lance 5 is transmitted to the inner side surface 4 b of the insertion port 4 through the second protrusion 112. In the cross section of FIG. 8, the lance 5 and the two second protrusions 112 form a triangle. As indicated by the two arrows A2 in FIG. 8, the load applied by the lance 5 is transmitted to the inner side surface 4b via the second protrusion 112 through two paths having different directions. Since the interlock pin 110 is pressed against the inner side surface 4b of the insertion port 4 in two directions, it is difficult to shift in the Y direction in the figure.

  Points to be noted regarding the technology described in the embodiments will be described. The first protrusion 11 at the tip of the interlock pin 10 has a rectangular parallelepiped shape, and the recess 7 of the insertion port 4 that engages with the first protrusion 11 has the same shape as the outer shape of the first protrusion 11. . The first protrusion 11 may have a tapered shape. In that case, it is preferable that the recess 7 of the insertion port 4 has the same shape as the outer shape of the first protrusion 11.

  The compression spring 22 and the spring 122 correspond to an example of a “cover side elastic member” in the claims. The lance 5 corresponds to an example of a “housing side elastic member”. The third protrusion 13 corresponds to an example of “protrusion” in the claims.

  Specific examples of the present invention have been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings can achieve a plurality of objects at the same time, and has technical usefulness by achieving one of the objects.

2: Interlock mechanism 4: Insert port 4a: Back surface 4b: Inner side surface 5: Lance 6: Opening 7: Recess 8: Housing 9: Cover 10, 110: Interlock pin 11: First protrusions 12, 112: Second projection 13: Third projection 14: Rib 19: Short-circuit terminal 21, 121: Guide 21a, 121a: Front stopper 21b, 121b: Rear stopper 22: Compression spring 122: Spring 211: Inner flange

Claims (1)

An interlock mechanism provided between the cover and the cover that closes the opening provided in the housing of the electronic device,
An interlock pin supported by the cover and provided with a protrusion on the side surface;
Provided in the housing, and an insertion port into which the interlock pin is inserted when the cover is attached to the housing;
With
The cover supports the interlock pin while allowing movement of a predetermined distance in the insertion / extraction direction to the insertion port, and before restricting movement of the interlock pin to the insertion port side. A stopper, a rear stopper for restricting movement to the opposite side of the insertion port, and a cover-side elastic member for loading the interlock pin to the insertion port side;
The housing includes a housing-side elastic member that interferes with a movement path of the protrusion when the interlock pin is inserted into the insertion port.
The housing-side elastic member presses the interlock pin against the inner surface of the insertion port while pressing against the inner surface of the insertion port while abutting against the protrusion of the interlock pin inserted into the insertion port. And
When the interlock pin is inserted into the insertion port, the interlock pin is maintained in a state where it does not contact either the front stopper or the rear stopper.
Interlock mechanism.

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