JP2020033829A - Pop-out type lock handle device for door - Google Patents

Abstract

To provide a pop-out type lock handle device for doors that has a simple structure in which locking/unlocking operation using electric signals can be performed in addition to locking/unlocking operation using a key.SOLUTION: A lock handle device 1 includes a handle case 2, inner tube 3, locking member 4, handle 5, spring member 6, locking mechanism 7, lock unit 8, and push solenoid 55. The lock handle device 1 is locked automatically by push operation to the case 2 for the handle 5. The lock handle device 1 is unlocked because the rotation of a lock rotor 26 drives a deadbolt 21 to the non-locking position via a rotor cam 22. In the locking state, the push solenoid 55 makes a push bar 57 protrude using electric signals and moves the deadbolt 21 to the non-locking position in order to perform unlocking.SELECTED DRAWING: Figure 4

Description

  The present invention is used for a door of a housing of a vending machine or the like. When a rotor of a lock unit incorporated in a handle shaft is turned in a predetermined direction with a regular key, the handle projects from a handle case, and the handle is turned. The present invention relates to a pop-out type door lock handle device capable of unlocking a door.

  Patent Document 1 discloses a pop-out type lock handle device for a door. This lock handle device includes a handle case, an inner cylinder, a locking member, a handle, a spring member, a locking mechanism, and a lock unit. The handle case includes a bearing cylinder extending in the front-rear direction, and a flange provided at a front end of the bearing cylinder. The handle is fixed to the door by bringing the flange into contact with the front surface of the door of the housing. . The inner cylinder is rotatably fitted into the bearing cylinder of the handle case so as to be immovable back and forth. The locking member is connected to the rear end of the inner cylinder, and rotates forward and backward integrally with the inner cylinder between a locking position for locking the door to the housing and an unlocking position for releasing the door. The handle includes a substantially cylindrical handle shaft portion, and a handle plate portion extending from a front end of the handle shaft portion in one direction in a direction orthogonal to an axis thereof. The handle shaft is inserted into the inner cylinder in such a manner that it cannot rotate around the shaft. Therefore, the handle shaft can rotate integrally with the inner cylinder and the locking member with respect to the handle case. Further, the handle shaft is movable back and forth with respect to the inner cylinder between a retracted position where it is immersed in the handle case and a protruding position where it protrudes from the handle case. It becomes possible to rotate between the locked position and the unlocked position integrally with the inner cylinder. The handle plate has an opening communicating with the handle shaft, and is configured to abut on the front surface of the flange of the handle case 2 at the retracted position. The spring member is inserted between the inner cylinder and the handle shaft, and urges the handle in a forward protruding direction. The locking mechanism is provided at a rear portion of the handle shaft portion, and restrains or releases the handle shaft portion in the front-rear direction with respect to the inner cylinder at the retracted position. The lock unit is incorporated and fixed to the front portion of the handle shaft portion, and is driven so as to restrain or release the locking mechanism by rotating the rotor between a locked position and an unlocked position by key operation. The locking mechanism includes a dead bolt, a rotor cam, and a joint cam. The dead bolt is incorporated into the handle shaft so as to be able to advance and retreat in the radial direction between a locked position protruding in the radial direction from the handle shaft and an unlocked position immersed in the handle shaft, and is biased to the locked position. You. The rotor cam and the joint cam rotate in the unlocking direction in response to the rotation of the lock unit in the unlocking direction, thereby retracting the deadbolt to the unlocking position. The handle shaft portion has a bolt receiving space that is open to the outer periphery so that the dead bolt can protrude and retract in the radial direction. The inner cylinder is arranged so that when the handle is in the immersion position, the inner cylinder faces the bolt housing space of the handle shaft portion, penetrates the dead bolt and moves to the lock position, and thereby restrains the handle in the immersion position. The handle is configured to hold the deadbolt in the unlocked position when the handle is not in the retracted position. When the handle is in the locked position and is in the retracted position, the bearing cylindrical portion is opposed to the bolt receiving space and the through opening, thereby engaging the dead bolt in the lock position protruding from the through opening, thereby locking the handle 5. An engagement recess is provided to be restrained in position. The dead bolt has a head engaged with the engagement recess of the bearing cylinder in the locked position, a leg extending from the head, and a passive engagement formed on the leg to engage the joint cam. And is biased to the locked position by a spring interposed between the leg and the handle shaft.

JP-A-2006-56534

The lock handle device described in Patent Literature 1 unlocks a door only by operating a lock with a key, but there is a demand to electrically control unlocking of the door.
Accordingly, an object of the present invention is to provide a door pop-out type lock handle device that can electrically control the unlocking of the door in addition to the key operation of the lock.

Hereinafter, the present invention will be described with reference to the reference numerals in the accompanying drawings, but the present invention is not limited thereto.
A lock handle device 1 according to the present invention for solving the above problems includes a handle case 2, an inner cylinder 3, a locking member 4, a handle 5, a spring member 6, a locking mechanism 7, and a lock unit 8.
The handle case 2 includes a bearing tube 9 extending in the front-rear direction, and a flange 10 provided at the front end of the bearing tube 9. The flange 10 is brought into contact with the front surface of the door D of the housing. It is fixed to the door D.
The inner cylinder 3 is rotatably fitted into the bearing cylinder 9 of the handle case 2 so as to be rotatable and immovable back and forth.
The locking member 4 is connected to the rear end of the inner cylinder 3 inserted into the bearing cylinder 9, and is provided between a locking position for locking the door D to the housing and an unlocking position for releasing. , And rotates forward and backward integrally with the inner cylinder 3.
The handle 5 includes a substantially cylindrical handle shaft portion 17 and a handle plate portion 12 extending downward from a front end of the handle shaft portion 17 and orthogonal to the axis of the handle shaft portion 17. The handle shaft 17 is inserted into the inner cylinder 3 so as not to rotate around the axis. Therefore, the handle shaft 17 can be rotated integrally with the inner cylinder 3 and the locking member 4 with respect to the handle case 2. The handle shaft portion 17 is slidable back and forth with respect to the inner cylinder 3 between a retracted position that is sunk into the handle case 2 and a protruded position that protrudes from the handle case 2. The case 2 can be rotated integrally with the inner cylinder 2 between a locked position and an unlocked position. The handle plate portion 12 has an opening 19 communicating with the handle shaft portion 17, and is configured to abut on the front surface of the flange portion 10 of the handle case 2 at the retracted position.
The spring member 6 is inserted between the inner cylinder 3 and the handle shaft 17 and urges the handle 5 in a forward protruding direction.
The locking mechanism 7 is provided at a rear portion inside the handle shaft 17, and restrains or releases the handle shaft 17 in the front-rear direction with respect to the inner cylinder 3 at the retracted position.
The lock unit 8 is assembled and fixed to a front portion in the handle shaft portion 17, and drives the locking mechanism 7 to restrain or release the lock mechanism 7 by rotating the rotor 26 between a locked position and an unlocked position by a key operation.
The locking mechanism 7 includes a dead bolt 21 and a rotor cam 22. The dead bolt 21 is incorporated into the handle shaft 17 so as to be able to advance and retreat in the radial direction between a locked position protruding radially from the handle shaft 17 and an unlocked position immersed in the handle shaft 17, Energized to the locked position. The rotor cam 22 is incorporated in the handle shaft 17 so as to be rotatable around an axis between a locked position and an unlocked position, and rotates in the unlocking direction in response to the rotation of the rotor 26 of the lock unit 8 in the unlocking direction. By doing so, the dead bolt 21 is retracted to the unlocked position.
The handle shaft portion 17 includes a bolt accommodating space 23 for accommodating the dead bolt 21 so as to protrude and retract in the radial direction from the bolt access opening 33 on the outer periphery.
The inner cylinder 3 includes a through-opening 37 facing the bolt access opening 33 of the handle shaft 17 when the handle 5 is at the retracted position. When the openings 33 and 37 face each other, the dead bolt 21 penetrates them and moves to the lock position, thereby restraining the handle 5 in the immersion position. The inner cylinder 3 holds the dead bolt 21 at the unlocked position when the handle 5 is not at the retracted position.
When the handle 5 is in the retracted position in the locked position, the bearing cylinder 9 faces the bolt access opening 33 and the through opening 37 of the bolt storage space 23, and thereby the dead bolt 21 at the locked position protruding from the through opening 37. Is provided with a slit 40 arranged to engage so that the handle 5 is exposed radially outward, thereby restraining the handle 5 in the locked position.
The dead bolt 21 is formed on the head 41 to engage with the slit 40 of the bearing cylinder 9, the leg 42 extending from the head 41, and the leg 42 so as to engage with the rotor cam 22 in the locked position. A passive engagement portion 28 is provided, and is biased to the lock position by the spring 27 interposed between the leg portion 42 and the handle shaft portion 17.
A push solenoid 55 for pushing the dead bolt 21 at the locked position to the unlocked position by an electric signal from the control center is fixed to the lower rear side of the flange portion 10 of the handle case 2. The push bar 57 of the push solenoid 55 is disposed so that the tip thereof faces the head 41 of the deadbolt 21 via the slit 40.

  The pop-out type lock handle device of the present invention has an additional function of electrically controlling the unlocking of the door in addition to the key operation of the lock, so that the use thereof can be greatly expanded.

1 is an exploded perspective view of a part of a door pop-out type lock handle device according to the present invention. 1 is an exploded perspective view of a door pop-out type lock handle device according to the present invention. It is sectional drawing of a lock handle device. It is sectional drawing with the handle of a lock handle device in a protruding position. It is a front view of a lock handle device. It is a side view of a lock handle device. It is a rear view of a lock handle device. It is sectional drawing of the cam part in FIG. FIG. 5 is a cross-sectional view of the cam portion in FIG. 4, showing a state where a deadbolt is pulled up to an unlock position by a key operation of a lock. It is sectional drawing of the same position as FIG. 9, and is a figure which shows the state which pushed up the deadbolt to the unlocking position by the push solenoid.

An embodiment of the present invention will be described with reference to the drawings.
1 and 2, a lock handle device 1 includes a handle case 2 (FIG. 2), an inner cylinder 3, a locking member 4, a handle 5, a spring member 6, a locking mechanism 7, and a lock unit 8.

  2, 3, and 4, the handle case 2 includes a bearing cylinder 9 extending in the front-rear direction and a flange 10 provided at a front end of the bearing cylinder 9, as shown in FIGS. The rear surface of the flange 10 is fixed to the door D by bringing the rear surface of the flange 10 into contact with the front panel of the door D of the housing. A handle receiving recess 11 for receiving the handle plate 12 of the handle 5 is formed on the front surface of the flange 10.

  2, 3, 4, the inner cylinder 3 is inserted into the bearing cylinder 9 of the handle case 2 so as to be relatively rotatable around an axis by about 90 ° between a locked position and an unlocked position, and has a front flange. The portion 13 and the locking member 4 fixed to the rear end prevent the bearing tube portion 9 from moving back and forth. As shown in FIG. 1, the inner cylinder 3 opens forward and is closed by an end wall 14 at the rear. As shown in FIGS. 3, 4, and 7, the end wall 14 is exposed to the rear of the bearing cylinder 9, and the locking member 4 is fixed to the rear surface. As shown in FIG. 2, a stopper projection 15 formed on the rear surface of the flange portion 13 is fitted into an approximately 90 ° arc-shaped concave portion 16 formed on the inner peripheral front edge of the bearing cylinder 9 of the handle case 2. By doing so, the rotation range of the inner cylinder 3 with respect to the handle case 2 is restricted to about 90 °. The rotation direction of the inner cylinder 3 can be changed by changing the fitting angle of the inner cylinder 3 into the bearing cylinder 9 by 180 °.

  2 to 4, the locking member 4 is fixed to the rear surface of the end wall 14 of the inner cylinder 3 and extends vertically to lock the door D to the housing, and extends horizontally. Between the handle case 2 and the inner case 3 with respect to the handle case 2 in a range of about 90 °.

  In FIG. 1, the handle 5 includes a substantially cylindrical handle shaft portion 17 and a handle plate portion 12 extending from the front end thereof to one side (downward) in a direction orthogonal to the axis. The handle shaft portion 17 is not rotatable around the axis with respect to the inner cylinder 3 by being fitted with the concave portion 62 on the inner periphery of the inner cylinder 3 in the outer circumference, and is relatively fixed in the axial direction within a predetermined range. It is movably inserted.

  Accordingly, the handle 5 is slidable back and forth with respect to the inner cylinder 3 between a retracted position (FIG. 3 and a protruding position (FIG. 4) protruding from the handle case 2) immersed in the handle case 2. In the protruding position, the handle case 2 can be integrally rotated with the inner cylinder 3 and the locking member 4 between a locked position (solid line in FIG. 5) and an unlocked position (virtual line in FIG. 5). .

  As shown in FIGS. 3 and 5, the handle plate portion 12 is immersed in the handle receiving recess 11 of the handle case 2 at the retracted position and cannot be rotated. As shown in FIG. 1, the handle plate 12 has an opening 19 communicating with the handle shaft 17 and opening forward, and a hood receiving recess 20 extending on the outer edge thereof.

  1, 3 and 4, the spring member 6 is inserted between the end wall 14 of the inner cylinder 3 and the rear end of the handle shaft 17, and biases the handle 5 in the forward projecting direction.

  The locking mechanism 7 includes a dead bolt 21 and a rotor cam 22, is incorporated in each of the accommodation spaces 23 and 24 (FIGS. 3 and 4) in the handle shaft 17, and interlocks with the locking and unlocking operation of the lock unit 8. Then, the handle shaft 17 is restrained or released in the front-rear direction with respect to the inner cylinder 3 at the retracted position.

  The lock unit 8 is incorporated and fixed in a lock storage space 25 (FIGS. 3 and 4) of the handle shaft portion 17, and the dead bolt is rotated via the rotor cam 22 by rotating the rotor 26 from the locked position to the unlocked position by key operation. 21 is driven to the unlocked position.

  The dead bolt 21 is incorporated in the dead bolt accommodating space 23 of the handle shaft 17, and as shown in FIGS. 3 and 8, a lock position protruding from the handle shaft 17 in the radial direction thereof, and FIG. As shown in FIG. 9, it is freely movable in a radial direction between a non-locking position immersed in the handle shaft 17 and is urged to a locking position by a spring 27.

  The rotor cam 22 is incorporated in a rotor cam housing space 24 of the handle shaft 17. The rotor cam 22 transmits the rotation of the rotor 26 of the lock unit 8 to the dead bolt 21, and includes a drive system joint portion 29 (FIGS. 8 and 9) that engages with the passive engagement portion 28 of the dead bolt 21. It is rotatable around an axis between a locked position (FIG. 8) and an unlocked position (FIG. 9). The rotor cam 22 rotates in the unlocking direction in response to the rotation of the rotor 26 in the unlocking direction, thereby pushing up the dead bolt 21 to the unlocking position (FIGS. 3 and 8).

  3 and 4, a lock receiving space 25, a rotor cam receiving space 24, and a bolt receiving space 23 are formed inside the handle shaft 17 from the front to the rear. The lock receiving space 25 is opened forward by the opening 19. A bearing hole 30 that rotatably supports the rear end of the rotor cam 22 is formed at the rear end of the handle shaft 17. On the outer peripheral side of the bearing hole 30, a sector-shaped engaging concave portion 31 for regulating the rotation angle of the rotor cam 22 is formed. A bolt access opening 33 is formed in a lower portion of the peripheral wall 32 of the dead bolt housing space 23. As shown in FIGS. 8 and 9, the deadbolt accommodation space 23 holds the deadbolt 21 so as to be able to protrude and retract in the radial direction from the bolt access opening 33. As shown in FIG. 1, an opening 34 for inserting a lock fixing member 35 is formed on the right side of the peripheral wall 32 of the lock storage space 25.

  As shown in FIGS. 1 and 3, the inner cylinder 3 is provided with a through-opening 37 on the peripheral wall 36 corresponding to the bolt access opening 33 of the handle shaft 17. When the handle 5 is in the retracted position (FIG. 3), the through-opening 37 faces the bolt access opening 33 to lower the dead bolt 21 protruding from the bolt housing space 23 as shown in FIGS. And the handle 5 is constrained to the retracted position by moving the handle 5 to the lock position. When the handle 5 is not in the retracted position, as shown in FIGS. 4 and 9, the dead bolt 21 is pressed by the peripheral wall 36 and is held at the unlocked position. An axial guide hole 38 is formed in the peripheral wall 36 of the inner cylinder 3 and extends forward from the through-opening 37, and the projection 39 of the dead bolt 21 movably engages with the guide hole 38.

  Accordingly, the handle 5 moves in the front-rear direction with respect to the inner cylinder 3 within a range (FIGS. 3 and 4) in which the projection 39 moves along the long hole 38 after the top portion 45 of the dead bolt 21 is disengaged from the through opening 37. Can be moved.

  In the peripheral wall 36 of the inner cylinder 3, an opening 37 ′ and an elongated hole 38 ′ having the same shape as the through-opening 37 and the guide elongated hole 38 are provided at positions 180 ° rotationally symmetric (upward) with these. The head of the stopper bolt 61 screwed into the upper surface of the rear end of the handle shaft 17 fits into the opening 37 ′ and the elongated hole 38 ′, and the axis of the handle 5 and the inner cylinder 3 extends within the extended range of the elongated hole 38 ′. The relative movement range in the direction is limited (FIGS. 2 and 3).

  As shown in FIGS. 2 and 3, a slit 40 is formed in the bearing cylinder 9 of the handle case 2 so as to face the through-opening 37 and the guide long hole 38 and extend in the front-rear direction in the axial direction. When the dead bolt 21 protrudes from the through opening 37 to the lock position (FIGS. 3 and 8), the lower end of the projection 39 is exposed from the slit 40 to the lower outside of the bearing cylinder 9.

  As shown in FIGS. 1 and 8, the deadbolt 21 includes a head 41 and a pair of parallel legs 42 extending from the head 41. A projection 39 protrudes from the top 45 of the head 41. The passive engaging portion 28 is provided on the front side of one leg 42. The head 41 projects downward and outward through the bolt access opening 33 of the handle shaft 17 in the locked position (FIG. 8). The dead bolt 21 is incorporated in the bolt accommodating space 23 in the handle shaft portion 17 so as to be relatively movable in the radial direction, and penetrates the shaft cylinder portion 43 of the rotor cam 22 between the pair of leg portions 42 in the front-rear direction. The spring 27 is interposed between the distal end of the leg 42 and the inner periphery of the handle shaft 17, whereby the dead bolt 21 is urged to the locked position.

  As shown in FIGS. 1 and 8, the passive engagement portion 28 of the deadbolt 21 is formed of a concave portion provided on the front side so as to receive the drive engagement portion 29 of the rotor cam 22. A contact surface 44 is provided for contact.

  As shown in FIGS. 3 and 8, the rotor cam 22 is incorporated in the handle shaft portion 17 so as to be rotatable forward and backward around an axis between a locked position and an unlocked position. As shown in FIGS. 1 and 3, the rotor cam 22 includes a shaft cylinder portion 43 to which the rotor 26 of the lock unit 8 fits, a flange portion 46 formed at the front end thereof, and a rear surface of the flange portion 46. It includes a projecting drive engaging portion 29 and a projecting ridge 47 formed on the outer periphery of the shaft tube portion 43 so as to extend in the axial direction. The drive engagement portion 29 engages with the passive engagement portion 28 of the dead bolt 21. As shown in FIGS. 2 and 8, the shaft cylinder portion 43 of the rotor cam 22 is supported by the bearing hole 30 of the handle shaft portion 17 at the rear end by engaging the ridge 47 with the fan-shaped engagement recess 31. You. Therefore, the rotor cam 22 is integrated with the rotor 26 of the lock unit 8 within the angular range of the sector-shaped engagement concave portion 31 with respect to the handle shaft 17 between the locked position (FIG. 8) and the unlocked position (FIG. 9). Is freely rotatable around the axis.

  When the rotor cam 22 rotates to the unlock position, the drive engagement portion 29 engages with the contact surface 44 of the passive engagement portion 28 of the dead bolt 21 to move the dead bolt 21 to the unlock position. Is done.

  As shown in FIGS. 1 and 3, the lock unit 8 is incorporated into the handle 5 with a guard hood 50 interposed between the lock case 48 and the fixing ring 49. The lock case 48 is cylindrical, has a screw portion 51 on the outer periphery, and has a pair of flat surfaces 52 parallel to the axis on opposite side portions. The fixing ring 49 has an annular groove 53 on the outer periphery, and is screwed and fixed to the outer periphery of the lock case 48. The guard hood 50 is made of a hard material and effectively resists violent destruction by a drill or the like.

  As shown in FIGS. 1 and 3, the lock unit 8 is fixed in the handle shaft 17 by a fixing member 35 that is inserted into the handle shaft 17 in a direction orthogonal to the axis through the fixing fitting insertion opening 34.

  As shown in FIGS. 2 and 3, a push solenoid 55 electrically connected to a control center is fixed to a rear surface side of the lower flange portion 10 of the handle case 2 via a mounting bracket 56. The push solenoid 55 is for pushing the dead bolt 21 at the lock position to the unlock position by an electric signal from the control center, and is provided on the protrusion 39 of the dead bolt 21 projecting below the bearing cylinder 9 from the slit 40. The push bar 57 is fixed with the ends thereof facing each other.

  A cover fitting 58 made of a hard material is attached to a lower rear portion of the handle case 2 so as to make it difficult to approach a lower end of the push bar 57 of the push solenoid 55 from a violent approach from the front. This prevents the door D from being pierced into the front panel and pushing up the push bar 57 from the lower end side with a tool to prevent unauthorized unlocking.

  A micro switch 59 that detects the position of the handle 5 and sends an electric signal to a control center is attached to the rear side of the upper flange 10 of the handle case. The base end side of the sensor pin 60 that penetrates the flange 10 movably in the front-rear direction abuts the actuator of the microswitch 59, and the tip protrudes from the front surface of the handle receiving recess 11.

  Now, from the state shown in FIGS. 3 and 8 in which the door D is locked to the housing in the closed state by the locking member 4, the door D is unlocked, opened, closed after work is completed, and closed again. The process until locking is described.

  In the state shown in FIGS. 3 and 8, the locking member 4 is in the locked position, the handle 5 is immersed in the handle case 2, the dead bolt 21 is in the locked position engaged with the through opening 37 of the inner cylinder 3, The rotor 26 and the rotor cam 22 of the lock unit 8 are all in the locked position.

  In this state, when the key is inserted into the lock and rotated about 90 ° clockwise in FIG. 8, the drive engagement portion 29 of the rotor cam 22 pushes the contact surface 44 of the passive engagement portion of the dead bolt 21, and Pull the bolt 21 to the unlocked position. At the same time as the dead bolt 21 comes out of the through opening 37 of the inner cylinder 3, the handle 5 is pushed out of the handle case 2 by the spring member 6, and the dead bolt 21 is held at the unlocked position by the peripheral wall 36 of the inner cylinder 3. , FIG.

Thereby, when the handle 5 is gripped and rotated, for example, 90 ° in a counterclockwise direction, the locking member 4 rotates together with the inner cylinder 3 to the unlocking position, and the locking member 4 is moved from the corresponding engagement portion of the casing (not shown). Since the door D comes off, the door D can be opened.
When the required work is completed, the door D is closed, the handle 5 is rotated clockwise by 90 ° together with the inner cylinder 3 and the locking member 4 to return to the locked position, and the handle 5 is pushed into the handle case 2. 3, the dead bolt 21 is pushed by the spring 27 and automatically protrudes from the handle shaft 17 and engages with the through opening 37 at a position where the through opening 37 of the handle 3 and the slit 40 of the handle case 2 face each other. Locked to the housing.

  Also, the unlocking operation can be performed by exciting the solenoid 55 as shown in FIG. 10 by remote control or the like from the control center without operating the lock. When the solenoid 55 is excited, the push bar 57 projects upward to push up the dead bolt 21 to the unlocked position, and the handle 5 is pushed out of the handle case 2, so that the lock operation is unnecessary. Thereby, remote emergency unlocking is also possible. By adding an electric authentication device as necessary and restricting the unlocking authority, unlocking means can be diversified while improving security, and the use of the pop-out type lock handle device can be greatly expanded. .

DESCRIPTION OF SYMBOLS 1 Lock handle device 2 Handle case 3 Inner cylinder 4 Locking member 5 Handle 6 Spring member 7 Locking mechanism 8 Lock unit 9 Bearing cylinder part 10 Flange part 11 Handle receiving concave part 12 Handle plate part 13 Flange part 14 End wall of inner cylinder 15 Stopper protrusion 16 Arc-shaped concave portion 17 Handle shaft portion 18 Projecting portion 19 Front 20 Hood receiving concave portion 21 Dead bolt 22 Rotor cam 23 Dead bolt receiving space 24 Cam receiving space 25 Lock receiving space 26 Rotor 27 Spring 28 Passive engaging portion 29 Drive engagement Part 30 Bearing hole 31 Fan-shaped engaging concave part 32 Peripheral wall 33 of handle shaft part Dead bolt access opening 34 Fixing metal fitting opening 35 Lock fixing member 36 Inner cylinder peripheral wall 37 Inner cylinder through opening 38 Inner cylinder long hole 39 Dead bolt Projection 40 Slit 41 Dead bolt head 42 Dead bolt leg 43 Rotor Cam shaft cylinder portion 44 Dead bolt contact surface 45 Dead bolt top portion 46 Rotor cam flange portion 47 Rotor cam ridge 48 Lock case 49 Locking ring 50 Guard hood 51 Screw portion 52 Flat surface 53 Annular groove 55 Push solenoid 56 Mounting Fitting 57 Push bar 58 Guard fitting 59 Micro switch 60 Sensor pin 61 Stopper bolt 62 Recess 63 Leg 64 Guard hood 65 Bearing hole 66 Fan-shaped engaging recess 67 Other end 68 Step D

Claims (3)

A handle case having an axially extending bearing tubular portion and a flange provided at the front end of the bearing tubular portion, the flange being in contact with the front surface of the door of the housing and being fixed to the door. When,
An inner cylinder inserted into the bearing cylinder portion of the handle case so as to be relatively rotatable around the axis between a locked position and an unlocked position and immovable back and forth,
A locking member coupled to the rear end of the inner cylinder, the locking member rotating forward and reverse integrally with the inner cylinder between a locking position for locking the door to the housing and an unlocking position for releasing the door;
A handle comprising a substantially cylindrical handle shaft portion, and a handle plate portion extending downward from a front end of the handle shaft portion in a direction orthogonal to an axis of the handle shaft portion, wherein the handle shaft portion is provided. Is inserted into the inner cylinder so as to be relatively non-rotatable around an axis, and is relatively slidable back and forth with respect to the inner cylinder between a retracted position that is immersed in the handle case and a projected position that protrudes from the handle case. At the protruding position, the handle case is configured to be rotatable about the axis with respect to the handle case between the locking position and the unlocking position integrally with the inner cylinder, and the handle plate portion is communicated with the handle shaft portion and forward. It has an opening to be opened, and is configured to abut on the front surface of the flange of the handle case in the immersion position,
A spring member inserted between the inner cylinder and the handle shaft portion, for urging the handle shaft portion forward so as to push the handle to a protruding position;
A handle is provided at a rear portion of the handle shaft, and engages with the inner cylinder and the bearing cylinder so as to restrain the handle at a retracted position with respect to the inner cylinder and a lock position with respect to the bearing cylinder. A locking mechanism operable between a locked state and a released state in which the handle is released from engagement with the inner cylinder and the bearing cylinder to allow the handle to protrude from the inner cylinder.
A lock unit incorporated and fixed to a front portion of the handle shaft portion, the lock unit being configured to be driven to restrain or release the locking mechanism by rotation between a locked position and an unlocked position of the rotor by a key operation. In the out-type lock handle device,
The locking mechanism is biased toward the locking position so as to be able to advance and retreat in the radial direction between a locked position protruding radially downward from the handle shaft and an unlocked position immersed in the handle shaft, and the locking mechanism is biased to the handle shaft. A dead bolt incorporated into the handle portion, and the lock unit is rotatably incorporated in the handle shaft portion around an axis between a locked position and an unlocked position in response to rotation of the rotor of the lock unit in the unlocked direction. A rotor cam that retreats the dead bolt to the unlocked position by rotating to the
The handle shaft portion includes a bolt housing space that is opened to the outer periphery by a bolt access opening so as to make the dead bolt protrude and retract in a radial direction,
When the handle is in the retracted position, the inner tube faces the access opening of the handle shaft, thereby penetrating the deadbolt and moving to the lock position, thereby restraining the handle in the retracted position. The handle is not in the retracted position and is configured to hold the deadbolt in the unlocked position when the handle is not in the retracted position;
When the handle is in the retracted position in the locked position, the bearing tube portion faces the bolt access opening and the through-opening, thereby exposing the dead bolt in the locked position protruding from the through-opening to the outside in the radial direction. And a slit arranged to engage the handle so as to restrain the handle in a locked position,
The dead bolt has a head engaged with the slit of the bearing cylinder in the locked position, a leg extending from the head, and a passive part formed on the leg to engage the rotor cam. An engagement portion, and is urged to a lock position by a spring interposed between the leg portion and the handle shaft portion,
A push solenoid for pushing the dead bolt in the lock position to the unlock position by an electric signal from the control center is provided on the lower rear side of the flange portion of the handle case. A door pop-out type lock handle device, which is fixed so as to face the head of the deadbolt via a door. A microswitch fixed to the upper rear side of the flange portion of the handle case and detecting a projecting or buried position of the handle to send an electric signal to the control center;
A sensor pin penetrating the flange portion movably in the front-rear direction such that a proximal end thereof abuts on the actuator of the microswitch and a distal end protrudes from a surface with which the handle plate abuts. A door pop-out type lock handle device according to claim 1.   A guard fitting made of a hard material that is fixed to a lower rear side of the flange portion of the handle case and blocks a lower end of a push bar of the push solenoid and a door of the housing is provided. A pop-out type lock handle device for a door according to claim 1 or 2.