JP4928790B2 - Lever mounting structure - Google Patents

Description

  The present invention relates to a lever mounting structure for mounting a lever employed in, for example, a vehicle door lock device to a device base.

  Generally, in a door lock device for a vehicle, an open lever is connected to an open rod connected to the door handle, a link lever is provided on the open lever, and a latch mechanism is provided by operating the door handle from the open lever to the link lever. Is to be released. The link lever is locked or unlocked by the lock lever. That is, when the link lever is locked, the operation of the door handle is invalidated by the link lever and the latch mechanism cannot be released. On the other hand, when the link lever is unlocked, the operation of the door handle is enabled by the link lever and the latch mechanism can be released. The lock lever includes a key lock lever that operates in the locked or unlocked state by operating the key from the outside of the vehicle, and a Cirno block lever that operates in the locked or unlocked state by operating the sill knob from the inside of the vehicle. These lock levers are often attached to each other so as to be rotatable with respect to the apparatus base for space efficiency.

  In the conventional lever mounting structure in which each lever is mounted on the device base, a bolt is used for a rotating shaft that rotatably supports each lever, and the bolt is inserted into the device base and each lever and tightened with a nut. (For example, refer to Patent Document 1).

  Further, in another conventional lever mounting structure in which each lever is mounted on the device base, a shaft rod serving as a rotation shaft is integrally provided on the first lever, and this shaft rod is provided in an engagement hole provided in the device base. Lock. Furthermore, a plurality of hooks are integrally provided on the upper surface of the first lever on a concentric circle of the shaft center of the shaft rod, and a stepped shaft hole is formed in the second lever to engage with the hook, and the stepped shaft hole is hooked. And the second lever is pivoted to the first lever (see, for example, Patent Document 2).

JP 59-109678 A Japanese Patent No. 3538331

  However, in the conventional lever mounting structure, the levers mounted in a stacked manner are mounted so as to smoothly rotate. For this reason, the tightening of the nut must be adjusted. For this reason, there is a possibility that an individual difference may occur in the rotation of the lever depending on each device.

  On the other hand, in another conventional lever mounting structure, the first lever is mounted by only locking the shaft rod to the engaging hole of the apparatus base, and the second lever is connected to the stepped shaft hole to the hook of the first lever. It is attached only by engagement. For this reason, when the external force which a shaft rod pulls out from an engagement hole is added with respect to a 1st lever, there exists a possibility that a 1st lever may remove | deviate from an apparatus base with a 2nd lever. In addition, when an external force that causes the stepped shaft hole to come out of the hook is applied to the second lever, the second lever may be detached from the first lever.

  Note that the above problem is not limited to the case where the levers are stacked and attached, but may occur even when one lever is attached to the apparatus base.

  In view of the above circumstances, an object of the present invention is to provide a lever mounting structure that is easy to mount and has sufficient mounting strength against external forces.

In order to achieve the above object, a lever mounting structure according to claim 1 of the present invention is a rod mounting structure in which a lever is rotatably mounted to a predetermined base portion, and is a rod-shaped member that extends integrally with the lever. A rotating shaft having a flange portion projecting in the radially outward direction of the rod-shaped portion at the tip of the portion, and moving while guiding the rotating shaft so as to be movable in a predetermined direction perpendicular to the axial center. a bearing as well as restricting the movement of the rotation axis in a direction along the axis engaged with the flange portion at a position to rotatably support the rotation shaft, in the direction perpendicular to the axis of the rotary shaft A regulating member that regulates movement, and the regulating member is inserted into a shaft hole provided in the lever along the axis of the rotating shaft, and cooperates with the bearing to rotatably support the rotating shaft. It consists of a shaft .

The lever mounting structure according to claim 2 of the present invention is the lever mounting structure in which the first lever and the second lever are overlapped with each other so as to be independently rotatable with respect to a predetermined base. A first rotating shaft having a flange portion projecting radially outward of the rod-shaped portion at the tip of the rod-shaped portion extending integrally with the first shaft, and the first rotating shaft provided perpendicularly to the axis of the first rotating shaft. The first rotation shaft is engaged with the flange portion at a position moved while being guided so as to be movable in a predetermined direction to restrict the movement of the first rotation shaft in the direction along the axis, and rotatably supports the first rotation shaft. One bearing, a second rotating shaft having a flange portion projecting radially outward of the rod-shaped portion at the tip of the rod-shaped portion integrally extending to one of the first lever and the second lever; Either one lever or the second lever Therefore, the second rotary shaft is moved in the direction along the axis by engaging the flange portion at the position where the second rotary shaft is moved while being guided so as to be movable in a predetermined direction orthogonal to the axis. a second bearing for rotatably supporting the second rotary shaft with the first rotation axis on the same axis as well as restricting the movement of the first rotary shaft and second rotary shaft in a direction perpendicular to the axis A regulating member for regulating, and the regulating member is provided on the second lever along the axis of the second rotating shaft and the shaft hole provided in the first lever along the axis of the first rotating shaft It comprises a rod shaft that is inserted into the shaft hole and cooperates with the first bearing and the second bearing to rotatably support the first rotating shaft and the second rotating shaft .

The lever mounting structure according to claim 3 of the present invention is a lever mounting structure in which the lever is rotatably mounted on a predetermined base portion, and the diameter of the rod-shaped portion is attached to the tip of the rod-shaped portion integrally extending to the lever. A rotating shaft having a flange portion projecting outward, and provided on the base portion, and inserting the flange portion of the lever from one surface side of the base portion to the other surface side so that the rotating shaft is centered. A bearing that engages with the flange portion at a position moved while being guided so as to be movable in a predetermined direction orthogonal to the shaft and restricts the movement of the rotary shaft in the direction along the axis, and rotatably supports the rotary shaft. And a regulating member that is attached to the other surface side of the base and regulates the movement of the rotating shaft in a direction orthogonal to the axis.

  The lever mounting structure according to the present invention is easy to mount the lever without using a bolt or the like on the rotating shaft, and can have sufficient mounting strength against external force. Further, when the restricting member is a rod shaft that is inserted through a shaft hole provided in the lever along the axis of the rotation shaft and supports the rotation shaft in cooperation with the bearing, the rotation of the lever is prevented. It can be installed in a smooth state.

  Even when the first lever and the second lever are overlapped with each other so that they can be independently rotated with respect to a predetermined base, the first lever and the second lever can be used without using a bolt or the like. The mounting operation of the second lever is easy and can have a sufficient mounting strength against external force. Further, the restricting member is inserted into the shaft hole provided in the first lever along the axis of the first rotating shaft and the shaft hole provided in the second lever along the axis of the second rotating shaft, and the first bearing When the first and second rotating shafts are coupled with the second bearing to support the first rotating shaft and the second rotating shaft in a rotatable manner, the first lever and the second lever can be mounted in a smooth state. it can.

  Exemplary embodiments of a lever mounting structure according to the present invention will be described below in detail with reference to the accompanying drawings. Note that the lever mounting structure in the present embodiment is employed in, for example, a door lock device that holds a door in a closed state with respect to a vehicle and further locks the closed state of the door. Therefore, in this embodiment, a lever mounting structure including a door lock device will be described.

  1 is a front view showing an example of a door lock device adopting a lever mounting structure according to the present invention, FIG. 2 is a rear view of the door lock device shown in FIG. 1, and FIG. 3 is a left side of the door lock device shown in FIG. FIG. 4 is a right side view of the door lock device shown in FIG.

  The door lock device illustrated in the present embodiment is provided at a door of a front hinge disposed on the right front seat of a four-wheeled vehicle. As shown in FIGS. 1 to 4, in the door lock device, a latch mechanism and a lock mechanism are provided with a base plate 1 as a base. The base plate 1 is formed, for example, by bending or punching a sheet metal, and is bent at a substantially right angle so that the substrate 11 faces the front side (the front side of the vehicle body) and projects from the side of the substrate 11 to the front side. The main cross section is substantially L-shaped.

  As shown in FIGS. 2 to 4, the latch mechanism has a latch body (accommodating portion) 21 formed of synthetic resin. As shown in FIG. 2, the latch body 21 has an opening 21 a on the back surface (one surface), accommodates the latch 22 and the ratchet 23 from the opening 21 a, and closes the opening 21 a with a cover plate 24. . In addition, the latch body 21 has a horizontal cutout groove 211 extending in a substantially horizontal direction toward the vehicle interior side at a position substantially at the center. The front surface (the other surface) of the latch body 21 is attached to the substrate 11 of the base plate 1. The cover plate 24 has a horizontal cutout groove 241 as in the latch body 21.

  The latch 22 and the ratchet 23 are for meshing and holding the striker S (see FIGS. 5 to 7) provided on the vehicle main body side of the four-wheeled vehicle, as in the prior art.

  As shown in FIGS. 5 to 7, the latch 22 is positioned above the horizontal cutout groove 211 of the latch body 21 via a latch rotating shaft 25 extending substantially horizontally along the front-rear direction of the vehicle body. And has a meshing groove 221, a hook portion 222, and a locking portion 223.

  The engagement groove 221 is formed from the outer peripheral surface of the latch 22 toward the latch rotation shaft 25 and is formed to have a width that can accommodate the striker S.

  The hook portion 222 is a portion located on the indoor side of the engagement groove 221 when the latch 22 is rotated about the latch rotation shaft 25 and the engagement groove 221 is opened downward. As shown in FIG. 7, the hook portion 222 stops at a position (full latch position) that crosses the horizontal cutout groove 211 of the latch body 21 when the latch 22 is rotated counterclockwise. On the other hand, as shown in FIG. 5, the hook portion 222 stops at a position (open position) where the horizontal cutout groove 211 is opened when the latch 22 is rotated clockwise.

  The locking portion 223 is a portion located on the outdoor side of the engagement groove 221 when the latch 22 is rotated about the latch rotation shaft 25 and the engagement groove 221 is opened downward. As shown in FIG. 5, the locking portion 223 crosses the horizontal cutout groove 211 when the latch 22 is rotated clockwise, and gradually toward the back (outdoor) of the horizontal cutout groove 211. It is configured to stop while tilting upward. Although not clearly shown in the drawing, a latch spring is provided between the latch 22 and the latch body 21 to constantly urge the latch 22 clockwise in FIGS.

  The ratchet 23 extends substantially horizontally along the front-rear direction of the vehicle body at a position below the horizontal cutout groove 211 of the latch body 21 and on the indoor side of the latch rotation shaft 25. And has an engaging portion 231 and an action portion 232.

  The engaging portion 231 is a portion that extends radially outward from the ratchet rotation shaft 26 toward the outdoor side. When the ratchet 23 is rotated counterclockwise in FIGS. 5 to 7, the engaging portion 231 can be engaged with the hook portion 222 and the locking portion 223 of the latch 22 described above via its end face. It is.

  The action part 232 is a part extending radially outward from the ratchet rotation shaft 26 toward the indoor side. The action portion 232 is connected to the ratchet lever 27. The ratchet lever 27 is provided on the front side of the base plate 1 of the base plate 11 (the front side of the vehicle body) and rotates around the axis of the ratchet rotation shaft 26. That is, the ratchet 23 and the ratchet lever 27 are integrally rotated with each other around the axis of the ratchet rotation shaft 26. Although not shown in the drawing, between the ratchet 23 and the latch body 21, a ratchet spring that constantly biases the ratchet 23 (and the ratchet lever 27) counterclockwise in FIGS. 5 to 7. Is provided.

  In the latch mechanism configured as described above, when the door is in an open state with respect to the vehicle body, the latch 22 is disposed in the open position as shown in FIG. When the door is closed from this state, the striker S provided on the vehicle body side comes into contact with the locking portion 223 of the latch 22. As a result, the latch 22 rotates counterclockwise against the elastic force of a latch spring (not shown). During this time, the ratchet 23 has the end surface of the engaging portion 231 slidably contacted with the outer peripheral surface of the latch 22 by the elastic force of the ratchet spring (not shown), and the ratchet rotation shaft is appropriately selected according to the outer peripheral surface shape of the latch 22. It rotates around the 26 axis.

  When the door is further closed from the above-described state, the amount of the striker S entering the horizontal notch groove 211 gradually increases, so that the latch 22 pushed by the striker S further rotates counterclockwise. Eventually, as shown in FIG. 6, the engagement groove 221 of the latch 22 reaches the engagement portion 231 of the ratchet 23. In this state, since the latching portion 223 of the latch 22 comes into contact with the end surface of the engaging portion 231 of the ratchet 23, the latch 22 rotates clockwise against the elastic restoring force of a latch spring (not shown). Is prevented from rotating. In addition, since the hook portion 222 of the latch 22 is arranged so as to cross the horizontal cutout groove 211, the striker S moves in a direction away from the horizontal cutout groove 211 by the hook portion 222, that is, the door is opened with respect to the vehicle body. The operation is prevented (half latch state).

  Subsequently, when the door is further closed from the half-latch state, the striker S entering the horizontal cutout groove 211 further rotates the latch 22 counterclockwise via the locking portion 223. Eventually, as shown in FIG. 7, the striker S reaches the horizontal cutout groove 211. During this time, the ratchet 23 rotates clockwise against the elastic force of the ratchet spring (not shown) by the hook portion 222 of the latch 22 coming into contact with the upper surface of the engaging portion 231, and the hook portion of the latch 22. When 222 passes, it immediately turns counterclockwise by the elastic restoring force of a ratchet spring (not shown). As a result, as shown in FIG. 7, the hook portion 222 of the latch 22 comes into contact with the end surface of the engaging portion 231 of the ratchet 23, so that the latch 22 resists the elastic restoring force of a latch spring (not shown). Thus, the 22 clockwise rotation is prevented. Even in this state, the hook portion 222 of the latch 22 is disposed so as to cross the horizontal cutout groove 211, so that the striker S is moved by the hook portion 222 in a direction in which the striker S is disengaged from the back (outdoor) of the horizontal cutout groove 211. The situation is prevented, and eventually the door is kept closed with respect to the vehicle body (full latch state).

  Further, the action portion 232 of the ratchet 23 or the ratchet lever 27 is rotated clockwise about the axis of the ratchet rotation shaft 26 against the elastic force of the ratchet spring (not shown) from the above-described full latch state. Thereby, the contact engagement state between the hook portion 222 of the latch 22 and the engagement portion 231 of the ratchet 23 is released, and the latch 22 is rotated clockwise by an elastic restoring force of a latch spring (not shown). As a result, as shown in FIG. 5, the horizontal cutout groove 211 is opened, and the striker S can move in a direction away from the horizontal cutout groove 211, and the door can be opened with respect to the vehicle body. .

  1, the ratchet lever 27 is provided on the front side of the substrate 11 of the base plate 1 via the ratchet rotation shaft 26 so as to be rotatable about the ratchet rotation shaft 26 as an axis. A connecting end portion 271 connected to the portion 232, a working end portion 272 related to the release means, and a pressing end portion 273 extend in the radially outward direction of the ratchet rotation shaft 26.

  As shown in FIGS. 1 and 3, release means is provided on the front side of the substrate 11 of the base plate 1 (the front side of the vehicle body).

  The release means rotates the ratchet lever 27 described above in the clockwise direction in FIGS. 5 to 7 to release the full latch state or the half latch state of the latch mechanism so that the door can be opened with respect to the vehicle body. As shown in FIGS. 1 and 3, it has an open lever 31, a link lever 32, and an inside handle lever 33.

  As shown in FIG. 1, the open lever 31 is provided above the front side of the substrate 11 of the base plate 1. The open lever 31 is provided so as to be rotatable with respect to the substrate 11 via a latch rotation shaft 25. An open lever spring 34 is wound around the latch rotating shaft 25. The open lever spring 34 has one end engaged with the base plate 1 and the other end engaged with the open lever 31. Thereby, the open lever spring 34 always biases the open lever 31 clockwise in FIG.

  The open lever 31 is made of sheet metal and has one open action end 311 and the other open action end 312. One open action end 311 extends toward the left in FIG. The one open action end portion 311 is related to an opening operation of an outside handle (not shown) as a door handle disposed outside the door (outside the vehicle compartment). The other open action end 312 extends rightward in FIG. 1 and toward the side plate 12 of the base plate 1. The other open action end 312 is related to an opening operation of an inside handle (not shown) as a door handle disposed inside the door (vehicle interior side). The open lever 31 biased by the open lever spring 34 is in a state in which the other open action end 312 is in contact with a component fixed to the base plate 1 side (part of the latch body 21 in this embodiment). The rotation is restricted.

  The link lever 32 is made of a synthetic resin material, and extends in a longitudinal direction from the upper side to the lower side on the left side of the substrate 11 of the base plate 1 in FIG. The upper end portion of the link lever 32 is connected to one open action end portion 311 of the open lever 31. Specifically, a first connection shaft 321 is provided on the front surface (one surface) of the upper end portion of the link lever 32. The link lever 32 is connected to the one open action end 311 via the first connecting shaft 321 in a state where it is pivotally supported. As shown in FIG. 3, a second connecting shaft 322 is provided on the back surface (the other surface) of the upper end portion of the link lever 32. The link lever 32 is slidably engaged with the long hole 351 of the open rod 35 linked to the outside handle (not shown) via the second connecting shaft 322. Further, as shown in FIG. 1, an operating portion 323 extends laterally on the right side portion of the link lever 32. The operating portion 323 is related to the action end portion 272 and the pressing end portion 273 of the ratchet lever 27. An arc-shaped long hole 324 is provided at the lower end of the link lever 32. This long hole 324 is engaged with the lock mechanism side described later.

  The inside handle lever 33 is made of sheet metal, and is arranged so as to be rotatable around the axis of the lever rotation shaft 36 provided on the side plate 12 of the base plate 1 as shown in FIG. And a contact end portion 332. The linkage end 331 is a portion extending upward in FIG. 3 and is connected to an inside handle (not shown) via a cable (not shown). The abutting end portion 332 is a portion extending toward the other open action end portion 312 of the open lever 31 shown in FIG. 1, and when the inside handle lever 33 is rotated clockwise in FIG. This is for abutting the open action end portion 312 and turning the open lever 31 counterclockwise in FIG.

  When the latch mechanism is in the half latch state shown in FIG. 6 or the full latch state shown in FIG. 7, the outside handle is opened and the open rod 35 is pushed downward in FIG. When the inside handle is opened and the inside handle lever 33 rotates clockwise in FIG. 3, the open lever 31 resists against the elastic force of the open lever spring 34 as shown in FIG. Rotate clockwise. As described above, when the open lever 31 is rotated counterclockwise, the link lever 32 moves downward according to the rotation locus of the one open action end 311. The link lever 32 is translated in the downward direction in a state where the upper end portion thereof is pivotally supported by one open action end portion 311 by the first connecting shaft 321 and guided by the long hole 324 in the lower end portion. Along with this movement, the operating portion 323 of the link lever 32 abuts on the action end portion 272 of the ratchet lever 27 and rotates the ratchet lever 27 counterclockwise around the center of the ratchet rotation shaft 26. Then, the ratchet lever 27 and the ratchet 23 rotate integrally, and the contact engagement state between the hook portion 222 of the latch 22 of the latch mechanism and the engagement portion 231 of the ratchet 23 is released as shown in FIG. The door can be opened with respect to the vehicle body.

  When the outside handle is opened and the open rod 35 is pushed downward in FIG. 1, the open lever 31 rotates counterclockwise as shown in FIG. 8 (the open rod 35 in FIG. At this time, the other open action end 312 of the open lever 31 moves away from the contact end 332 of the inside handle lever 33. Therefore, a situation in which the opening operation of the outside handle affects the inside handle side is prevented. Further, when the inside handle is opened and the inside handle lever 33 is rotated clockwise in FIG. 3, the open lever 31 is rotated counterclockwise as shown in FIG. The rotation of the open lever 31 is not transmitted to the open rod 35 by the provided long hole 351. Therefore, the situation in which the opening operation of the inside handle affects the outside handle side is prevented.

  The lock mechanism makes it impossible to transmit the action of the release means described above to the ratchet lever 27 so that the full latch state of the latch mechanism can be locked (maintained). As shown in FIG. is doing.

  The lock lever 41 is made of a synthetic resin material and is provided below the substrate 11 of the base plate 1 as shown in FIG. The lock lever 41 has a lock lever rotation shaft 411, and the lock lever rotation shaft 411 is rotatably supported with respect to the substrate 11. The lock lever 41 has an approximately L shape, and one end thereof extends rightward in FIG. 1 and the other end extends substantially upward. An engagement hole 412 is provided at one end of the lock lever 41, and a lock operation lever 511 is inserted into and engaged with the engagement hole 412. The lock operating lever 511 is provided on the actuator 51 fixed to the side plate 12 of the base plate 1 as shown in FIG. 4, and is a lock operating portion (not shown) provided on the inner side (vehicle interior side) of the door. It is linked to. Further, as shown in FIG. 1, an engagement piece 413 is provided at the other end of the lock lever 41. The engagement piece 413 is inserted into and engaged with a long hole 324 provided in the link lever 32 of the release means. Although not shown in the drawing, when the lock lever 41 is rotated clockwise or counterclockwise around the lock lever rotation shaft 411 in FIG. 1, the rotated state is maintained by a spring. Be energized. In the present embodiment, a ratchet spring (not shown) that constantly biases the rotation direction of the ratchet 23 (and the ratchet lever 27) is used as the spring.

  The key lever 42 is made of a synthetic resin material, and is provided below the substrate 11 of the base plate 1 in a form superimposed on the lock lever 41 as shown in FIG. The key lever 42 has a key lever rotation shaft 421, and the key lever rotation shaft 421 is rotatably supported with respect to the lock lever 41. Note that the key lever rotation shaft 421 is disposed on the same axis as the lock lever rotation shaft 411. The key lever 42 is connected to one end extending to the left in FIG. 1 with a key rod (not shown) linked to a key cylinder (not shown) provided outside the door (outside the vehicle compartment). Further, in the key lever 42, as shown in FIG. 3, a key operation detection lever 512 provided in the actuator 51 is connected to an engagement piece 422 provided at the other end extending rightward in FIG. Further, the key cylinder (not shown) is configured such that the key hole into which the key is inserted is always in a predetermined direction (neutral position). In association with this, the key lever 42 is restricted to the predetermined rotation position shown in FIG.

  As shown in FIG. 1, the lock lever 41 is provided with a notch groove 414 around the axis of the lock lever rotation shaft 411. On the other hand, the key lever 42 is provided with a projecting piece 423 that engages with the notch groove 414. The engagement of the projecting piece 423 with the notch groove 414 has a predetermined play in the rotation direction of the levers 41 and 42.

  The lock mechanism configured as described above is operated when the door is closed with respect to the vehicle body and the latch mechanism is in the fully latched state as shown in FIG. When the lock lever 41 is rotated clockwise about the lock lever rotation shaft 411 as shown in FIG. 9 by the operation of the portion (not shown) or the actuator 51, according to the rotation locus of the engagement piece 413. The link lever 32 rotates. The link lever 32 is pivotally supported at one open action end 311 by the first connecting shaft 321 and the engagement piece 413 of the lock lever 41 is engaged with the long hole 324 at the lower end. As shown in FIG. 9, it rotates counterclockwise with the first connecting shaft 321 as an axis. When the link lever 32 rotates counterclockwise, the operating portion 323 of the link lever 32 moves to the right. In this state, when the release means is operated as described above, the link lever 32 moves in parallel as shown in FIG. 10, but the operating portion 323 does not come into contact with the action end portion 272 of the ratchet lever 27, and the latch 22. The contact engagement state between the hook portion 222 and the engagement portion 231 of the ratchet 23 is not released. As a result, the door is held closed with respect to the vehicle body, and the vehicle can be locked (locked state). Even when the key lever 42 is rotated clockwise about the key lever rotation shaft 421 in FIG. 1 by the key operation from the outside of the door (outside the vehicle compartment), the lock lever 41 is centered on the lock lever rotation shaft 411. Therefore, the locked state described above can be achieved.

  On the other hand, when the lock lever 41 is rotated counterclockwise about the lock lever rotation shaft 411 by the operation of the lock operation unit from the inside of the door (vehicle interior side) or the actuator 51 from the locked state described above. The link lever 32 rotates according to the rotation locus of the engagement piece 413. The link lever 32 is pivotally supported at one open action end 311 by the first connecting shaft 321 and the engagement piece 413 of the lock lever 41 is engaged with the long hole 324 at the lower end. As shown in FIG. 1, the first connecting shaft 321 is pivoted clockwise about the axis. When the link lever 32 rotates clockwise, the operating portion 323 of the link lever 32 moves to the left. In this state, when the release means is operated as described above, the operating portion 323 of the link lever 32 moved in parallel comes into contact with the operating end portion 272 of the ratchet lever 27 as shown in FIG. And the engagement portion 231 of the ratchet 23 are released, and the door can be opened with respect to the vehicle body (unlocked state). Even when the key lever 42 is rotated counterclockwise about the key lever rotation shaft 421 in FIG. 1 by the key operation from the outside of the door (outside the vehicle compartment), the lock lever 41 is interlocked with the lock lever rotation shaft. Since 411 rotates counterclockwise about the axis, the unlocked state described above can be achieved.

  By the way, in the door lock device in the present embodiment, the door is in an open state with respect to the vehicle body, and the lock 22 is locked by an operation of the lock operation unit in a state where the latch 22 is disposed at the open position as shown in FIG. The mechanism is locked (see FIG. 9). Here, the operating portion 323 of the link lever 32 moves rightward and faces the pressing end portion 273 of the ratchet lever 27. When the door is closed from this state, the latch 22 in contact with the striker S rotates clockwise toward the full latch state shown in FIG. For this reason, the ratchet 23 rotates counterclockwise in FIG. 9 with the end surface of the engaging portion 231 slidingly contacting the outer peripheral surface of the latch 22, and the ratchet lever 27 also rotates counterclockwise in the same manner. Then, since the pressing end portion 273 of the ratchet lever 27 pushes the operating portion 323 of the link lever 32 to the left, the link lever 32 rotates counterclockwise and the lock lever 41 rotates counterclockwise. Then, the lock mechanism returns to the unlocked state. In other words, even if the lock mechanism is locked by operating the lock operation unit with the key placed in the vehicle compartment, the lock mechanism returns to the unlocked state when the door is closed. Can be prevented (self-cancellation mechanism). On the other hand, when the door is open with respect to the vehicle body and the lock mechanism is locked by operating the lock operation unit (see FIG. 9), the release handle is operated by opening the outside handle or inside handle. Then, the link lever 32 moves in parallel as shown in FIG. 10, and the operating portion 323 is separated from the pressing end portion 273 of the ratchet lever 27. When the door is closed from this state, the pressing end portion 273 of the ratchet lever 27 does not contact the operating portion 323 of the link lever 32, so that the door can be closed while being locked ( Keyless mechanism).

  When the lock lever 41 rotates clockwise or counterclockwise about the lock lever rotation shaft 411, there is play in the engagement between the notch groove 414 of the lock lever 41 and the protruding piece 423 of the key lever 42. The key lever 42 does not rotate with the lock lever 41. As a result, when the lock lever 41 is rotated about the lock lever rotation shaft 411 by the operation of the lock operation unit from the inside of the door (vehicle interior side) or the actuator 51, the key cylinder (not shown) This prevents the keyhole orientation from changing.

  Hereinafter, assembly of the door lock device described above will be described. 11 is an exploded perspective view of the door lock device shown in FIG. 1 viewed from the front side, FIG. 12 is an exploded perspective view of the door lock device shown in FIG. 1 viewed from the back side, and FIG. 13 is a perspective view showing the base plate. 14 and 15 are perspective views showing the lock lever, FIG. 16 is a perspective view showing the key lever, FIGS. 17 and 18 are perspective views showing the link lever, FIG. 19 is a sectional view showing the assembly of the ratchet rotating shaft, and FIG. FIG. 21 is a rear view showing the assembly of the lock lever and the base plate, and FIGS. 22 to 24 are side views showing the assembly of the base plate and the actuator.

  Here, a configuration of main parts related to the assembly of the door lock device will be described. As shown in FIG. 11, the latch rotation shaft 25 has a first step portion 252 that receives the thickness of the open lever 31 and rotatably supports the open lever 31 on the proximal end side having the retaining collar portion 251. Yes. The latch rotating shaft 25 receives the thickness of the base plate 1, the latch body 21, and the cover plate 24 stacked on the front end side of the first step portion 252, while the latch 22 is interposed between the latch body 21 and the cover plate 24. It has the 2nd step part 253 supported so that rotation is possible.

  As shown in FIG. 11, the ratchet rotation shaft 26 has a first step portion 262 that rotatably supports the ratchet lever 27 by receiving the thickness of the ratchet lever 27 on the proximal end side having the retaining collar portion 261. Yes. The ratchet rotating shaft 26 has a second step portion 263 that receives the thickness of the base plate 1 on the tip side of the first step portion 262. Further, the ratchet rotating shaft 26 is capable of rotating the ratchet 23 between the latch body 21 and the cover plate 24 while receiving the thickness obtained by laminating the latch body 21 and the cover plate 24 on the distal end side of the second step portion 263. It has a third step 264 to be supported.

  As shown in FIG. 13, the base plate 1 has a latch bearing hole 111 through which the latch rotation shaft 25 is inserted and a ratchet bearing hole 112 through which the ratchet rotation shaft 26 is inserted. Furthermore, the base plate 1 has a lock lever bearing hole 113 for rotatably supporting the lock lever 41 on the substrate 11. The lock lever bearing hole 113 is for rotatably supporting the lock lever rotating shaft 411 of the lock lever 41. The lock lever bearing hole 113 has an insertion hole portion 113a through which the lock lever rotation shaft 411 is inserted, and an inner diameter smaller than the insertion hole portion 113a connected to the insertion hole portion 113a. And a bearing hole 113b that is rotatably supported. Further, the base plate 1 has a rotation restricting hole 114 related to the lock lever 41 in the vicinity of the lock lever bearing hole 113 in the substrate 11.

  As shown in FIG. 13, the base plate 1 has an insertion piece 121 for attaching the actuator 51 on the side plate 12. The insertion piece 121 includes a first insertion piece 121a bent toward the substrate 11 so as to be substantially parallel to the substrate 11 from the edge of the side plate 12, and further from the tip of the first insertion piece 121a to the substrate 11. And a pair of second insertion pieces 121b extending toward the substrate 11 so as to be substantially parallel to each other. Furthermore, the base plate 1 has a screw hole 122 for attaching the actuator 51 and the inside handle lever 33 in the side plate 12. The screw hole 122 is formed so as to screw an attachment screw 361 that forms a fastening member described later in the same direction as the direction in which the insertion piece 121 extends.

  As shown in FIG. 14, the lock lever 41 has a lock lever rotating shaft 411 on the back side facing the base plate 1. The lock lever rotating shaft 411 has a flange portion 411b that protrudes radially outward of the rod-shaped portion 411a at the tip of a columnar rod-shaped portion 411a that is integrally extended with the lock lever 41. Furthermore, the lock lever rotation shaft 411 has a shaft hole 411c that penetrates along the center (axial center) of the rod-shaped portion 411a. The flange portion 411b of the lock lever rotation shaft 411 has an outer diameter that can be inserted into the insertion hole portion 113a of the lock lever bearing hole 113 in the base plate 1, and the rod-shaped portion 411a of the lock lever rotation shaft 411 is formed of the lock lever bearing hole. It has an outer diameter that engages with the bearing hole 113b of 113 in a rotatable manner.

  Furthermore, as shown in FIG. 15, the lock lever 41 has a bearing 415 on the front side where the key lever 42 faces. The bearing 415 is for rotatably supporting the key lever rotation shaft 421 of the key lever 42 on the same axis as the lock lever rotation shaft 411 thereof. The bearing 415 is a bowl-shaped body integrally disposed on the lock lever 41 with the axis of the lock lever rotation shaft 411 as the center, and a support piece 415a extending along the axis direction of the lock lever rotation shaft 411; The support piece 415a is formed with a locking piece 415b extending from the upper end toward the axis. A plurality (three in this embodiment) of bearings 415 are arranged around the axis of the lock lever rotating shaft 411 in such a manner that the bearing 415 is opened only in a predetermined direction orthogonal to the axis. The bearing 415 may be provided continuously around the axis of the lock lever rotating shaft 411 as long as it is open only in a predetermined direction orthogonal to the axis.

  Further, as shown in FIGS. 14 and 15, the lock lever 41 has a restricting protrusion 416 extending toward the back side.

  As shown in FIG. 16, the key lever 42 has a key lever rotation shaft 421 on the back side facing the lock lever 41. The key lever rotation shaft 421 has a flange portion 421b that protrudes radially outward of the rod-shaped portion 421a at the tip of a columnar rod-shaped portion 421a that extends integrally with the key lever 42. Further, the key lever rotation shaft 421 has a shaft hole 421c penetrating along the center (axial center) of the rod-shaped portion 421a. The shaft hole 421c has the same inner diameter as the shaft hole 411c provided in the lock lever 41. The flange portion 421b of the key lever rotation shaft 421 has an outer diameter that engages with the support piece 415a of the bearing 415 in the lock lever 41 in a rotatable manner, and the rod-shaped portion 421a of the key lever rotation shaft 421 is engaged with the bearing 415. The outer diameter engages with the stop piece 415b in a rotatable manner.

  As shown in FIG. 17, the link lever 32 is provided with a first connecting shaft 321 on the front surface (one surface) of the upper end portion thereof. The link lever 32 is connected in a state where it is pivotally supported with respect to one open action end 311 of the open lever 31 via the first connecting shaft 321. Note that a pair of locking protrusions 321 a extending in the radially outward direction opposite to the axis of the first connection shaft 321 are provided at the tip of the first connection shaft 321. On the other hand, one open action end 311 of the open lever 31 is provided with a shaft hole 311a (see FIGS. 11 and 12) having a shape including the locking projection 321a and passing through the first connecting shaft 321. That is, when the open lever 31 and the link lever 32 are connected, the locking protrusion 321a is inserted by inserting the first connecting shaft 321 into the shaft hole 311a and rotating the first connecting shaft 321 around the first connecting shaft 321. Engages with the periphery of the shaft hole 311a.

  As shown in FIG. 18, the link lever 32 is provided with a second connection shaft 322 coaxially with the first connection shaft 321 on the back surface (the other surface) of the upper end portion. The link lever 32 is slidably engaged with the long hole 351 of the open rod 35 linked to the outside handle (not shown) via the second connecting shaft 322. Note that a pair of locking projections 322 a extending in the radially outward direction opposite to the axis of the second connecting shaft 322 are provided at the tip of the second connecting shaft 322. Further, a locking claw 322b is provided on the side of the second connecting shaft 322. That is, when the open rod 35 and the link lever 32 are connected, the locking protrusion 322a is formed by inserting the second connecting shaft 322 through the elongated hole 351 and relatively rotating the second connecting shaft 322 around the center. Engages with the periphery of the long hole 351. Further, when the second connecting shaft 322 is inserted into the long hole 351, the locking claw 322b serves as a temporary retaining.

  Here, the assembly of the door lock device will be described. As shown in FIGS. 11 and 12, the door lock device is assembled by inserting each component from the leading end side of the latch rotating shaft 25 and the ratchet rotating shaft 26 facing upward to crimp the leading end. Specifically, the base ends of the latch rotation shaft 25 and the ratchet rotation shaft 26 are appropriately fixed, and each component is inserted therethrough.

  First, as shown in FIG. 19A, after the bearing hole 274 of the ratchet lever 27 is inserted into the first step portion 262 of the ratchet rotating shaft 26, the ratchet bearing hole 112 of the base plate 1 is inserted into the second step portion 263. . At this time, the second step portion 263 protrudes from the surface of the base plate 1. Next, as shown in FIG. 19 (b), the second step portion 263 of the ratchet rotary shaft 26 is caulked to the base plate 1 using a caulking tool A that covers the tip end side of the ratchet rotary shaft 26. On the other hand, the latch bearing hole 111 of the base plate 1 is inserted while the open lever 31 is inserted into the first step portion 252 of the latch rotating shaft 25.

  Next, the latch body 21 is inserted through the second step portion 253 of the latch rotation shaft 25 and the third step portion 264 of the ratchet rotation shaft 26 with the opening 21a facing upward. The latch 22 is inserted into the second step portion 253 of the latch rotating shaft 25 and the ratchet 23 is inserted into the third step portion 264 of the ratchet rotating shaft 26 so that the latch 22 and the ratchet 23 are accommodated in the latch body 21. . Furthermore, the action part 232 of the ratchet 23 and the connecting end part 271 of the ratchet lever 27 are connected. Further, when the latch 22 and the ratchet 23 are accommodated in the latch body 21, a latch spring and a ratchet spring (not shown) are engaged with the latch 22 and the ratchet 23, respectively, and are accommodated in the latch body 21.

  Next, the opening 21 a of the latch body 21 is closed with the cover plate 24, and the leading ends of the latch rotating shaft 25 and the ratchet rotating shaft 26 extending from the cover plate 24 are caulked to the cover plate 24.

  Before the latch body 21 is inserted through the latch rotation shaft 25 and the ratchet rotation shaft 26, the lock lever 41 and the key lever 42 are mounted on the base plate 1 in advance. At this time, the lock lever 41 and the key lever 42 are mounted on the base plate 1 in a pre-overlapped form. Specifically, as shown in FIGS. 20A and 20B, the flange portion 421 b of the key lever rotation shaft 421 of the key lever 42 is engaged with the bearing 415 of the lock lever 41. Then, in a state where the shaft hole 411c of the lock lever 41 and the shaft hole 421c of the key lever 42 are overlapped, the key lever 42 is provided to be rotatable with respect to the lock lever 41 around the key lever rotation shaft 421.

  In order to mount the lock lever 41 and the key lever 42, which are overlapped as described above, to the base plate 1, as shown in FIGS. 21 (a) to 21 (c) (here, the key lever 42 is omitted). The flange portion 411b of the lock lever rotating shaft 411 in the lock lever 41 is inserted into the insertion hole portion 113a of the lock lever bearing hole 113 in FIG. In this state, the lock lever 41 is moved to the bearing hole 113b side to engage the rod-like portion 411a of the lock lever rotating shaft 411 with the bearing hole 113b. Here, the latch body 21 is inserted into the latch rotating shaft 25 and the ratchet rotating shaft 26, and the latch body 21 is attached to the base plate 1. At this time, the support shaft 212 (shown in FIGS. 11 and 12) provided integrally with the latch body 21 is inserted into the shaft hole 411 c of the lock lever 41 and the shaft hole 421 c of the key lever 42. As a result, the lock lever 41 is rotatably supported on the base plate 1, and the key lever 42 is rotatably supported on the lock lever 41.

  In the link lever 32, the first connecting shaft 321 is inserted into the shaft hole 311 a of one open action end 311 in the open lever 31 in a state where the open rod 35 is attached to the second connecting shaft 322. Further, the long hole 324 of the link lever 32 is engaged with the engagement piece 413 of the lock lever 41.

  Finally, the actuator 51 is attached to the base plate 1. In this case, the actuator 51 is attached via the insertion piece 121 and the screw hole 122 provided on the side plate 12 in the base plate 1 shown in FIG. In the actuator 51, as shown in FIG. 22, the insertion hole 513 through which the mounting screw 361 is inserted, the first insertion piece 121a and the second insertion piece 121b of the insertion piece 121 are inserted and engaged, and the mounting screw 361 is tightened. And a groove portion 514 that is engaged only by allowing movement along the axis. Here, the mounting screw 361 is configured as a stepped screw. The stepped portion is inserted into a bearing hole 33a provided in the inside handle lever 33, and the stepped portion serving as the support shaft of the inside handle lever 33 is a lever rotation shaft. 36. When the actuator 51 is attached to the base plate 1, the groove portion 514 of the actuator 51 is inserted into the insertion piece 121 of the base plate 1 as shown in FIG. Next, as shown in FIG. 24, the mounting screw 361 inserted through the inside handle lever 33 is tightened into the screw hole 122 of the base plate 1. Here, the direction in which the actuator 51 is inserted into the insertion piece 121 is the same as the direction in which the mounting screw 361 is tightened.

  In the door lock device described above, as a mounting structure of a lever that rotatably mounts the lock lever 41 to the base plate (predetermined base) 1, the rod-shaped portion is attached to the tip of a rod-shaped portion 411 a that extends integrally with the lock lever 41. A lock lever rotating shaft 411 having a flange portion 411b protruding outward in the radial direction of 411a and a base plate 1 provided on the base plate 1 and moving while guiding the lock lever rotating shaft 411 so as to be movable in a predetermined direction orthogonal to the axis. The base plate 1 is provided with a bearing hole (bearing) 113 that engages with the flange portion 411b at the position and restricts the movement of the lock lever rotation shaft 411 in the direction along the axis and rotatably supports the lock lever rotation shaft 411. A support shaft (regulating member) 2 that restricts the movement of the lock lever rotating shaft 411 in the direction orthogonal to the shaft center. And a 2. As a result, it is possible to easily attach the lock lever 41 without using a bolt or the like on the rotating shaft, and to have sufficient attachment strength against external force.

  Further, the support shaft 212 is inserted into a shaft hole 411c provided in the lock lever 41 along the axis of the lock lever rotation shaft 411, and can cooperate with the lock lever bearing hole 113 to rotate the lock lever rotation shaft 411. It consists of a supporting shaft. As a result, the lock lever 41 can be attached in a state where the rotation is smooth.

  Further, as a mounting structure of a lever that is rotatably attached to the base plate (predetermined base) 1 in a form in which the lock lever (first lever) 41 and the key lever (second lever) 42 are overlapped, the lock lever 41 A lock lever rotation shaft (first rotation shaft) 411 having a flange portion 411b protruding in a radially outward direction of the rod-shaped portion 411a at the tip of the rod-shaped portion 411a integrally extending to the lock plate, and a lock lever provided on the base plate 1 The rotary shaft 411 is engaged with the flange portion 411b at a position where the rotary shaft 411 is moved while being guided so as to be movable in a predetermined direction perpendicular to the axis, and the movement of the lock lever rotary shaft 411 in the direction along the axis is restricted. A lock lever bearing hole (first bearing) 113 that rotatably supports the lock lever rotating shaft 411 and the key lever 42 are integrally extended. A key lever rotation shaft (second rotation shaft) 421 having a flange portion 421b projecting radially outward of the rod-shaped portion 421a at the tip of the rod-shaped portion 421a, and a lock lever 41 provided on the key lever rotation shaft 421. Engages with the flange portion 421b at a position moved while being guided so as to be movable in a predetermined direction orthogonal to the center, and restricts the movement of the key lever rotating shaft 421 in the direction along the axis and locks the key lever rotating shaft 421 to the lock lever. A bearing (second bearing) 415 that is rotatably supported on the same axis as the rotating shaft 411, and the lock lever rotating shaft 411 and the key lever rotating shaft 421 are moved in a direction fixed to the base plate 1 and perpendicular to the axis. A supporting shaft (regulating member) 212 to be regulated is provided. As a result, it is possible to easily attach the lock lever 41 and the key lever 42 without using a bolt or the like on the rotating shaft, and to have sufficient attachment strength against external force. In this case, the key lever rotation shaft 421 may be provided on either the lock lever 41 or the key lever 42, and the bearing 415 may be provided on either the lock lever 41 or the key lever 42.

  Further, the support shaft (regulating member) 212 includes a shaft hole 411 c provided in the lock lever 41 along the axis of the lock lever rotation shaft 411 and a shaft hole 421 c provided in the key lever 42 along the axis of the key lever rotation shaft 421. And a rod shaft that rotatably supports the lock lever rotating shaft 411 and the key lever rotating shaft 421 in cooperation with the lock lever bearing hole 113 and the bearing 415. As a result, the lock lever 41 and the key lever 42 can be attached so as to be smoothly rotatable.

  Further, the link lever 32 is connected to the open lever 31, and the open rod 35 connected to the outside handle is connected to the open lever 31, and the operation of the outside handle is routed from the open lever 31 to the link lever 32. As a door lock device for releasing the latch mechanism, a first connecting shaft 321 that swingably engages the link lever 32 with the open lever 31, and an open rod 35 that slidably engages with the link lever 32. The second connecting shaft 322 is integrally provided on the link lever 32. As a result, it is possible to reduce the number of parts for connecting the open lever 31, the link lever 32, and the open rod 35, and to reduce the size of the apparatus.

  Further, the first connecting shaft 321 is provided on one surface of the link lever 32, and the second connecting shaft 322 is provided on the other surface of the link lever 32. As a result, since the connecting portions of the open lever 31, the link lever 32, and the open rod 35 are concentrated on one surface and the other surface in the area of the surface of the link lever 32, the apparatus can be downsized. Become.

  Further, the first connecting shaft 321 and the second connecting shaft 322 are arranged coaxially. As a result, it is possible to reduce the transmission load of the operating force that passes the operation of the outside handle from the open lever 31 to the link lever 32.

  Further, the link lever 32 is formed of a synthetic resin material with a first connecting shaft 321 and a second connecting shaft 322. As a result, the sliding resistance with the open lever 31 and the open rod 35 can be reduced, and the weight of the device can be reduced.

  Further, the latch 22 and the ratchet 23 are accommodated in a latch body (accommodating portion) 21 whose one surface is open, and a cover plate 24 that closes the opening 21a of the latch body 21 and the other surface of the latch body 21 are attached. The latch body 21 is sandwiched between the base plate 1 and the latch rotating shaft 25 for supporting the latch 22 and the ratchet rotating shaft 26 for supporting the ratchet 23. The latch body 21 is integrally formed with the ratchet 23. As a door lock device in which the rotating ratchet lever 27 is supported on the ratchet rotating shaft 26 at a position outside the base plate 1, the ratchet rotating shaft 26 rotatably supports the ratchet lever 27 on the base end side having the retaining bar 261. And the thickness of the base plate 1 is received at the tip side of the first step 262. A second step portion 263, the ratchet lever 27 is inserted into the first step portion 262, and the base plate 1 is inserted into the second step portion 263. It becomes. As a result, by attaching the ratchet rotating shaft 26 to the base plate 1 in advance, it becomes possible to improve the assembly workability while suppressing the play in the axial direction of the ratchet lever 27.

  Further, the latch body 21 having one surface opened and the latch 22 and the ratchet 23 are accommodated. The cover plate 24 that closes the opening 21a of the latch body 21 and the base plate 1 to which the other surface of the latch body 21 is attached. As a form in which the latch body 21 is sandwiched between them, the latch rotating shaft 25 that supports the latch 22 and the ratchet rotating shaft 26 that supports the ratchet 23 pass through the ratchet 23 and rotate integrally with the ratchet 23. As a method of assembling the door lock device in which the lever 27 is supported on the ratchet rotation shaft 26 at a position outside the base plate 1, the base plate 1 is inserted into the ratchet rotation shaft 26 through which the ratchet lever 27 is rotatably inserted. 26 is fixed to the base plate 1 while the ratchet A step of inserting the base plate 1 into the latch rotary shaft 25 oriented in the same direction as the rotary shaft 26, and the latch body 21 through the ratchet rotary shaft 26 and the latch rotary shaft 25 in a manner following the base plate 1 A step of crimping the distal ends of the rotary shafts 25 and 26 from the outside of the cover plate 24 that closes the opening 21a of the latch body 21 after the latch 22 and the ratchet 23 are inserted into the 25 and 26. As a result, the ratchet rotary shaft 26 and the latch rotary shaft 25 are caulked from the same direction, so that the assembly workability can be improved while suppressing the play of the ratchet lever 27 in the axial direction.

  In the above-described embodiment, only the ratchet rotation shaft 26 is attached to the base plate 1 in advance. Similarly, the latch rotation shaft 27 may be attached to the base plate 1 in advance.

  In addition, as a door lock device configured to operate the latch mechanism or the lock mechanism by driving the actuator 51, the insertion piece 121 is formed on the base plate 1 to which the latch mechanism is attached, and the groove portion 514 of the actuator 51 is inserted into the insertion piece 121. The actuator 51 is fixed to the base plate 1 while the detachment from the insertion piece 121 is restricted by a mounting screw 361 (fastening member) that forms a support shaft of the inside handle lever 33 that operates the latch mechanism. As a result, since the actuator 51 is attached to the base plate 1 by the insertion piece 121, the groove 514, and the attachment screw 361, the attachment workability of the actuator 51 can be improved. Depending on the driving of the actuator 51, it is possible to release the engagement between the latch 22 and the ratchet 23 in the latch mechanism, or to switch the lock mechanism to the locked state or the unlocked state.

  Further, the insertion piece 121 and the groove portion 514 allow the movement along the direction in which the mounting screw 361 is tightened and insert the actuator 51 into the base plate 1. As a result, the direction in which the actuator 51 is inserted into the base plate 1 and the direction in which the mounting screw 361 is tightened are the same direction, so that the workability of mounting the actuator 51 can be improved.

  Further, the mounting screw 361 has one step portion that rotatably supports the inside handle lever 33. As a result, it is possible to suppress backlash and excessive tightening during rotation of the inside handle lever 33 while attaching the three members of the base plate 1, the actuator 51, and the inside handle lever 33.

  In the present embodiment, the fastening member is the mounting screw 361, but can be changed as appropriate.

It is a front view which shows an example of the door lock apparatus which employ | adopted the attachment structure of the lever which concerns on this invention. It is a rear view of the door lock apparatus shown in FIG. It is a left view of the door lock apparatus shown in FIG. It is a right view of the door lock apparatus shown in FIG. It is a figure which shows operation | movement of a latch mechanism. It is a figure which shows operation | movement of a latch mechanism. It is a figure which shows operation | movement of a latch mechanism. It is a front view of a door lock device showing release operation of a latch mechanism. It is a front view of the door lock device which shows the locked state of a lock mechanism. It is a front view of the door lock device which shows the locked state of a lock mechanism. It is the disassembled perspective view which looked at the door lock apparatus shown in FIG. 1 from the front side. It is the disassembled perspective view which looked at the door lock apparatus shown in FIG. 1 from the back side. It is a perspective view which shows a base plate. It is a perspective view which shows a lock lever. It is a perspective view which shows a lock lever. It is a perspective view which shows a key lever. It is a perspective view which shows a link lever. It is a perspective view which shows a link lever. It is sectional drawing which shows the assembly of a ratchet rotating shaft. It is a front view which shows the assembly of a lock lever and a key lever. It is a rear view which shows the assembly of a lock lever and a base plate. It is a side view which shows the assembly of a base plate and an actuator. It is a side view which shows the assembly of a base plate and an actuator. It is a side view which shows the assembly of a base plate and an actuator.

Explanation of symbols

1 Base plate 11 Substrate (base)
111 Latch bearing hole 112 Ratchet bearing hole 113 Lock lever bearing hole (bearing, first bearing)
113a Insertion hole (bearing, first bearing)
113b Bearing hole (bearing, first bearing)
114 Rotation Restriction Hole 12 Side Plate 121 Insertion Piece 121a First Insertion Piece 121b Second Insertion Piece 122 Screw Hole 21 Latch Body 21a Opening 211 Horizontal Notch Groove 212 Support Shaft (Regulation Member, Bar Shaft)
22 Latch 221 Engagement groove 222 Hook part 223 Locking part 23 Ratchet 231 Engagement part 232 Action part 24 Cover plate 241 Horizontal notch groove 25 Latch rotation shaft 251 Unlocking flange part 252 First step part 253 Second step part 26 Ratchet rotation shaft 261 Stopper 262 First stage 263 Second stage 264 Third stage 27 Ratchet lever 271 Connection end 272 Action end 273 Press end 274 Bearing hole 31 Open lever 311 One open action end 311a Shaft hole 312 The other open action end 32 Link lever 321 First connecting shaft 321a Locking protrusion 322 Second connecting shaft 322a Locking protrusion 322b Locking claw 323 Actuator 324 Long hole 33 Inside handle lever 33a Bearing hole 331 Linking end 332 Contact end 34 Open lever -Spring 35 Open rod 351 Long hole 36 Lever rotating shaft 361 Mounting screw 41 Lock lever (lever, first lever)
411 Lock lever rotation axis (rotation axis, first rotation axis)
411a Rod-shaped part (rotating shaft, first rotating shaft)
411b Flange (Rotating shaft, First rotating shaft)
411c Shaft hole 412 Engagement hole 413 Engagement piece 414 Notch groove 415 Bearing (second bearing)
415b Locking piece (second bearing)
415a Support piece (second bearing)
416 Restriction protrusion 42 Key lever (second lever)
421 Key lever rotation axis (second rotation axis)
421a Rod-shaped part (second rotating shaft)
421b Flange (second rotary shaft)
421c Shaft hole 422 Engagement piece 423 Projection piece 51 Actuator 511 Lock operation lever 512 Key operation detection lever 513 Insertion hole 514 Groove A Crimping tool S Strike

Claims (3)

In the mounting structure of the lever that rotatably mounts the lever with respect to a predetermined base,
A rotating shaft having a flange portion projecting radially outward of the rod-shaped portion at the tip of the rod-shaped portion integrally extending with the lever;
The rotating shaft is moved in a direction along the axis by engaging with the flange portion at a position provided on the base and movably guiding the rotating shaft in a predetermined direction perpendicular to the axis. A bearing that regulates and rotatably supports the rotating shaft;
And a regulating member for regulating movement of said rotation axis in a direction perpendicular to the axis,
The restriction member includes a rod shaft that is inserted into a shaft hole provided in the lever along the axis of the rotation shaft, and that supports the rotation shaft in a rotatable manner in cooperation with the bearing . Mounting structure. In the mounting structure of the lever that is rotatably mounted independently with respect to a predetermined base in a form in which the first lever and the second lever are overlapped,
  A first rotating shaft having a flange portion projecting radially outward of the rod-shaped portion at the tip of the rod-shaped portion integrally extending to the first lever;
  A first rotation shaft that is provided at the base and engages with the flange portion at a position moved while guiding the first rotation shaft so as to be movable in a predetermined direction orthogonal to the axis, and in a direction along the axis. A first bearing that restricts the movement of the first rotation shaft and rotatably supports the first rotation shaft;
  A second rotating shaft having a flange portion projecting in the radially outward direction of the rod-shaped portion at the tip of the rod-shaped portion integrally extended to either the first lever or the second lever;
  It is provided on either the first lever or the second lever, and engages with the flange portion at a position moved while guiding the second rotation shaft so as to be movable in a predetermined direction perpendicular to the axis. A second bearing that restricts movement of the second rotary shaft in a direction along the center and supports the second rotary shaft rotatably on the same axis as the first rotary shaft;
  A regulating member that regulates movement of the first rotating shaft and the second rotating shaft in a direction orthogonal to the axis;
  The restricting member is inserted through a shaft hole provided in the first lever along the axis of the first rotation shaft and a shaft hole provided in the second lever along the axis of the second rotation shaft. A lever mounting structure comprising a rod shaft that rotatably supports the first rotating shaft and the second rotating shaft in cooperation with one bearing and the second bearing. In the mounting structure of the lever that rotatably mounts the lever with respect to a predetermined base,
  A rotating shaft having a flange portion projecting radially outward of the rod-shaped portion at the tip of the rod-shaped portion integrally extending with the lever;
  It is provided in the base, and moves while guiding the rotary shaft so as to be movable in a predetermined direction perpendicular to the axis by inserting the flange portion of the lever from one surface side of the base portion to the other surface side. A bearing that engages with the flange portion at a position to restrict movement of the rotating shaft in a direction along the axis, and rotatably supports the rotating shaft;
  A lever mounting structure comprising: a restricting member that is attached to the other surface side of the base and restricts the movement of the rotating shaft in a direction orthogonal to the axis.

Images