JP2015055065A - Lock device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lock device having a small-sized mechanism capable of restraining unlocking by mischief.SOLUTION: The lock device comprises an external operation part 104 installable in an opening door, a body part 108 connected to the external operation part 104 and an installation plate 102 and a driving part 125 for moving a slide bolt 132 by the linear movement along an inside surface of the opening door until the slide bolt 132 separates from a receiving member 133 in a state where a base part 101 can abut on a panel and moving the base part 101 by the rotational movement up to a position where the base part 101 does not interfere with the panel in a state where the slide bolt 132 separates from the receiving member 133.

Description

  The present invention relates to a locking device.

Conventionally, an apparatus for locking a private room such as a toilet booth is known. For example, the doors of toilet booths are often open inside. For this reason, when a person falls in the private room of the toilet booth, there is a problem that it becomes difficult to rescue the person in the private room without sufficiently opening the hinged door.
As an apparatus for solving this problem, for example, the apparatus described in Patent Document 1 operates as an open door in normal use, and operates as a double swing door by an operation from outside the private room in an emergency.

JP 2007-224710 A

Unlocking a locked private room from the outside is useful in an emergency, but on the other hand, if unlocked by mischief, there is a problem that a private space cannot be maintained. To solve this problem, the emergency unlocking procedure is divided into two stages. In the first unlocking, the slide bolt is slid to allow only the inner opening as in the normal unlocking operation, and the first unlocking is followed. It is known that the slide bolt can be further slid by the second stage of unlocking to allow double opening.
However, in order to slide the slide bolt in two stages, in addition to the movement amount of the slide bolt necessary for normal locking and unlocking operation, the movement amount for the second stage slide is necessary, and the entire locking device is It becomes large.
The design of the lock device may be given priority from the point of constituting a part of the interior. In this case, it is not allowed to increase in size by incorporating a mechanism that slides in two stages, and due to mischief. It is difficult to incorporate a conventional mechanism that can prevent unlocking into a locking device.

  This invention is made | formed in view of the situation mentioned above, The objective is to provide the locking device which has a small mechanism which can suppress the unlocking by mischief.

  One aspect of the present invention is a lock device that connects a hinged door that opens and closes the doorway to a panel that constitutes a doorway of a room, the base part being attachable to the hinged door, and the base part connected to the base part. A movable body movable with respect to the base portion, and a locked member that can be fixed to the panel and that can be locked to the movable body, and the base portion is a mounting plate that can be fixed to the hinged door And an external unlocking part connected to the mounting plate for moving the movable body from the outside of the room, and the external unlocking part of the room with the hinged door closing the doorway An external operation part that can be attached to the hinged door so as to be exposed to the outside and accepts an unlocking operation by an unlocking operator, and the attachment about a rotation axis that is connected to the external operation part and is perpendicular to the inner surface of the hinged door On the inside surface against the plate And a main body connected to the mounting plate, and the unlocking operation is transmitted from the external operation unit provided in the main body, and the base or The movable body is moved by linear movement along the inner surface until the movable body is separated from the locked member in a state in which the movable body can come into contact with the panel, and the movable body is engaged. And a drive unit that moves the base part by the rotational movement to a position where the base part or the moving body does not interfere with the panel in a state of being separated from the stop member.

  The external operation unit includes an outer cylinder part fixed to the base part, and an operation input shaft disposed inside the outer cylinder part and rotatable with respect to the outer cylinder part, The drive unit is arranged inside the outer cylinder unit, is connected to the operation input shaft, is rotatable integrally with the operation input shaft, and has a transmission shaft unit having a first gear inside the main body unit, A coupling mechanism that is arranged inside the main body and transmits the rotation of the transmission shaft portion and has a second gear and a concavo-convex portion, and the second gear meshes with the first gear, and a mechanism that is inserted into the concave portion in the concavo-convex portion. And a rotation transmission member having a third gear formed on the outer periphery thereof, and the movable body may have a rack that meshes with the third gear.

  Further, the coupling mechanism is configured such that the second gear and the concavo-convex portion are formed on an outer periphery, and can rotate around a rotation axis parallel to a rotation axis of the transmission shaft portion with respect to the main body portion within the main body portion. An intermediate gear, a fitting member that is supported by the main body part and can be fitted to the mounting plate so as to be able to come into contact with the concavo-convex part and to advance and retreat within the main body part, and a forward and backward direction of the fitting member A biasing member that biases the fitting member in a direction in which the convex portion is fitted to the mounting plate, and the intermediate gear rotates in response to a rotational force from the transmission shaft portion. By doing so, the concavo-convex portion may be brought into contact with the fitting member, and the fitting member may be pressed and moved against the urging force of the urging member.

  The convex portion is inclined with respect to the advancing / retreating direction of the fitting member and in a circumferential direction centering on the rotation axis of the transmission shaft portion in a state where the fitting member is attached to the main body portion. The mounting plate may have a recessed portion that can be in contact with the inclined surface and into which at least a part of the convex portion can be inserted.

  According to the present invention, since the operation of moving the moving body to a position where it does not interfere with the panel is a rotation operation that occurs following the linear movement of the moving body, the locking device having a small mechanism that can prevent unlocking by mischief. Can be provided.

It is a general view which shows the room where the locking device of one Embodiment of this invention was attached. It is a top view of the locking device of the embodiment. It is a rear view of the locking device of the embodiment. It is a rear view of the locking device of the embodiment, and is a view showing a state where the slide bolt is in a locked state. It is sectional drawing in the AA of FIG. It is a front view which shows the structure of the drive part in the locking device of the embodiment. It is a side view which shows a part of drive part in the locking device of the embodiment. It is a rear view which shows a part of drive part and the internal structure of a slide bolt in the locking device of the embodiment. It is explanatory drawing for demonstrating the effect | action of the locking device of the embodiment. It is explanatory drawing for demonstrating the effect | action of the locking device of the embodiment.

(First embodiment)
Hereinafter, a lock device 100 according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 10. FIG. 1 is an overall view showing a room to which the lock device of the present embodiment is attached. FIG. 2 is a plan view of the locking device of the embodiment. FIG. 3 is a rear view of the lock device of the embodiment. FIG. 4 is a rear view of the locking device according to the embodiment, and shows a state where the slide bolt is in a locked state. FIG. 5 is a cross-sectional view taken along the line AA in FIG. FIG. 6 is a front view showing the configuration of the drive unit in the lock device of the embodiment. FIG. 7 is a side view showing a part of the drive unit in the lock device of the embodiment. FIG. 8 is a rear view showing a part of the drive unit and the internal structure of the slide bolt in the locking device of the embodiment.

  First, with reference to FIG. 1, schematic structure of the hinged door 4 and the panel 3 used as the object to which the locking device 100 of this embodiment is attached is demonstrated. The hinged door 4 and the panel 3 together with the wall 2 constitute a room 1. In the present embodiment, the configuration of the hinged door 4 and the panel 3 to which the lock device 100 is attached is an inward opening in which the hinged door 4 is opened toward the inside of the room 1 at normal times. Furthermore, the hinged door 4 in the present embodiment is configured to open as an outer opening in addition to an inner opening by performing a predetermined unlocking operation on the lock device 100 from the outside of the room 1. Specifically, in this embodiment, when the lock device 100 is not attached to the panel 3 and the hinged door 4, the hinged door 4 can be double-opened with respect to the panel 3. When a part of the lock device 100 interferes with the directed surface, it is normally restricted to open inward.

Next, the structure of the locking device 100 of this embodiment attached to said panel 3 and the hinged door 4 is demonstrated with reference to FIG. 2 thru | or FIG.
A lock device 100 shown in FIGS. 1 and 2 is a device for connecting a hinged door 4 to a panel 3 constituting an entrance of a room 1.
As shown in FIG. 2, the lock device 100 includes a base part 101 that can be attached to the hinged door 4, a slide bolt 132 (moving body) connected to the base part 101, and can be fixed to the panel 3. 132 includes a receiving member 133 (member to be locked) that can be locked.

  The base 101 includes an attachment plate 102 that can be fixed to the hinged door 4 and an external unlocking portion 103 that is connected to the attachment plate 102 and moves the slide bolt 132 from the outside of the room 1.

The mounting plate 102 is fixed to a surface facing the inside of the room 1 in a state where the hinged door 4 blocks the entrance / exit of the room 1 among both surfaces in the thickness direction of the hinged door 4. The attachment plate 102 is attached to the door end side of the hinged door 4.
As shown in FIG. 3, a plurality of screw holes 102 a for passing screws for fixing the mounting plate 102 to the hinged door 4 and a part of a fitting member 129 described later can be inserted into the mounting plate 102. A depression 102b is formed. The recessed portion 102b has a shape that is recessed in a substantially rectangular shape from the outer periphery to the inner side of the mounting plate 102 when viewed from the thickness direction of the mounting plate 102.

  The external unlocking unit 103 includes an external operation unit 104 that accepts an unlocking operation by the unlocking operator, a main body unit 108 that is connected to the external operation unit 104, and an external operation unit 104 that is connected to the external operation unit 104. Drive unit 125.

As shown in FIG. 2, the external operation unit 104 can be attached to the hinged door 4 so as to be exposed to the outside of the room 1 in a state where the hinged door 4 closes the doorway.
As shown in FIGS. 4 and 5, the external operation unit 104 includes an outer cylinder part 105 fixed to the base part 101 and an operation that is arranged inside the outer cylinder part 105 and is rotatable with respect to the outer cylinder part 105. And an input shaft 106.

The outer cylinder part 105 shown in FIG. 5 is a cylindrical member having an opening part 105 a that allows a predetermined key 140 to reach the operation input shaft 106. Furthermore, a thread groove 105 b for screwing a support cylinder part 109 (described later) provided in the main body part 108 is formed on the inner peripheral surface of the outer cylinder part 105.
The opening 105a formed in the outer cylinder portion 105 is preferably a small-diameter opening for the purpose of preventing the operation input shaft 106 from being rotated by mischief. Further, the opening 105 a formed in the outer cylinder portion 105 may have a contour shape corresponding to the shape of the key 140 for the purpose of enabling the operation input shaft 106 to be rotated only by the predetermined key 140. . In the present embodiment, the shape of the opening 105a is hexagonal for the purpose of allowing the outer cylinder 105 to be screwed into the support cylinder 109 using a hexagon wrench. If the contour shape of the opening 105a is non-circular, the same effect as in the case of a hexagonal shape can be obtained even if it is other than a hexagonal shape.

  As shown in FIG. 5, the operation input shaft 106 has a coupling groove 106 a having a non-circular cross-section at a portion directed to a transmission shaft portion 126 described later in the driving portion 125, and the opening portion 105 a of the outer cylinder portion 105. It is a substantially rod-shaped member having a concavo-convex shape 106b that meshes with the key 140 in the portion directed toward the. The operation input shaft 106 is connected to the outer cylinder portion 105 so as to be rotatable with respect to the outer cylinder portion 105 about the central axis of the outer cylinder portion 105 as a rotation center. Specifically, the operation input shaft 106 is formed with a groove 106c that extends over the circumference of the operation input shaft 106 when viewed from the center axis direction of the operation input shaft 106, and enters the groove. The operation input shaft 106 is connected to the outer cylinder part 105 by a retaining plate 107 (see FIGS. 2 and 5) fixed to the outer cylinder part 105. As a result, the central axis of the operation input shaft 106 and the central axis of the outer cylindrical portion 105 are maintained substantially coaxial.

As shown in FIG. 5, the main body 108 is connected to the external operation unit 104 and the mounting plate 102. The main body 108 is capable of rotating with respect to the mounting plate 102 around a rotation axis directed in the thickness direction of the mounting plate 102. In the present embodiment, the rotation axis of the main body 108 with respect to the mounting plate 102 is coaxial with the central axis of the operation input shaft 106 and the central axis of the transmission shaft 126. In other words, in this embodiment, the rotation axis of the main body 108 with respect to the mounting plate 102 coincides with the rotation axis of the transmission shaft 126 when the operation input shaft 106 is rotated by the key 140.
In the main body 108, when the mounting plate 102 is fixed to the hinged door 4, the door-side end of the slide bolt 132 can be moved upward from the horizontal state of the slide bolt 132. Further, the main body 108 has the slide bolt 132 in a state where the end of the slide bolt 132 on the door end side is higher than the end of the slide bolt 132 on the suspension base side when the mounting plate 102 is fixed to the hinged door 4. It can rotate with respect to the mounting plate 102 until it becomes the original horizontal state. The rotation range of the main body 108 is restricted so that the end of the slide bolt 132 on the door end side does not descend from the horizontal state.
Further, in the main body 108, when the main body 108 is in a horizontal state, the door end side portion is heavier than the hanging shaft side portion than the rotation shaft of the main body portion 108 than the rotation shaft of the main body portion 108. For this reason, the main body 108 needs an external force that resists gravity in order to rotate the door end side portion of the main body 108 to move upward.
The main body part 108 includes a support cylinder part 109 fixed to the mounting plate 102 and connected to the external operation part 104, and a guide part 111 connected to the support cylinder part 109.

  The support cylinder portion 109 is fixed to the mounting plate 102. A screw thread 109 a is formed on the outer peripheral surface of the support cylinder portion 109 to be screwed into a screw groove formed on the inner peripheral surface of the outer cylinder portion 105. The outer cylinder part 105 and the support cylinder part 109 can absorb the difference in thickness of the hinged door 4 by setting the insertion length of the screw thread 109a to the screw groove 105b to an arbitrary length. In the present embodiment, the support cylinder portion 109 is fixed to the mounting plate 102 by a spring retaining ring 110. Note that the support cylinder portion 109 may be integrally formed with the mounting plate 102.

The guide part 111 is connected to the support cylinder part 109 so as to be rotatable around the central axis of the support cylinder part 109. For this reason, in this embodiment, the guide part 111 of the main body part 108 can rotate around the rotation axis of the transmission shaft part 126 with respect to the mounting plate 102.
The guide portion 111 includes an accommodating portion 112 that is connected to the supporting cylinder portion 109 so as to be rotatable around the central axis of the supporting cylinder portion 109, a lid portion 118 attached to the accommodating portion 112, and the accommodating portion 112. And a connecting body 119 for fixing the lid portion 118 to the main body.

  As shown in FIGS. 4 and 5, the accommodating portion 112 includes a click mechanism 113 for informing the operator that the slide bolt 132 has reached the unlocked state by a click feeling, and the hinged door 4 by contacting the panel 3. An opening / closing direction restricting portion 116 that restricts the opening / closing direction of the housing to one side, and an accommodation groove 117 for accommodating the drive portion 125 inside the accommodation portion 112.

As shown in FIGS. 3 and 4, the click mechanism 113 has a hole portion 112 a that opens to the outer surface of the housing portion 112, a spring 114 that is inserted into the hole portion 112 a, and a spring 114 that moves outward from the hole portion 112 a. And a ball 115 disposed in the hole 112a so as to be pressed. Although details will be described later, a click groove 132 d into which the ball 115 of the click mechanism 113 is fitted is formed on the inner surface of the slide bolt 132.
The ball 115 of the click mechanism 113 is pressed against the inner surface of the slide bolt 132 by the spring 114. For this reason, when the slide bolt 132 moves linearly with respect to the housing portion 112, a click feeling and a click sound are generated when the ball 115 is fitted in the click groove 132d formed on the inner surface of the slide bolt 132. In the present embodiment, the click mechanism 113 can provide a click feeling at two positions, a position where the slide bolt 132 is closest to the receiving member 133 side and a position where the slide bolt 132 is farthest from the receiving member 133. The click grooves 132d into which the balls 115 are fitted are formed at two locations separated in the forward and backward direction of the slide bolt 132.

  As shown in FIG. 2, the door opening / closing direction restricting portion 116 is attached with a door stop rubber for preventing the panel 3 from being damaged when the opening / closing direction restricting portion 116 contacts the panel 3.

  The housing groove 117 shown in FIG. 5 has a shape corresponding to each component of the drive unit 125 so that the drive unit 125 to be described later can suitably operate in the housing unit 112. Further, in the present embodiment, the accommodation groove 117 has an opening 117 a for projecting the fitting member 129 so that a part of the fitting member 129 described later can be fitted to the mounting plate 102.

  The lid portion 118 is fixed to the housing portion 112 in order to hold each component of the drive unit 125 housed in the housing groove 117. The lid portion 118 is provided with a rail 118a for connecting the guide portion 111 and the slide bolt 132 and guiding the slide bolt 132 to the guide portion 111 so as to be linearly movable.

  The connecting body 119 connects the housing part 112 and the lid part 118 and restricts the forward and backward movement of the slide bolt 132 with respect to the guide part 111, and the housing part 112 at a position away from the first connecting body 120. And a second connecting body 124 that connects the lid portion 118 to each other.

  The first connecting body 120 includes a stopper screw 121 that is screwed into the housing portion 112 from the housing portion 112 toward the lid portion 118, and a non-circular nut 122 that fits into the lid portion 118 and fits into the stopper screw 121.

The non-circular nut 122 is a hexagonal nut in this embodiment, and is inserted into a recess 118b formed in the lid portion 118 corresponding to the outer shape of the hexagonal nut.
An end portion of a stopper screw 121 that extends through the hexagon nut toward the slide bolt 132 in the first connecting body 120 can abut on a stopper, which will be described later, formed on the slide bolt 132.
Thus, in this embodiment, the 1st coupling body 120 which fixes the accommodating part 112 and the cover part 118 functions as the movement control part 123 which controls the forward / backward movement of the slide bolt 132 with respect to the guide part 111. FIG.

  The second coupling body 124 is a screw that is screwed from the lid portion 118 side toward the housing portion 112 side. In the present embodiment, the accommodating portion 112 is previously formed with a screw groove that meshes with the screw that is the second connecting body 124.

  As shown in FIGS. 5 to 8, the drive unit 125 is arranged inside the outer tube unit 105 and the support tube unit 109 in a state where the outer tube unit 105 and the support tube unit 109 are screw-fitted, and is operated. A transmission shaft portion 126 connected to the shaft 106, a connection mechanism 127 connected to the transmission shaft portion 126 and disposed inside the main body portion 108, and a rotation transmission member 131 connected to the connection mechanism 127 inside the main body portion 108. Is provided.

  As shown in FIG. 5 and FIG. 6, the transmission shaft portion 126 is disposed inside the main body portion 108 and a connection portion 126 a that can rotate integrally with the operation input shaft 106 by being connected to the operation input shaft 106. A gear portion 126b (first gear).

  The connecting portion 126a has a non-circular cross section corresponding to the shape of the coupling groove 106a formed in the operation input shaft 106. Further, the depth at which the coupling portion 126a is inserted into the coupling groove 106a is arbitrary, and even when the screwing amount of the outer cylinder portion 105 with respect to the support cylinder portion 109 differs depending on the thickness of the hinged door 4, the transmission shaft portion 126 and The operation input shaft 106 is kept connected.

  As shown in FIG. 6, the gear portion 126b has a disk shape in which teeth are formed on a part of the outer periphery, and the teeth of the gear portion 126b mesh with an intermediate gear 128 described later.

  Since the transmission shaft portion 126 and the operation input shaft 106 are connected by coupling, the transmission shaft portion 126 is easily coupled to the driving portion 125 by the work of attaching the external operation portion 104 to the base portion 101.

The coupling mechanism 127 shown in FIGS. 5 and 6 uses the rotation of the transmission shaft portion 126 as power for releasing the fixed state between the guide portion 111 and the mounting plate 102 and power for moving the slide bolt 132. It is the power transmission means for doing.
The coupling mechanism 127 includes an intermediate gear 128 that meshes with the gear portion 126 b and rotates within the accommodating portion 112, a fitting member 129 that moves forward and backward by the intermediate gear 128, and a stopper spring that fits the fitting member 129 into the mounting plate 102. 130 (biasing member).

As shown in FIGS. 6 and 7, the intermediate gear 128 has a second gear 128 a that meshes with the gear portion 126 b and an uneven portion 128 b into which a part of a rotation transmission member 131 described later is inserted on the outer periphery. The intermediate gear 128 can rotate with respect to the main body 108 inside the main body 108 around a rotation axis parallel to the rotation axis of the transmission shaft 126.
The second gear 128a of the intermediate gear 128 is formed on a part of the outer periphery of the intermediate gear 128 corresponding to the number of teeth of the gear portion 126b.
The uneven portion 128b of the intermediate gear 128 is disposed between a pair of convex portions 128b1 extending from the outer peripheral surface of the intermediate gear 128 in the radial direction of the intermediate gear 128 and spaced apart from each other, and a set of convex portions. And a recess 128b2 for receiving the mating protrusion 131a.

  As shown in FIGS. 3, 5, and 6, the fitting member 129 is supported by the housing groove 117 so as to be able to come into contact with the concavo-convex portion 128 b of the intermediate gear 128 and to advance and retreat within the housing portion 112. Further, the fitting member 129 has a convex portion 129 a that can be fitted to the mounting plate 102.

As shown in FIGS. 3 and 5, the convex portion 129 a can be exposed to the housing portion 112 through the opening formed in the housing groove 117, and is inclined to enter the wedge shape with respect to the recess portion 102 b of the mounting plate 102. It has a surface 129b.
The inclined surface 129b formed in the convex portion 129a is inclined with respect to the advancing / retreating direction of the fitting member 129 and is centered on the rotation axis of the transmission shaft portion 126 in a state where the fitting member 129 is attached to the main body portion 108. The surface is oriented in the circumferential direction.

  The stopper spring 130 shown in FIG. 5 urges the fitting member 129 in a direction in which the convex portion 129a is fitted to the mounting plate 102 in the advancing / retreating direction of the fitting member 129. In the present embodiment, the stopper spring 130 is a compression spring whose expansion / contraction direction is directed in the forward / backward direction of the fitting member 129.

As shown in FIGS. 5 and 7, the rotation transmission member 131 has an engagement protrusion 131 a to be inserted into the recess 128 b 2 in the recess 128 b formed in the intermediate gear 128 of the coupling mechanism 127 and has a gear 131 b (first gear) on the outer periphery. (Three gears) having a substantially disk shape.
As shown in FIG. 8, the gear 131 b formed on the outer periphery of the rotation transmission member 131 meshes with a rack 132 a formed on the inner surface of the slide bolt 132, and the rotation transmission member 131 rotates, whereby the slide bolt 132 is guided. It moves linearly with respect to 111 (see FIG. 5). The gear 131 b formed on the outer periphery of the rotation transmitting member 131 has a number of teeth corresponding to the amount of movement of the slide bolt 132 and is formed on a part of the outer periphery of the rotation transmitting member 131.

  As shown in FIGS. 7 and 8, the engagement protrusion 131 a is formed on the surface facing the intermediate gear 128 among the pair of surfaces facing each other in the plate thickness direction of the rotation transmitting member 131. When the engagement protrusion 131a enters the recess 128b2 of the uneven portion 128b formed in the intermediate gear 128 and the rotation transmitting member 131 rotates, the engagement protrusion 131a presses the uneven portion 128b to rotate the intermediate gear 128. .

As shown in FIGS. 3 to 5, the slide bolt 132 (moving body) is movable with respect to the base portion 101, and engages with the receiving member 133 so that the hinged door 4 and the panel are connected via the lock device 100. 3 is a member for connecting the three.
As shown in FIG. 8, the slide bolt 132 has a rack 132 a that meshes with the gear 131 b of the rotation transmission member 131. The rack 132 a provided on the slide bolt 132 is always in mesh with the rotation transmitting member 131 when the slide bolt 132 is attached to the guide portion 111.
A guide 132b for connecting the guide portion 111 and the slide bolt 132 so as to be linearly movable is provided on the inner surface of the slide bolt 132. In the present embodiment, the guide 132 b provided on the inner surface of the slide bolt 132 has an uneven shape for accommodating the rail 118 a formed on the lid portion 118 of the guide portion 111.
Further, as shown in FIGS. 5 and 8, a stopper 132 c capable of contacting the stopper screw 121 is formed on the inner surface of the slide bolt 132. The stopper 132c has a shape projecting from the inner surface of the slide bolt 132 toward the inside of the slide bolt 132. When the stopper screw 121 is tightened, the stopper screw 121 can contact the stopper 132c, and the stopper screw 121 is loosened. The protrusion length is set so that the stopper screw 121 does not hit the stopper 132c.
As shown in FIGS. 3 and 4, a click groove 132 d into which the ball 115 of the click mechanism 113 enters is formed on the inner surface of the slide bolt 132.

  The receiving member 133 (member to be locked) shown in FIGS. 2 and 5 is not particularly limited as long as the receiving member 133 can be locked to the slide bolt 132 and can be fixed to the panel 3. Appropriately selected and applicable. In this embodiment, the receiving member 133 has a substantially cylindrical shape having a small diameter portion 133a into which a part of the slide bolt 132 enters and a large diameter portion 133b disposed on both sides of the small diameter portion 133a so as to sandwich the small diameter portion 133a therebetween. have.

Next, the operation of the lock device 100 of this embodiment will be described. 9 and 10 are explanatory diagrams for explaining the operation of the locking device of the present embodiment.
In this embodiment, as shown in FIGS. 1 and 2, the base portion 101 and the receiving member 133 of the lock device 100 are fixed inside the room 1.
In a normal use mode, the lock device 100 is configured to lock the hinged door 4 by connecting the hinged door 4 and the panel 3 while restricting the hinged door 4 to the inner opening only.
That is, in the normal use mode, the locking device 100 has the mounting plate 102 fixed to the door end side of the hinged door 4, the receiving member 133 is fixed to the panel 3, and the slide bolt 132 from the hinged door 4 toward the receiving member 133. The guide portion 111 is fixed to the mounting plate 102 by the action of the connecting mechanism 127 so that the forward and backward movement of the connecting mechanism 127 occurs.

  Specifically, the stopper spring 130 (see FIG. 5) of the coupling mechanism 127 presses the fitting member 129 (see FIG. 9), thereby forming the convex portion 129a of the fitting member 129 as shown in FIG. The inclined surface 129b and the outer surface of the recess 102b of the mounting plate 102 are in contact with each other. Then, due to the pressing force of the stopper spring 130, the convex portion 129 a of the fitting member 129 meshes with the recess portion 102 b of the mounting plate 102 in a wedge shape. For this reason, the guide part 111 and the attachment plate 102 are fixed without rattling.

  Furthermore, the opening / closing direction restricting portion 116 disposed in the housing portion 112 is disposed at a position that protrudes from the door tip of the hinged door 4 and can interfere with the panel 3 (see FIG. 2).

When the guide portion 111 and the mounting plate 102 are in a fixed state, the slide bolt 132 can be linearly moved manually inside the room 1. That is, the slide bolt 132 can be manually engaged with the receiving member 133, or the slide bolt 132 can be manually separated from the receiving member 133 (see FIGS. 3 and 4).
In a normal use mode, it is possible to switch the locking state between the slide bolt 132 and the receiving member 133 by linear movement of the slide bolt 132, but the opening / closing direction restricting portion 116 disposed in the guide portion 111 is provided on the panel 3. Because of the interference, the hinged door 4 can be locked and unlocked by the locking device 100 in a state of being restricted to the inner opening.

  On the other hand, when it is necessary to open the hinged door 4 from the outside of the room 1, the unlocking operation is performed using the dedicated key 140 on the external operation unit 104 exposed to the outside of the room 1. First, the slide bolt 132 can be separated from the receiving member 133.

  Specifically, when the operation input shaft 106 is rotated by the key 140 illustrated in FIG. 5, the rotation of the operation input shaft 106 is transmitted to the transmission shaft portion 126 of the drive unit 125. Further, when the transmission shaft portion 126 rotates, the gear portion 126b of the transmission shaft portion 126 rotates the intermediate gear 128. When the intermediate gear 128 rotates, the engaging protrusion 131a that has entered the concave portion 128b2 of the concave and convex portion 128b of the intermediate gear 128 rotates integrally with the intermediate gear 128, whereby the rotation transmitting member 131 rotates and the slide bolt 132 moves linearly. To do.

  When the slide bolt 132 moves linearly and is farthest from the receiving member 133, the ball 115 of the click mechanism 113 enters the click groove 132d of the slide bolt 132 as shown in FIG. The operator who has performed the operation is notified of the unlocking by the click feeling.

  In a state where the slide bolt 132 moves linearly and is separated from the receiving member 133, the opening / closing direction restricting portion 116 of the guide portion 111 can still interfere with the panel 3, and the hinged door 4 is restricted to open inward.

  Here, for example, when the hinged door 4 cannot be opened inward due to a person or object falling on the inner surface of the hinged door 4, the operation input shaft 106 is further rotated in the same direction by the key 140. Then, due to the rotational force transmitted from the operation input shaft 106 to the intermediate gear 128 via the transmission shaft portion 126, the concave and convex portion 128 b of the intermediate gear 128 abuts on the fitting member 129, and the stopper spring 130 biases the fitting member 129. The fitting member 129 is pressed and moved against the biasing force. As a result, the engagement protrusion 131 a formed on the fitting member 129 is pulled out from the recess 102 b of the mounting plate 102. Then, the guide portion 111 is rotatable with respect to the mounting plate 102, and the guide portion 111 is rotated with respect to the mounting plate 102 by the rotational force of the key 140 as shown in FIG.

  When the guide portion 111 rotates with respect to the mounting plate 102, the opening / closing direction restricting portion 116 disposed on the guide portion 111 also rotates integrally with the guide portion 111, so that the opening / closing direction restricting portion 116 does not interfere with the panel 3. The guide part 111 can be moved to the position. When the opening / closing direction regulating portion 116 is in a position where it does not interfere with the panel 3, the base portion 101 of the lock device 100 does not contact the panel 3, so that the hinged door 4 can be opened outward.

  As described above, in the locking device 100 according to the present embodiment, the drive unit 125 receives the unlocking operation from the external operation unit 104, so that the slide bolt 132 can be moved in a state where the guide unit 111 can contact the panel 3. The slide bolt 132 is moved by linear movement along the inner surface of the hinged door 4 until it is separated from the receiving member 133. As a result, as a first stage of the unlocking operation from the outside of the room 1, the unlocking can be performed while the state restricted to the inward opening is maintained.

  Furthermore, in the locking device 100 of the present embodiment, the drive unit 125 is configured such that the base unit 101 is the panel in a state in which the unlocking operation is transmitted from the external operation unit 104 and the slide bolt 132 is separated from the receiving member 133. The guide unit 111 is moved by a rotational movement to a position where it does not interfere with 3. As a result, as a second stage of the unlocking operation from the outside of the room 1, the hinged door 4 can be opened outward as well as opened inside.

The lock device 100 according to the present embodiment requires an operation of rotating the key 140 against the biasing force of the stopper spring 130 between the first stage and the second stage of the unlocking operation. Therefore, it is possible to conceal that the second-stage operation is possible for those who do not know that the second-stage operation is necessary. Thereby, the lock device 100 of the present embodiment can prevent the hinged door 4 from opening outward due to an inappropriate unlocking operation due to mischief or the like from the outside of the room 1.
Further, it is necessary to lift the door end side portion of the main body 108 against the gravity in the second stage of the unlocking operation, which contributes to concealing that the second stage operation is possible.

  Moreover, in the case of the hinged door 4, the person who is in the room 1 can put the weight to prevent the inner door from being opened. On the other hand, when the door is the outer door, pull the hinged door to prevent the door from being opened. May not be easy. In this respect, the locking device 100 of the present embodiment always moves the slide bolt 132 in a state of being restricted to the inside opening before allowing the hinged door 4 to be opened outside. It is possible to give a grace time until resistance to an inappropriate unlocking operation from the outside of the room 1.

  Furthermore, in the lock device 100 of the present embodiment, the first and second steps of the unlocking operation are continuously performed by rotating the key 140 in the same direction. For the operator who knows that the operation at the stage is necessary, the hinged door 4 can be quickly opened outward.

  In the locking device 100 of this embodiment, the first stage of the unlocking operation is a normal linear movement of the slide bolt 132, and the second stage of the unlocking operation is the rotational movement of the guide portion 111 with respect to the mounting plate 102. Therefore, the base part 101 of the locking device 100 can be reduced in size as compared with the case where the normal unlocking and the outer opening allowance are continuously performed only by linear movement of the slide bolt 132.

  As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, the concrete structure is not restricted to this embodiment, The design change etc. of the range which does not deviate from the summary of this invention are included.

  For example, in the above embodiment, a state in which the lock device 100 is attached to the hinged door 4 whose right side is seen from the outside of the room 1 is shown. The locking device 100 according to the above embodiment may be attached to the hinged door 4. In this case, the lock device 100 may have an inverted structure with respect to the structure shown in the above embodiment.

  In the above embodiment, an example in which the opening / closing direction restricting portion 116 is arranged on the guide portion 111 is shown, but means for abutting the panel 3 and restricting the hinged door 4 to be inwardly open is provided on the slide bolt 132. It may be done.

  In addition, the design change etc. with respect to the said specific structure are not limited to the said matter.

1 room 2 wall 3 panel 4 hinged door 100 locking device 101 base part 102 mounting plate 102a screw hole 102b hollow part 103 external unlocking part 104 external operation part 105 outer cylinder part 105a opening part 105b thread groove 106 operation input shaft 106a coupling Groove 106b Concave and convex shape 106c Groove 107 Retaining plate 108 Main body portion 109 Support cylinder portion 109a Screw thread 110 Retaining ring 111 Guide portion 112 Housing portion 112a Hole portion 113 Click mechanism 114 Spring 115 Ball 116 Opening / closing direction regulating portion 117 Housing groove 117a Opening 118 Lid 118a Rail 119 Connection body 120 First connection body 122 Non-circular nut 123 Movement restricting portion 124 Second connection body 125 Drive portion 126 Transmission shaft portion 126a Connection portion 126b Gear portion (first gear)
127 coupling mechanism 128 intermediate gear 128a second gear 128b uneven portion 128b1 convex portion 128b2 concave portion 129 fitting member 129a convex portion 129b inclined surface 130 stopper spring 131 rotation transmission member 131a engagement protrusion 131b gear (third gear)
132 Slide bolt (moving body)
132a Rack 132b Guide 132c Stopper 132d Click groove 133 Receiving member (locked member)
133a Small diameter part 133b Large diameter part 140 Key

Claims (4)

A locking device that connects a hinged door that opens and closes the doorway to a panel constituting the doorway of the room,
A base portion attachable to the hinged door;
A movable body connected to the base portion and movable relative to the base portion;
A locked member that can be fixed to the panel and that the movable body can lock;
With
The base is
A mounting plate that can be fixed to the hinged door;
An external unlocking part connected to the mounting plate for moving the moving body from the outside of the room;
With
The external unlocking part is
An external operation unit that can be attached to the hinged door so as to be exposed to the outside of the room in a state where the hinged door closes the doorway and receives an unlocking operation by an unlocking operator;
A main body connected to the mounting plate and connected to the external operation unit and capable of rotating along the inner surface with respect to the mounting plate around a rotation axis perpendicular to the inner surface of the hinged door;
The unlocking operation is transmitted from the external operation unit provided in the main body, and the movable body is engaged with the base in a state in which the base or the movable body can contact the panel by the unlocking operation. The moving body is moved by linear movement along the inner surface until the moving member is separated from the locking member, and the base part or the moving body interferes with the panel while the moving body is separated from the locked member. A drive unit that moves the base unit by the rotational movement to a position that does not,
A locking device comprising: The locking device according to claim 1,
The external operation unit is
A cylindrical part fixed to the base part;
An operation input shaft that is arranged inside the cylindrical portion and is rotatable with respect to the cylindrical portion;
Have
The drive unit is
A transmission shaft portion that is arranged inside the cylindrical portion, is connected to the operation input shaft, is rotatable integrally with the operation input shaft, and has a first gear inside the main body portion;
A coupling mechanism that is arranged inside the main body portion, transmits the rotation of the transmission shaft portion, has a second gear and an uneven portion, and the second gear meshes with the first gear;
A rotation transmission member having an engagement protrusion to be inserted into the concave portion in the concave-convex portion and having a third gear formed on the outer periphery;
Have
The moving body is a locking device having a rack that meshes with the third gear. The locking device according to claim 2,
The coupling mechanism is
An intermediate gear formed on the outer periphery of the second gear and the concavo-convex portion and rotatable around a rotation axis parallel to the rotation axis of the transmission shaft portion with respect to the main body portion within the main body portion;
A fitting member having a convex portion that can be brought into contact with the concave-convex portion and supported by the main body portion so as to be able to advance and retreat in the main body portion and fit into the mounting plate;
An urging member for urging the fitting member in a direction in which the convex portion is fitted to the mounting plate among the advancing and retreating directions of the fitting member;
Have
The intermediate gear rotates in response to the rotational force from the transmission shaft portion, thereby bringing the concave and convex portions into contact with the fitting member and pressing the fitting member against the urging force of the urging member. Moving lock device. The locking device according to claim 3,
The convex portion is inclined with respect to the advancing / retreating direction of the fitting member and is directed in a circumferential direction around the rotation axis of the transmission shaft portion in a state where the fitting member is attached to the main body portion. Having an inclined surface,
The said mounting plate is a locking device which has a hollow part which can contact the said inclined surface and can insert at least one part of the said convex-shaped part.

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