JP2009197485A - Latch device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a latch device which smoothly carries out cancellation of holding of a latch body, that is a trigger of self-propelling forward motion of a mobile body, the latch body gripping a striker at a standby position and at the same time relatively traveling by energization to allow the mobile body to perform the self-propelling forward motion. <P>SOLUTION: The latch body 41 of the latch device is formed of: a latch base 411 for receiving energization by an energizing means 42; a slider 412 combined with the latch base 411 in a forward/backward movable manner, and receding against the energization upon striking by a striker 3; and a latch arm 413 rotatably assembled in the latch base 411, and having a hook portion 413a for the striker 3. Upon receding of the slider 412, the latch arm 413 is turned to a hooking position at which the hook portion 413a is hooked on the striker 3, and the turning operation triggers cancellation of the holding by the holding means. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention has a latch body that captures a striker at a predetermined forward movement position of the movable body and travels by biasing, and the movable body automatically moves from the predetermined forward position to the forward end position by the latch body. The present invention relates to an improvement of a latch device that moves forward and backward.

  As a structure in which the movable body moves forward to the self-propelled start position and moves to the stop position by self-propelled movement, there is a self-propelled forward mechanism shown in Patent Document 1.

  This self-propelled forward movement mechanism includes a catcher stopper, a striker holding body, and a catcher having these urging bodies. When the catcher stopper is projected by the urging body, the holding body is in the forward position and in the non-holding state, and when the holding body is in the backward position and is in the holding state, the catcher stopper is Be drawn. Such a catcher is housed in a recess that extends in the moving direction of the movable body formed in the upper portion of the movable body so as to be movable along the moving direction. A catching hole for the catcher stopper is formed in the recess, and the catcher biasing means is charged at a reference position of the catcher in which the catcher stopper is hooked on the catching hole. If the striker body enters the holding body of the catcher at the reference position when the movable body is moved forward to the self-propelled start position, the holding body is moved to the retracted position and holds the striker body. At the same time, the catch stopper pulls in and gets out of the engagement hole. As a result, the catcher that has captured the striker body by the urging means of the urging means of the catcher is moved relatively rearward, and the movable body is forwardly moved forward.

However, in the mechanism of this Patent Document 1, since the pull-in direction of the catcher stopper is orthogonal to the urging direction of the catcher, it is difficult to reduce the resistance when the catcher stopper is pulled out from the engagement hole. By the way, in order to let the catcher stopper come out of the engagement hole, it is necessary to move the holding body backward by the amount of the drawing stroke necessary for the withdrawal.
JP 2007-309088 A

  The main problem to be solved by the present invention is that, in this type of device, the movable body is triggered by the self-running movement of the movable body, and at the same time the striker is captured at the standby position, and at the same time, the movable body can be moved or moved relatively. The latch body that makes the body move forward is released smoothly at this standby position.

In order to achieve the above object, in the present invention, the latch device has the following configurations (1) to (6).
(1) A latch body provided on any one of a movable body and a fixed body that supports the movable body so as to be capable of reciprocating, and is provided so as to be able to travel along the moving direction of the movable body;
(2) biasing means for the latch body;
(3) a holding means for holding the latch body in the standby position against the biasing of the biasing means;
(4) The striker provided on the other of the movable body and the stationary body is captured by the latch body at the standby position at the predetermined forward movement position of the movable body and released by the holding means, and is biased by the biasing means. A latch device that self-travels the movable body to the forward movement end position by a latch body that travels or travels relatively,
(5) The latch body
A latch base that is biased by the biasing means;
A slider that is combined with the latch base so that it can move back and forth, and retracted against the bias by the striker strike,
It is assembled to the latch base so as to be rotatable, and has a latch arm with a hooking portion for the striker,
(6) When the slider moves backward, the latch arm is rotated to the engaging position where the engaging portion is engaged with the striker, and the holding by the holding means is released by this rotation.

  According to such a configuration, when the movable body is moved forward to the predetermined forward movement position, the latch arm is rotated to the engagement position by causing the striker to abut against the slider of the latch body, and the striker is captured by the latch body. In addition, the holding means can be released by this rotation, and the latch body can be run or relatively run from the standby position by the biasing means. The movable body can be moved forward to the forward movement end position by the travel or relative travel of the latch body. Since the holding means is released by the rotation of the latch arm, the force required for the release and the pushing amount of the slider can be reduced as much as possible.

  If the holding means is composed of a lock portion formed between the latch arm engagement portion and the pivot shaft and a locked portion formed on the travel lane side of the latch body, the engagement is achieved by retreating the slider. With the rotation toward the engagement position on the part side, the engagement between the locked portion and the lock portion can be smoothly released.

The slider has a linkage recess for receiving a linkage projection formed on the latch arm;
As the slider moves backward, the wall facing toward the rear of the linking recess presses the linking projection to rotate the latch arm to the engaging position, and when the slider moves forward, the wall facing toward the front of the linking recess is linked to the linking projection. The latch arm may be rotated toward the non-engagement position by pressing.

  In this case, when the movable body is moved forward to the predetermined forward movement position from the state where the latch body is positioned at the standby position, the striker pushes the slider backward against the bias. When the slider is pushed in in this way, the latch arm's linkage projection is pressed from the front by the slider's linkage recess, so that the latch arm is rotated to position the latch arm at a latching position that prevents the striker from coming out. be able to. Further, when the movable body at the forward movement end position is moved backward toward the predetermined forward movement position, the latch arm is rotated to the non-engagement position by the slider that is advanced by biasing at the predetermined forward movement position, and the striker is moved. Can be released.

  According to the present invention, this standby of the latch body that causes the movable body to self-propelled and that moves the movable body by self-propelled by moving or relatively traveling by energizing at the same time as capturing the striker at the standby position, which triggers the self-running movement of the movable body. The release at the position can be smoothly performed.

  The best mode for carrying out the present invention will be described below with reference to FIGS.

  Here, FIG. 1 shows a sliding door 1 ′ provided with a latch device 4 with a braking device 5 according to the embodiment, and FIGS. 2 to 4 show the main part of the sliding door 1 ′ from above. It shows.

  5 shows a state in which the components constituting the apparatus are separated, and FIG. 6 shows the front end side of the base 40 and the latch body 41 which is also an additional braking unit 51, and the lower part of the latch body 41 is directed upward. It is shown as a state directed to. FIG. 7 shows a main part of the base 40.

  8 and 9 show the latch body 41 as viewed from above, and FIG. 9 shows a state in which the slider 412 is retracted and the latch arm 413 is rotated to the engaging position.

  FIGS. 10 to 12 show a cross-section of the built-in portion of the device in the sliding door 1 ′, and FIG. 11 shows that the sliding door 1 ′ has moved forward to a predetermined forward position at a speed higher than a predetermined speed. A state in which the distance x between the basic braking unit 52 and the additional braking unit 51 is narrowed is shown. Further, in FIG. 12, the additional braking unit 51 is further added between the additional braking unit 51 and the basic braking unit 52 in the example shown in FIGS. 1 to 11, and the braking device 5 is configured by the three damper units 50. An example is shown. 10 to 12, the illustration of the urging means 42 is omitted.

  The latch device 4 according to this embodiment includes a latch body 41 that captures the striker 3 at a predetermined forward movement position of the movable body 1 and travels by urging, and the predetermined forward movement is performed by the latch body 41. The movable body 1 is self-running from the position to the forward movement end position.

  In this embodiment, when the latching device 4 moves the sliding door 1 ′ as the movable body 1 supported by the door frame 2 ′ as the fixed body 2 so as to be openable and closable in the closing direction. From the middle, it is allowed to self-propel to a closed position where it hits the door stop 2a.

  Apart from this, when the sliding device 1 ′ is moved in the opening direction by the latch device 4, the sliding door 1 ′ can be self-propelled from the middle to the fully opened position.

  Further, in this embodiment, the latch device 4 includes the braking device 5, and the forward movement (to the left side of FIG. 3) from the predetermined forward movement position (position of FIG. 3) of the sliding door 1 ′. (Forward movement to the position of FIG. 4) is applied with braking.

(Latch device 4)
The latch device 4 includes a latch body 41 provided on either the movable body 1 or the fixed body 2 that supports the movable body 1 so as to be able to reciprocate. On the other of the movable body 1 and the fixed body 2, a striker 3 for the latch body 41 is provided.

  In the illustrated example, the striker 3 is provided on the door frame 2 ′ as the fixed body 2, and the latch device 4 is provided on the sliding door 1 ′ as the movable body 1.

  In the illustrated example, the striker 3 is provided in a groove 2c in which the upper end of the sliding door 1 'formed in the upper frame portion 2b of the door frame 2' is accommodated. In the illustrated example, the striker 3 has a groove in the groove 2c at a position spaced from the door contact 2a with respect to the front end 1a of the sliding door 1 'positioned in front of the sliding door 1' when the sliding door 1 'is closed. The upper end side of the shaft is fixed to the bottom of the groove so as to protrude downward from the bottom. (Fig. 11)

  On the other hand, in the illustrated example, the sliding door 1 ′ is opened at the upper end of the sliding door 1 ′ at the upper end surface 1 b of the sliding door 1 ′ and continues long in the moving direction of the sliding door 1 ′. A built-in space 1c for the latch device 4 is provided, and the latch device 4 is accommodated in the built-in space 1c.

  As a result, when the sliding door 1 ′ is moved in the closing direction to the predetermined forward movement position, the striker 3 enters the built-in space 1c from the front end 1a of the sliding door 1 ′ and is captured by a latch body 41 held at a standby position described later. It has become so. At the same time, when the striker 3 is captured, the latch body 41 is released from the holding state and is moved in a direction away from the front end 1a of the sliding door 1 'by the urging force of the urging means 42 described later. In the illustrated example, the striker 3 provided on the door frame 2 ′ as the fixed body 2 is captured by the latch body 41 at a predetermined forward movement position of the sliding door 1 ′ as the movable body 1. The latch body 41 is relatively moved in the direction away from the front end 1a of the sliding door 1 'by the urging of 42, and the sliding door 1' is moved forward to the closed position which is the forward movement end position. The

  Contrary to the illustrated example, when the striker 3 is provided on the sliding door 1 'side and the latch device 4 is provided on the door frame 2' side, the latch that captures the striker 3 at a predetermined forward movement position of the sliding door 1 '. By the movement of the sliding door 1 ′ toward the forward movement side by the urging of the body 41, the sliding door 1 ′ is self-propelled to the closed position that is the forward movement end position.

  The latch device 4 includes a latch body 41 that is provided so as to be able to travel along the moving direction of the movable body 1, an urging means 42 of the latch body 41, and a latch body against the urging force of the urging means 42. Holding means for holding 41 in the standby position. Then, the latch device 4 causes the latch body 41 in the standby position to be captured at the predetermined forward movement position of the movable body 1 and to release the holding by the holding means. Then, the movable body 1 is caused to self-travel to the forward movement end position by the latch body 41 that travels or is relatively traveled by the urging force of the urging means 42.

  In the illustrated example, the base 40 accommodated in the built-in space 1 c is provided with a latch body 41, an urging means 42, and a holding means, and a braking device 5 to be described later is incorporated so that the sliding door 1 as the movable body 1 is provided. Is provided with a latch device 4 and such a braking device 5.

  In the illustrated example, the base 40 is configured to have an elongated box shape with the upper surface opened. The base 40 is housed in the built-in space 1c so that one end thereof is positioned at the front end 1a of the sliding door 1 'so that the length direction of the base 40 is along the moving direction of the sliding door 1'. The base 40 is provided on the inner surfaces of the pair of side plates 40a and 40a along the moving direction of the sliding door 1 ', and the guide rib 40b continues long along the length direction of the side plate 40a at a position approximately in the middle of the side plate 40a. It has. In the example shown in the figure, the latch body 41 is guided by the guide rib 40b and travels along the length direction of the base 40 in the base 40. The inside of the base 40 functions as a travel lane of the latch body 41. It is supposed to be. Further, a rack 55 constituting the braking device 5 is provided below the one guide rib 40b of the pair of side plates 40a, 40a so that its teeth protrude downward. One end of the base 40 is covered by a front plate portion 40c below the guide rib 40b between the pair of side plates 40a, 40a, and the upper portion is opened above the front plate portion 40c. The striker 3 enters the base 40 from one end thereof.

  On one end side of the base 40, a horizontal plate portion 40d continuous with the upper end of the front plate portion 40c is formed. Reference numeral 40e in the drawing denotes an attachment block that is attached to the rear side of the front plate portion 40c and is screwed to the sliding door 1 'at a portion protruding downward from the lower edge of the base 40.

  Above the horizontal plate portion 40d, a window hole 40f is provided in a penetrating manner in each of the pair of side plates 40a and 40a. Further, the horizontal plate portion 40d is formed with a pair of locked portions 40g and 40g with a gap between the horizontal locked portion 40g and the other locked portion 40g in the width direction of the base 40. The pair of locked parts 40g, 40g are respectively connected to the rear edge of the rear side of the window hole 40f so that the lower edge of the window hole 40f reaches a position approximately in the middle of the window hole 40f in the front-rear direction. It is comprised so that the rib shape formed so that may be bordered may be made. Each of the pair of locked portions 40g and 40g has a hooking surface 40h facing the front end 1a side of the sliding door 1 ′ at the front end thereof, and an inner surface between the hooking surface 40h and the rear end thereof faces the hooking surface 40h. Accordingly, the inclined surface 40i gradually widens the width dimension of the locked portion 40g. In the standby position of the latch body 41, the latch arm 413 of the latch body 41 is positioned at a non-engagement position where the outer portion is inserted into the window hole 40f and the catch portion 413a is not engaged with the striker 3. The lock portion 413d formed on the 413 enters between the engaging surface 40h of the locked portion 40g and the side edge portion on the front side of the window hole 40f and is caught by the locked portion 40g. That is, in the example shown in the figure, the holding means is constituted by the locked part 40g and the lock part 413d.

  The latch body 41 includes a latch base 411, a slider 412, and a latch arm 413.

  The latch base 411 is linked to the urging means 42 and is urged by the urging means 42. In the illustrated example, the latch base 411 includes left and right wall portions 411a and 411a and a lower wall portion 411b which are long in the length direction of the base 40, and the interval between the outer surfaces of the left and right wall portions 411a and 411a is set to the base 40. The pair of side plates 40a, 40a is configured to have a long and narrow box shape with an upper surface opening that has a size that allows a small clearance. A bridging piece 411c is formed on the front end side of the latch base 411 between the upper ends of the left and right wall portions 411a and 411a. Between the bridging piece 411c and the lower wall portion 411b, the pivot shaft 413c of the latch arm 413 is formed. Is constructed so that the axis line extends along the vertical direction. The rotation shafts 413c are provided on the left and right sides, and a space is formed between the left rotation shaft 413c and the right rotation shaft 413c. The rear end portion of the latch arm 413 is closed by a rear wall portion 411d extending between the left and right wall portions 411a and 411a. Further, a mounting portion for a spring front end of a tension coil spring 42a serving as the biasing means 42 is formed behind the rear wall portion 411d. The spring rear end of the tension coil spring 42 a is attached to a mounting portion 40 k provided on the base 40 on the rear end side of the base 40, so that the spring fits in a space above the guide rib 40 b in the base 40. It has become.

  The slider 412 is combined with the latch base 411 so as to be able to move back and forth, and is retracted against the bias by the strike of the striker 3. In the illustrated example, the slider 412 has a head 412a positioned in front of the left and right rotation shafts 413c and 413c of the latch arm 413 and a neck portion 412b passing between the left and right rotation shafts 413c and 413c. And a body part 412c having a front part integrally connected to the head part 412a. The body portion 412c is accommodated in a small space between the inner surfaces of the left and right wall portions 411a and 411a of the latch base 411, and is accommodated in the latch base 411 so as to be slidable in the front-rear direction. In the illustrated example, the slider 412 is placed between the rear part of the body part 412c and the rear wall part 411d of the latch base 411, so that the slider 412 is located between the body part 412c and the neck part 412b. The parts 412d and 412d are always urged toward a forward position where the parts 412d and 412d are brought into contact with the linkage protrusion 413b of the latch arm 413 from the rear.

  The latch arm 413 is rotatably assembled to the latch base 411 and includes a hooking portion 413 a for the striker 3. In the illustrated example, the latch arm 413 includes an engaging portion 413a that protrudes inwardly at the front end thereof, and has a linkage protrusion 413b that protrudes inwardly at the rear end thereof. In the illustrated example, the latch body 41 includes a pair of left and right latch arms 413 and 413, and the right latch arm 413 can rotate to the front end side of the latch base 411 with the right rotation shaft 413 c at the rear end. The left latch arm 413 is pivotally assembled to the front end side of the latch base 411 with the left pivot shaft 413c at the rear end thereof. The latch base 413 protrudes forward from the front end of the latch base 411. 411 is provided.

  In the illustrated example, the link protrusion 413b of the left latch arm 413 is accommodated in the link recess 412f as a link recess 412f between the left jaw portion 412e and the shoulder 412d of the slider 412, and The slider 412 and the pair of latch arms 413 are arranged so that the linkage protrusion 413b of the right latch arm 413 is accommodated in the linkage recess 412f as a linkage recess 412f between the right jaw portion 412e and the shoulder 412d of the slider 412. 413.

  Then, when the slider 412 moves backward, the wall portion (jaw portion 412e) facing rearward of the linkage recess 412f presses the linkage projection 413b, and the latch arm 413 is rotated to the engagement position where the engagement portion 413a is engaged with the striker 3. In addition, the forward movement of the slider 412 causes the wall portion (shoulder portion 412d) facing the front of the linkage recess 412f to press the linkage projection 413b so that the latch arm 413 is rotated toward the non-engagement position. ing.

  Each of the left and right latch arms 413 has a latching portion 413a in front of the movable body 1 on the forward side of the movable body 1 with an interval in the traveling direction of the latch body 41, and a rotating shaft 413c behind the latch portion 413a. In addition, a lock portion 413d is provided between the hook portion 413a and the rotation shaft 413c, with the hook surface 413e facing rearward at the lower portion thereof. In the illustrated example, at the standby position of the latch body 41, the latch arm 413 is located in the window hole 40 f of the base 40, and the portion between the rotation shaft 413 c and the lock portion 413 d of the latch arm 413 is located above the locked portion 40 g. In addition, the lock portion 413d is positioned in front of the locked portion 40g and the outside thereof is inserted. In other words, the locked portions 40g are formed on both sides of the travel center line of the latch body 41.

  When the latch body 41 is located on the most front end side of the base 40 (in the illustrated example, in the vicinity of the front end 1a of the sliding door 1 ′), the linkage protrusion 413b of the latch arm 413 is inward of the rotation shaft 413c of the latch arm 413. Since the shoulder 412d of the slider 412 urged forward is pressed from the rear, the latch arm 413 enters the window hole 40f of the base 40, and the striker 3 moves between the engaging portions 413a of the pair of latch arms 413 and 413. It is positioned at a non-engagement position that allows entry. At this time, the lock portion 413d of the latch arm 413 is caught by the locked portion 40g of the base 40, and the latch body 41 is located at the most front end side of the base 40, that is, in the standby state with the latch arm 413 positioned at the non-engagement position. Positioned to position. (FIG. 2) The urging force is most accumulated in the urging means 42 at this standby position.

When the sliding door 1 'is moved forward to the predetermined forward movement position from the state where the latch body 41 is positioned at the standby position, the striker 3 enters the base 40 and passes between the engaging portions 413a of the pair of latch arms 413 and 413. Then, the slider 412 is pushed rearward against the head 412a of the slider 412 against the urging force. When the slider 412 is pushed in this way, the linkage protrusion 413b of the latch arm 413 is pressed from the front by the jaw portion 412e of the slider 412 inward of the rotation shaft 413c of the latch arm 413. Is rotated in the direction of coming out from the window hole 40f of the base 40, and is positioned at the engaging position for preventing the striker 3 from coming out from between the engaging portions 413a of the pair of latch arms 413, 413. At this time, the outer surface of the locking portion 413d of the latch arm 413 enters the inner edge of the engaging surface 40h of the locked portion 40g of the base 40, and the locking portion 413d is disengaged from the locked portion 40g. The holding by is released. (FIG. 3) Thereby, the latch body 41 is relatively moved backward in the base 40 by the biasing means in a state where the striker 3 is captured, and the sliding door 1 ′ is forcibly moved to the forward movement end position. . (FIG. 4) In the illustrated example, after the pair of latch arms 413 and 413 are pulled out from the window holes 40f of the base 40, they are continuously positioned at the engagement positions by the inner surfaces of the pair of side plates 40a and 40a. The capture of is not unraveled.
When the sliding door 1 ′ (FIG. 4) in the closed position, that is, the forward movement end position is moved backward toward the predetermined forward movement position, the latch body is moved relatively toward the standby position in the backward movement process. 41 is stored again in the biasing means 42, and the latch arm 413 can enter the window hole 40f when the predetermined forward movement position is reached, so that the latch arm 413 is biased by the slider 412 biased forward. The latch body 41 is again positioned at the standby position by rotating to the non-engagement position to release the striker 3 and re-engaging the lock portion 413d with the locked portion 40g. (Figure 2)

  In the example shown in the figure, the sliding door 1 'is closed when the holding means is released and the latch body 41 has run backward due to the urging force of the urging means without holding the striker 3. Thus, the latch arm 413 is rotated to the non-engagement position for engaging the striker 3 with the engagement portions 413a of the pair of latch arms 413 and 413 of the latch body 41 thus moved rearward. The elastic deformation portions 40j that allow the above are provided on the pair of side plates 40a and 40a of the base 40, respectively. (Fig. 5)

  In the latch device 4, when the movable body 1 is moved forward to a predetermined forward movement position, the latch arm 413 is rotated to the engagement position by causing the striker 3 to abut against the slider 412 of the latch body 41. The striker 3 can be captured by the latch body 41, and the holding means is released by this rotation, and the latch body 41 is caused to run or relatively run from the standby position by the biasing means. be able to. The movable body 1 can be self-running to the forward movement end position by the travel or relative travel of the latch body 41. Since the holding means is released by the rotation of the latch arm 413, the force required for the release and the pushing amount of the slider 412 can be reduced as much as possible.

(Braking device 5)
The braking device 5 is configured by supporting two or more damper units 50 movably on the base 40, respectively.

  In the example shown in FIGS. 1 to 11, two damper units 50, 50 are accommodated in the base 40 so as to be movable in the length direction of the base 40. In this example, one of the two damper units 50, 50 is integrally connected to the lower part of the latch base 411 of the latch body 41 so as to form the damper unit 50 integrally with the latch body 41. . (Hereinafter, this damper unit 50 is referred to as an additional braking unit 51.) The other of the two damper units 50, 50 is located behind the additional braking unit 51. (Hereinafter, this damper unit 50 is referred to as a basic braking unit 52.)

  In the example shown in FIGS. 1 to 12, the additional braking unit 51 is brought into contact with the fixed body 2 side, in this example, the striker 3 in the predetermined forward movement position of the movable body 1.

  The additional braking unit 51 includes a block portion 51a that fits in a space below the guide rib 40b in the base 40 by integrally connecting an upper portion to a lower portion of the latch base 411 that is substantially fitted between the pair of side plates 40a, 40a of the base 40. Have. The horizontal dimension of the block portion 51a is smaller than the horizontal dimension of the latch base 411, and downward sliding contact surfaces 51c are formed between the latch base 411 and the block portion 51a on the left and right, respectively. The additional braking unit 51 is slidably supported in the base 40 so that the left and right sliding contact surfaces 51c and 51c are hooked on the corresponding guide ribs 40b from above.

  On the other hand, the basic braking unit 52 has a plate-like head portion 52a having a width that fits between the pair of side plates 40a, 40a of the base 40 and a base portion integrally connected to the lower portion of the plate-like head portion 52a. 40 has a block portion 52b that fits in a space below the guide rib 40b. The horizontal dimension of the block portion 52b is smaller than the horizontal dimension of the plate-shaped head portion 52a, and a sliding contact surface 52d facing downward is provided between the plate-shaped head portion 52a and the block portion 52b. The basic braking unit 52 is slidably supported in the base 40 so that the left and right sliding contact surfaces 52d and 52d are respectively hooked on the corresponding guide ribs 40b from above.

Each of the two damper units 50 and 50 includes a damper main body 53 having a pinion 53a that applies a braking force to the rotation of the pinion 53a.
On the other hand, the base 40 is provided with the rack 55 for the pinion 53a of the damper main body 53 as described above.
According to the speed of the movable body 1 (that is, according to the magnitude of the kinetic energy of the movable body 1), specifically, depending on the speed of the sliding door 1 ′ at a predetermined forward movement position, The number of damper units 50 that engage the pinion 53a is changed.

  In the example shown in FIGS. 1 to 11, the basic braking unit 52 includes a damper main body 53 having a pinion 53a that is rotated about a rotation axis along the left-right direction on one surface side of the block portion 51a. And the base 40 side so that the pinion 53a of the damper main body 53 is always meshed with the rack 55 formed on the lower side of the guide rib 40b formed on one of the pair of side plates 40a, 40a. Is combined with.

  On the other hand, the additional braking unit 51 is movably provided with a damper main body 53 including a pinion 53a that rotates about a rotation axis along the left-right direction on one surface side of the block portion 51a. When the speed at the predetermined forward position of the sliding door 1 ′ as the movable body 1 is less than the predetermined speed, the damper main body 53 is positioned at a separation position where the pinion 53 a is not engaged with the rack 55 by urging. It has become.

  Specifically, the damper main body 53 of the additional braking unit 51 is supported by the block 51a so as to be rotatable about a rotation shaft 51d extending in the left-right direction on one side across the rotation center of the pinion 53a. Yes. In the illustrated example, the damper main body 53 is fitted into the holding recess 51f of the movable base 51e provided with the holding concave 51f of the damper main body 53 and integrated with the movable base 51e to form the damper main body 53. Yes. The movable base 51e is assembled at its front part to the block part 51a so as to be rotatable with the rotation shaft 51d. Further, between the rotation shaft 51d of the movable base 51e and the rotation center of the pinion 53a, and above the movable base 51e, one end of the spring is pressed against the side of the movable base 51e from above, from above. The movable base 51e, that is, the damper main body 53 is attached at a spaced position where the lower side portion of the movable base 51e hits the lower regulating wall 51h of the block 51a and a space is provided between the upper end of the pinion 53a and the rack 55. A torsion coil spring (hereinafter, this spring is referred to as first spring means 51i) is provided.

  Further, in this embodiment, the basic braking unit 52 and the additional braking unit 51 are connected in a state of being spaced apart by urging. Specifically, in the illustrated example, a compression coil spring is interposed between the rear end of the block portion 51 a of the additional braking unit 51 and the front end of the block portion 51 a of the basic braking unit 52. (Hereinafter, this spring is referred to as second spring means 54.) The spring forms an interval x between the basic braking unit 52 and the additional braking unit 51. (Fig. 10)

  Further, the basic braking unit 52 is formed with a pressing portion 52e against the damper main body 53 of the additional braking unit 51, and the basic braking unit 52 and the additional braking unit 51 in a state where the gap x is formed by the pressing portion 52e. And are connected. Specifically, in the illustrated example, a pressing portion 52e having a horn shape protruding forward is formed below the engaging portion with the second spring means 54 at the front end 52c of the block portion 52b of the basic braking unit 52. On the other hand, the block portion 51a of the additional braking unit 51 is formed with a receiving hole 51j for the pressing portion 52e that opens rearward at the rear end 51b of the block portion 51a and continues forward. The block 51a is formed with a window hole 51k communicating with the receiving hole 51j from the side. (FIGS. 10 and 11) An engaging projection 52f formed in the middle of the pressing portion 52e is formed in the window hole 51k. By engaging and engaging, the basic braking unit 52 and the additional braking unit 51 are connected in a state where an interval x is opened by the biasing.

  In this embodiment, when the speed of the movable body 1 at the predetermined forward movement position is equal to or higher than the predetermined speed, the basic braking unit 52 that always meshes the pinion 53a of the damper main body 53 with the rack 55. The distance x with the additional braking unit 51 is reduced against the bias, and the damper main body 53 of the additional braking unit 51 is moved by the pressing portion 52e to a position where the pinion 53a is engaged with the rack 55. Yes. (FIG. 11) Specifically, in the illustrated example, the receiving hole 51j is also opened at a location facing the rear end of the movable base 51e of the additional braking unit 51, and the movable body 1 in the predetermined forward movement position is opened. When the speed is equal to or higher than a predetermined speed, the tip of the pressing portion 52e is movable through the receiving hole 51j when the basic braking unit 52 is moved forward by the interval against the bias of the second spring means 54. The movable base 51e is rotated against the urging force of the first spring means 51i until it is pressed against the rear end 51g of the base 51e and the damper main body 53 engages the pinion 53a with the rack 55. ing. (FIG. 11) After that, when the speed of the movable body 1 becomes lower than a predetermined speed, the basic braking unit 52 is moved rearward by the interval x by the bias of the second spring means 54, and the pressing portion 52e Since the front end does not press the rear end 51g of the movable base 51e, the damper main body 53 is rotated to the separation position by the bias of the first spring means 51i. (Fig. 10)

  More specifically, in the example shown in FIGS. 1 to 11, the force applied to the sliding door 1 ′ by the biasing means 42 is E1 and the force for moving the sliding door 1 ′ in the closing direction. E2 is a force for positioning the damper main body 53 in the separated position by the first spring means 51i at E3, and E4 is a force for maintaining the distance between the basic braking unit 52 and the additional braking unit 51 by the second spring means 54. When E1 + E2> E3 + E4, both the basic brake unit 52 and the pinion 53a of the damper main body 53 of the additional brake unit 51 are engaged with the rack 55 so that the sliding door 1 'as the movable body 1 is moved by the braking by the two damper main bodies 53. When E1 + E2 <E3 + E4, only the pinion 53a of the damper main body 53 of the basic braking unit 52 is attached to the rack 55. Together they adapted to apply braking by one damper body 53 to move the sliding door 1 'as the movable member 1.

  Thereby, in this example, when the speed of the sliding door 1 ′ as the movable body 1 from the predetermined forward movement position to the forward movement end position is equal to or higher than the predetermined speed, the sliding door 1 ′ is changed accordingly. The applied braking force is increased, and when the speed of the sliding door 1 ′ is equal to or lower than a predetermined speed, the braking force applied to the sliding door 1 ′ can be decreased accordingly. When the sliding door 1 ′ is moved backward, the basic braking unit 52 that always engages the rack 55 with the pinion 53 a is subjected to a force opposite to that when the sliding door 1 ′ moves forward. The distance x with the braking unit 51 is not narrowed, and only the braking force of the damper main body 53 of the basic braking unit 52 is applied to this backward movement.

  FIG. 12 shows an example in which the additional braking unit 51 is further arranged between the latch body 41 as the additional braking unit 51 and the basic braking unit 52 in the damper unit 50. In this example, the intermediate additional braking unit 51 is provided with a pressing portion 52e against the damper main body 53 of the latch body 41 as the additional braking unit 51. In this case, according to the speed of the movable body 1, the number of the damper main bodies 53 that mesh the pinions 53 a with the rack 55 can be varied in the range of 1 to 3.

  In the illustrated example, the damper main body 53 includes a rotor 53b and a stator 53c that rotatably supports the rotor 53b, and causes the viscous resistance of a fluid such as silicon oil enclosed in the stator 53c to act on the rotation of the rotor 53b. It is configured as a so-called rotary damper. Regardless of such viscous resistance, for example, a structure is provided between the rotor 53b and the stator 53c so as to be in sliding contact with the rotation of the rotor 53b so that a certain frictional resistance is generated in the rotation of the rotor 53b. Also good. The pinion 53a is assembled to the outer end located outside the stator 53c of the rotor 53b so that the rotation axis of the rotor 53b becomes the rotation axis of the pinion 53a.

The perspective block diagram which showed the use condition of the latch apparatus 4 and the braking device 5 The principal part plane block diagram of sliding door 1 ' The principal part plane block diagram of sliding door 1 ' The principal part plane block diagram of sliding door 1 ' Exploded perspective view of the latch device 4 and the braking device 5 Perspective configuration diagram Perspective configuration diagram Plan view of the latch body 41 Plan view of the latch body 41 Main part longitudinal cross-section block diagram of sliding door 1 ' Main part longitudinal cross-section block diagram of sliding door 1 ' Main part longitudinal cross-sectional block diagram of the sliding door 1 '(The example in which a part of structure was different from the example of FIGS. 1-11)

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Movable body 2 Fixed body 3 Striker 4 Latching device 41 Latch body 411 Latch base 412 Slider 413 Latch arm 413a Engagement part 42 Energizing means

Claims (3)

Either a movable body or a fixed body that supports the movable body so as to be able to reciprocate, a latch body that is provided so as to be able to travel along the moving direction of the movable body,
Urging means of the latch body;
Holding means for holding the latch body in the standby position against the biasing of the biasing means,
The striker provided on the other of the movable body and the fixed body is captured by the latch body at the standby position at the predetermined forward movement position of the movable body and released by the holding means. A latch device that automatically moves the movable body to the forward movement end position by the latch body that is traveled in an automatic manner,
The latch body
A latch base that is biased by the biasing means;
A slider that is combined with the latch base so that it can move back and forth, and retracted against the bias by the striker strike,
It is assembled to the latch base so as to be rotatable, and has a latch arm with a hooking portion for the striker,
A latch device in which the latch arm is rotated to the engagement position for engaging the engaging portion with the striker by retreating the slider, and the holding by the holding means is released by this rotation.   The holding means includes a lock portion formed between a latching portion of the latch arm and the rotation shaft, and a locked portion formed on the travel lane side of the latch body. The latch device according to 1. The slider has a linkage recess for receiving a linkage projection formed on the latch arm;
As the slider moves backward, the wall facing toward the rear of the linking recess presses the linking projection to rotate the latch arm to the engaging position, and when the slider moves forward, the wall facing toward the front of the linking recess is linked to the linking projection. The latch device according to claim 1, wherein the latch arm is rotated toward the non-engagement position by pressing the lever.

Images