JP5226273B2 - Compound tablet - Google Patents

Description

  The present invention relates to a composite lock that can be suitably used, for example, when connecting a door panel to a moving partition panel.

  In order to lock a door, a sliding door, etc. installed in an opening of a building, a lock and sickle lock are widely used in general (for example, Non-Patent Document 1 and Patent Document 1).

The present locking can be locked by causing the dead bolt in the casing to linearly advance from the front surface by the rotation of an operation member such as a key or thumb turn, and engaging the dead bolt with the seat. Further, the sickle lock is locked by engaging a sickle bolt with the sickle bolt rotating from the casing while rotating in a circular arc shape.
Seven Shigende, Architectural Dictionary, Shokokusha (October 10, 1974), 279, 1440 JP-A-8-254053

  In the case of such prior art, since the main locking and sickle locks are limited to a single door or sliding door, for example, when a hinged door panel is connected to a suspended moving partition panel. Assuming that both the partition panel and the door panel need to be provided with individual locks and sickle locks, the locking operation tends to be complicated and the appearance is not good.

  Therefore, the object of the present invention is to easily lock two types of locking objects such as a moving partition panel and a door panel by connecting the main lock and the sickle lock, and to improve the appearance appearance. The object is to provide a composite tablet that can be put together.

  In order to achieve this object, the structure of the present invention comprises a main locking mechanism that advances and retracts a dead bolt by rotation of an operation member, and a sickle lock that advances and retracts a sickle bolt by rotation of the operation member. The sickle lock connects the respective rotation shafts so that the advance directions of the dead bolt and the bolt are orthogonal to each other, and the present locking is the rotation angle of the operation member (0 to 90) °, (90 to 180) Each range of ° is set as a dead bolt locking section and a transition section, respectively, while the sickle lock is used for each rotation angle range (0 to 90) ° and (90 to 180) ° of the operation member. The gist is to set the lock section.

  The locking can be provided with a stopper that prevents the dead bolt from advancing, and the stopper can allow the dead bolt to advance when the locking target of the locking is at a predetermined locking position. it can.

  Further, the locking target of the sickle lock may be a suspended moving partition panel, and the locking target of the main locking may be a door panel connected to one end of the moving partition panel via a hinge.

  According to the configuration of the present invention, the main locking and sickle locks have their respective rotating shafts connected to each other, and by rotating a common operation member, the dead bolt and the bolt are advanced in two directions orthogonal to each other. Can be made. Therefore, for example, a bolt of a sickle lock is advanced downward from the lower end of the moving partition panel, engaged with a seat on the floor surface to lock the moving partition panel, and a door panel connected to the moving partition panel via a hinge. The door panel can be locked by moving the dead bolt of the main locking lock horizontally and engaging with a seat in the door panel. The operating member here is a thumb turn, a key, a handle, or the like that rotates the rotating shaft, and may be mounted on the casing of the main locking and connected to the rotating shaft of the main locking, for example. Further, it is preferable that the rotary shafts of the main lock and the sickle lock are connected so as not to be relatively rotatable and to be separable.

  The stopper attached to the main lock prevents the dead bolt from advancing, thereby restraining the operation member to be non-rotatable and maintaining the locked state by, for example, a sickle lock stably. Further, the stopper allows the dead bolt to advance when the lock target of the final lock is at a predetermined lock position, and can securely lock the lock target.

  The main lock and sickle lock are the rotation angle (0 to 90) ° of the first half of the rotation range (0 to 180) ° of the common operation member, and the rotation angle (90 to 180) ° of the second half. Are divided into a dead bolt locking section, a transition section, a bolt transition section, and a locking section, respectively, so that the required operation force of the operation member can be kept small and the operation can be performed smoothly. Both of the objects to be locked can be locked, and any one can be selected and locked. However, the locking section here refers to the section where the dead bolt or bolt is advanced and held in the locked state outside the casing, and the transition section is the unlocked state where the dead bolt or bolt is inside the casing, This refers to the section that moves forward and backward between the external locked states.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  The composite lock is formed by integrally connecting the lock 10 and the sickle lock 20 (FIGS. 1 and 2). However, FIGS. 2A and 2B are respectively an equivalent view taken along line XX in FIG. 1 and an equivalent view taken along line YY in FIG.

  The lock 10 incorporates a rotating shaft 12 with a thumb turn 12 a into a casing 11 and has a dead bolt 13 that advances from the front surface 11 a side of the casing 11. The dead bolt 13 can be linearly advanced and retracted from the front surface 11a by rotating the rotating shaft 12 forward and backward via the thumb turn 12a. However, a stopper 14 for preventing the advancement of the dead bolt 13 is additionally provided on the front surface 11a side of the casing 11 as necessary.

  The stopper 14 is assembled to the casing 11 in combination with the guide frame 11c integrated with the casing 11 on the front surface 11a side of the casing 11 in which the dead bolt 13 advances (FIG. 3). However, FIGS. 3A and 3B are an exploded perspective view of main parts, respectively, and an enlarged cross-sectional view corresponding to the direction of arrows ZZ in FIG.

  The left and right sides of the stopper 14 are connected to the guide frame 11c via springs 14a. Both ends of the spring 14a are connected to a stopper 14 and set screws 14b and 14b fixed to the guide frame 11c. Accordingly, the stopper 14 is constantly urged to the position where the window 11b of the casing 11 into which the dead bolt 13 advances through the springs 14a and 14a, and can prevent the dead bolt 13 from moving forward (FIG. 3 ( On the other hand, the stopper 14 is moved against the springs 14a and 14a by applying an external force, and the window 11b is opened (the one-dot chain line in FIG. 3B), so that the dead bolt 13 advances. Can be allowed (the two-dot chain lines in FIGS. 3A and 3B). When the dead bolt 13 advances from the window 11b, the stopper 14 is blocked by the dead bolt 13 and cannot close the window 11b. When the dead bolt 13 moves backward into the casing 11, the stopper 14 automatically closes the window 11b. .

  The sickle lock 20 incorporates a rotating shaft 22 with respect to the casing 21 and has a sickle-shaped bolt 23 (FIGS. 1 and 2). The bolt 23 can be moved forward and backward so as to rotate from the front surface 21 a side of the casing 21 by rotating the rotating shaft 22 forward and backward. However, the rotary shaft 22 of the sickle lock 20 is connected to the rotary shaft 12 so as not to be rotatable relative to the rotary shaft 12 in a separable manner via a socket (not shown) that is detachably fitted to the tip of the rotary shaft 12 of the lock 10. Yes. Therefore, the bolt 23 of the sickle lock 20 can be driven in conjunction with the dead bolt 13 of the main locking 10 via the thumb turn 12 a of the main locking 10. The casings 11 and 21 of the main locking 10 and sickle lock 20 are connected via large and small spacers 21b and 21b that are fixed to the casing 21 side.

  The lock 10 is attached to the surface of the lower collar 31a of the suspended moving partition panel 31 (FIGS. 1 and 4). However, FIGS. 4A to 4D are a schematic plan view, a schematic front view, an enlarged plan view, and an enlarged front view, respectively, showing an attachment state of the lock 10.

  A door panel 32 that can be folded on the moving partition panel 31 is connected to one end of the moving partition panel 31 via a hinge 33. The lock 10 is as shown in FIGS. 4 (A) and 4 (B). The door panel 32 can be folded and locked on the moving partition panel 31. That is, the dead bolt 13 of the lock 10 can be engaged with the receiving seat 34 attached to the front end surface of the lower collar 32a of the door panel 32 with the door panel 32 as a lock target. Further, the stopper 14 folds the door panel 32 on the moving partition panel 31, and when the door panel 32 is at a predetermined locking position, the stopper 14 engages with the tip of the lower collar 32a of the door panel 32 to open the window 11b. However, the advancement of the dead bolt 13 can be permitted.

  On the other hand, the sickle lock 20 is incorporated downward in the lower collar 31a of the moving partition panel 31 so as to correspond to the lock 10 (FIGS. 1 and 2). The locking target of the sickle lock 20 is the movement partition panel 31. Therefore, the bolt 23 of the sickle lock 20 is engaged with the receiving seat 35 installed on the floor surface FL to lock the movement partition panel 31 so as not to move. (The solid line in FIG. 2 (A)), the moving partition panel 31 can be removably released by moving back into the casing 21 (two-dot chain line in FIG. 2).

  The dead bolt 13 of the lock 10 and the bolt 23 of the sickle lock 20 are rotated into the casings 11 and 21 respectively by rotating a common thumb turn 12a on the lock 10 and are moved into the casings 11 and 21, respectively. It is possible to shift to a reverse unlocking state. For example, when the rotation angle θ of the thumb turn 12a is 0 ° (FIG. 4), the dead bolt 13 advances to the locked state and locks the door panel 32 in the locked position, while the bolt 23 retracts to the unlocked state. Then, the moving partition panel 31 is released to be movable. Therefore, the moving partition panel 31 can be arbitrarily moved safely together with the folded door panel 32. At this time, the stopper 14 allows the dead bolt 13 to advance by the door panel 32 being folded over the moving partition panel 31 and being in the locked position.

  When the moving partition panel 31 is moved to a predetermined position and the thumb turn 12a is rotated by 90 °, the bolt 23 advances to the locked state (FIG. 5), and the moving partition panel 31 is locked so as not to move. At this time, the dead bolt 13 keeps the locked state, and keeps the door panel 32 locked. 5A to 5D correspond to FIGS. 4A to 4D, respectively, along with FIGS. 6A to 6D.

  Subsequently, when the thumb turn 12a is further rotated by 90 ° (FIG. 6), the dead bolt 13 is retracted to the unlocked state, and the door panel 32 is released so as to be opened and closed. Therefore, the door panel 32 can be opened on the extension line of the moving partition panel 31 to complete, for example, a seal with a wall surface (not shown). When the door panel 32 is opened, the stopper 14 automatically closes the window 11b for the advancement of the dead bolt 13 and prevents the advancement of the dead bolt 13, so that the thumb turn 12a is restrained so as not to rotate. There is no possibility that the locking of the moving partition panel 31 by the sickle lock 20 is inadvertently released.

  Further, in FIG. 6, the door panel 32 is folded over the moving partition panel 31 and returned to the locked position, so that the advancement of the dead bolt 13 by the stopper 14 can be released and the restraint of the thumb turn 12a can be released. Therefore, when the thumb turn 12a is rotated 90 ° in the reverse direction, the dead bolt 13 advances to lock the door panel 32 (FIG. 5), and when the thumb turn 12a is further rotated 90 ° in the reverse direction, the door panel 32 is locked. In this state, the bolt 23 can be moved backward to unlock the moving partition panel 31 (FIG. 4).

  The operation of the dead bolt 13 and the bolt 23 in FIGS. 4 to 6 is shown in FIG. 7 in correspondence with the rotation angle θ of the thumb turn 12a. However, in FIG. 7, curves 13 and 23 indicate the operations of the dead bolt 13 and the bolt 23, respectively. In FIG. 7, the range of rotation angle θ = (0 to 90) ° of the thumb turn 12a is the locking section of the dead bolt 13 that holds the dead bolt 13 in the locked state, and the bolt 23 that shifts the bolt 23 from the unlocked state to the locked state. 23, and the range of the rotation angle θ = (90 to 180) ° is the dead zone 13 transition zone and the bolt 23 locking zone. When the dead bolt 13 is retracted to the unlocked state at the rotation angle θ = 180 ° of the thumb turn 12a, the stopper 14 automatically prevents the dead bolt 13 from advancing (arrow 14 in FIG. 7). The operations of the dead bolt 13 and the bolt 23 in FIG. 7 reversibly correspond to the forward and reverse rotation of the thumb turn 12a at the rotation angle θ = (0 to 180) °, except for the operation of the stopper 14.

  An example of the internal mechanism of the main locking 10 and sickle lock 20 is shown in FIGS. However, each of (A) and (B) in FIGS. 8 to 12 is a schematic diagram of the internal structure of the sickle lock 20 corresponding to FIG. 2 (A), the final locking 10 equivalent to FIG. Each (C) is a schematic front view showing the internal structure of the lock 10. 8, 10, and 12, the final lock 10 and the sickle lock 20 are respectively shown in FIGS. 4, 5, and 6, the rotation angle θ = 0 °, 90 °, It corresponds to 180 °. 9 and 11 correspond to rotation angles θ = 45 ° and 135 °, respectively.

  8B and 8C, the rotating shaft 12 and the dead bolt 13 of the lock 10 are assembled to the frame body 15 in the casing 11. A pair of front and rear cam plates 12b, 12b are attached to the rotary shaft 12 in the same phase, and the dead bolt 13 has drive pins 13a movable along the front and rear long holes 15a, 15a of the frame body 15. It penetrates. Also, one end of the front and rear links 13b and 13b is rotatably connected to both ends of the drive pin 13a. The ends of the links 13b, 13b on the cam plate 12b, 12b side are connected via a common moving pin 13c, and the moving pin 13c is slidable in the front and rear guide slits 15b, 15b of the frame body 15. Can move. Each guide slit 15 b is formed in a quadrant around the rotating shaft 12.

  Further, the moving pin 13c slidably penetrates the long hole 16a at the tip end portion of the swing link 16, and the base portion of the swing link 16 is rotatably connected to the fixed pin 15c on the frame body 15. ing. The swing link 16 is provided with a spring 16b between the fixed pin 15c and the moving pin 13c. Further, the frame body 15 is provided with stopper pins 15d which are in contact with the cam plates 12b and 12b and limit the rotation shaft 12 and the rotation angle θ ≦ 180 ° of the thumb turn 12a. However, in FIG. 8C, the swing link 16 with the spring 16b is also shown as a separate drawing.

  8 (A) and 8 (B), the sickle lock 20 is configured by incorporating a rotating shaft 22 and a bolt 23 in a casing 21 with spacers 21b and 21b. A pair of front and rear cam plates 22 b, 22 b is attached to the rotating shaft 22, and the bolt 23 is rotatable around a fixed pin 23 a on the casing 21. A slit 23b is formed at the tip of the bolt 23 on the cam plate 22b, 22b side, and a moving pin 23c that moves along the guide slits 21c, 21c before and after the casing 21 is slidable in the slit 23b. Is engaged. Each guide slit 21 c is formed in a quadrant around the rotating shaft 22.

  One end of a swing link 24 is rotatably connected to the fixed pin 23a. A moving pin 23c is slidably passed through the long hole 24a at the tip of the swing link 24, and a spring 24b is mounted on the swing link 24 between the fixed pin 23a and the move pin 23c. . In addition, the casing 21 is provided with stopper pins 21d that are in contact with the cam plates 22b and 22b and limit the rotation shaft 22 and the rotation angle θ ≦ 180 ° of the thumb turn 12a. However, FIG. 8A shows only one of the front and rear cam plates 22b and 22b and the front and rear guide slits 21c and 21c, respectively, and a swing link 24 with a spring 24b is also shown as a separate figure. Is shown.

  In FIG. 8, the dead bolt 13 of the lock 10 has advanced to the locked state by the drive pin 13a positioned at the tip of the long holes 15a, 15a via the links 13b, 13b. The links 13b, 13b It arrange | positions in parallel with the long holes 15a and 15a via the movement pin 13c positioned by the cam plates 12b and 12b and the guide slits 15b and 15b. At this time, the spring 16b on the swing link 16 is sufficiently extended. On the other hand, the bolt 23 of the sickle lock 20 is positioned around the fixed pin 23a via the moving pin 23c positioned at one end of the guide slits 21c and 21c while being fitted into the notches of the cam plates 22b and 22b. The spring 24b on the swing link 24 is fully extended.

  Therefore, when the rotary shafts 12 and 22 are rotated in the forward direction via the thumb turn 12a (in the directions of the arrows in FIGS. 8C and 8A), the moving pin 23c of the sickle lock 20 is connected to the cam plates 22b and 22b. By moving in the guide slits 21c and 21c with rotation, the bolt 23 is rotated counterclockwise around the fixing pin 23a (in the directions of the arrows K2 in FIGS. 8A and 9A), and the thumb turn 12a. At the rotation angle θ = 90 °, the bolt 23 can be driven into a locked state (FIGS. 10A and 10B). At this time, the moving pin 23c moves toward the fixed pin 23a in the long hole 24a of the swing link 24 according to the rotation of the cam plates 22b and 22b, and pushes the spring 24b as short as possible at the rotation angle θ = 45 °. Shrink (FIG. 9A). Therefore, the spring 24b changes the operating force of the thumb turn 12a so as to be maximum at the rotation angle θ = 45 °, and the comfortable operation of the thumb turn 12a until the bolt 23 is advanced from the unlocked state to the locked state. A feeling can be realized.

  On the other hand, in the present locking 10, at the rotation angle θ = (0 to 90) °, the position of the moving pin 13c is kept constant even when the cam plates 12b and 12b are rotated. It is held (each (B), (C) in FIGS. 8 to 10).

  The bolt 23 of the sickle lock 20 is held in a locked state even when the rotation shaft 22 is rotated at a rotation angle θ> 90 ° (FIGS. 10 to 12 (A) and (B)). At this time, the moving pin 23c is kept at a fixed position even when the cam plates 22b and 22b rotate.

  On the other hand, the lock 10 can shift the dead bolt 13 from the locked state to the unlocked state at the rotation angle θ = (90 to 180) ° (see FIGS. 10 to 12 (B) and (C). )). The moving pin 13c engaged with the fan-shaped protrusions of the cam plates 12b and 12b at the rotation angle θ = 90 ° guides the guide slit while compressing the spring 16b on the swing link 16 as the cam plates 12b and 12b rotate. It is because it moves along 15b and 15b, and it drives so that the dead bolt 13 may be retracted to the unlocked state via the links 13b and 13b and the drive pin 13a (FIG. 10C, FIG. 11C). Each arrow K1 direction). In addition, the spring 16b is compressed and shortened to the shortest at the rotation angle θ = 135 °, and when the dead bolt 13 is shifted from the locked state to the unlocked state, a comfortable operational feeling of the thumb turn 12a can be realized.

  On the other hand, when the dead bolt 13 is completely retracted to the unlocked state (FIGS. 12B and 12C), the stopper 14 moves to the front of the dead bolt 13 via the springs 14a and 14a. Block advancement. 12 can be returned to the original state of FIG. 8 by rotating the rotary shafts 12 and 22 through 180 degrees in the reverse direction via the thumb turn 12a.

  In the above description, the thumb turn 12a for rotating the rotary shafts 12 and 22 may be replaced with an operation member such as a key or a handle, and instead of being mounted on the main locking 10 side, it is mounted on the sickle lock 20 side. May be. Moreover, instead of combining the dead bolt 13 and the bolt 23 leftward and downward as shown in FIGS. 4 to 6, the present locking lock 10 and sickle lock 20 may be combined rightward and downward, respectively. That is, the lock 10 and the sickle lock 20 can be combined in any direction so that the advance directions of the dead bolt 13 and the bolt 23 are orthogonal to each other. Further, each lock target of the main locking 10 and sickle lock 20 may be a combination of other arbitrary moving members instead of the door panel 32 and the moving partition panel 31.

Usage plan 1 is an explanatory diagram of the main part configuration of FIG. Main part configuration diagram of this lock Usage state explanatory diagram (1) Usage state diagram (2) Usage state diagram (3) Operation explanation diagram Operation explanatory diagram (1) Operation explanatory diagram (2) Operation explanatory diagram (3) Operation explanatory diagram (4) Operation explanatory diagram (5)

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... This lock 12 ... Rotating shaft 13 ... Dead bolt 14 ... Stopper 20 ... Sickle lock 22 ... Rotating shaft 23 ... Bolt

Patent Applicant Komatsu Wall Industry Co., Ltd.
Attorney Tadaaki Matsuda, Attorney

Claims (4)

A main lock that advances and retracts the dead bolt by rotation of the operation member, and a sickle lock that advances and retracts the sickle-shaped bolt by rotation of the operation member, the main lock and the sickle lock include the dead bolt and the bolt The rotary shafts are connected so that the advancing directions are orthogonal to each other , and the locking mechanism has a dead angle in each range of rotation angles (0 to 90) ° and (90 to 180) ° of the operation member. While the bolt locking section and the transition section are set, the sickle lock has a range of rotation angles (0 to 90) ° and (90 to 180) ° of the operation member as the bolt transition section and the locking section, respectively. A composite tablet characterized by setting .   The composite lock according to claim 1, wherein a stopper for preventing the dead bolt from advancing is attached to the final lock.   3. The composite lock according to claim 2, wherein the stopper allows the dead bolt to advance when the lock target of the final lock is at a predetermined lock position. The locking object of the sickle lock is a suspended moving partition panel, and the locking object of the main locking is a door panel connected to one end of the moving partition panel via a hinge. The composite tablet according to any one of claims 1 to 3.

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