JP6139053B2 - Locking device - Google Patents

Description

  The present invention relates to a lock device in which an operation body is restricted or released.

  Conventionally, there is an electric lock that operates by being supplied with electricity. In such an electric lock, electric power is used to operate a deadbolt, and a mechanism for maintaining the locked state of the deadbolt is also operated by electric power. It is essential to secure a power source. In view of this, there is an electric lock provided with a hand-powered power generation device as a power source for operating the electric lock in preparation for a situation where electricity is not supplied from the power source at the time of a power failure or the like (see, for example, Patent Document 1). .

JP 2004-285638 A

  However, in the power generation type electric lock described in Patent Document 1, since electric power is normally supplied from an external power source, an electronic lock using such an external power source is required from the viewpoint of environmental protection that has been demanded in recent years. There is a tendency on the part of users to use an electronic lock that uses electric power generated by a manual power generator even during normal times. Also, it is desired to use an electronic lock with low power consumption that can operate for a long time even with a small battery or the like. However, the mechanism (operating part) for maintaining the locked state of the dead bolt (operating body) is one in which a large number of physical members are operated in a complex manner, and it is indispensable to ensure a large amount of power. When effective electric power cannot be secured, there is a problem that a mechanism for maintaining the deadbolt locked state does not operate.

  The present invention has been made paying attention to such problems, and an object of the present invention is to provide a lock device that can restrict or release an operating body with a small force.

In order to solve the above problems, the locking device of the present invention provides:
An operating body that performs a predetermined operation and a rotating body that is rotatable by a rotating shaft are provided, and the rotating body protrudes into a moving path of the operating body and restricts movement of the operating body. And a non-regulated portion that does not restrict movement of the operating body in the moving path of the operating body,
Wherein a rotator magnetic poles, wherein in the vicinity of the operation of the external and the rotating body are disposed electromagnet, is characterized in that the electromagnet is Ru changing the orientation of the rotating body by being energized .
According to this feature, the rotating body can protrude into the moving path to restrict the movement of the operating body, and the rotating body at the center of the rotating shaft gives a small magnetic force by the magnetic force switching means. Therefore, the operation body can be regulated and released with a small force.

The locking device of the present invention comprises:
The rotating body is disposed between both magnetic poles of the electromagnet, and the rotating shaft of the rotating body is disposed close to one of the two magnetic poles.
According to this feature, since the magnetic force generated from each magnetic pole is applied to the rotating body in a slightly unbalanced state, the direction of the rotating body can be easily switched when the magnetic force of the electromagnet is generated, and even if the electric power supplied to the electromagnet is very small The direction of the rotating body can be switched.

It is a perspective view which shows the fixture provided with the electric power generating apparatus in Example 1. FIG. It is a fragmentary sectional view which shows the internal structure of the door of a fixture. It is a top view which shows a power generator. It is a circuit diagram showing a power generator. It is a front view which shows the electric power generating apparatus before operation. It is a front view which shows the state by which the tooth | gear part of an operation gear is engaged with the tooth | gear part of an electric power generation gear at the time of locking. It is a front view which shows the state by which energy is stored in a coil spring at the time of locking. It is a front view which shows the state by which energy is discharge | released to a coil spring at the time of locking. It is a front view which shows the state by which the tooth | gear part of an operation gear is engaged with the tooth | gear part of an electric power generation gear at the time of unlocking. It is a front view which shows the state by which energy is stored in a coil spring at the time of unlocking. It is a front view which shows the state by which energy is discharge | released to a coil spring at the time of unlocking. It is a front view which shows the power generator in an unlocked state. It is a front view which shows the power generator in a locked state. It is explanatory drawing which shows the direction of the force added to a rotary body from a dead bolt. It is explanatory drawing which shows the relationship between an electromagnet and a rotary body. (A) is a front view which shows the rotary body in an Example. (B) is a front view showing a rotating body in Modification 1. FIG. (C) is a front view which shows the rotary body in the modification 2. FIG. (A) is a front view which shows the electric power generating apparatus in Example 2. FIG. (B) is a front view showing the unlocked power generator. (C) is a front view which shows the power generator in a locked state.

  EMBODIMENT OF THE INVENTION The form for implementing the locking device based on this invention is demonstrated below based on an Example.

  The locking device according to the embodiment will be described with reference to FIGS. Reference numeral 1 in FIG. 1 is a fixture 1 (door device) installed in an office or the like. The fixture 1 is provided with a double door 2. The door 2 is provided with a handle portion 3 for opening the door 2 and a knob portion 4 (operation portion) for locking and unlocking the door 2. The handle portion 3 is linked to a latch mechanism (not shown) so that the door 2 is not inadvertently opened by the latch mechanism, and the latch mechanism is released by gripping the handle portion 3 so that the door is opened. 2 can be opened.

  As shown in FIG. 2, a power generator 6 to which the present invention is applied is provided inside the door 2. The power generation device 6 includes the knob 4 described above, and locks and unlocks the door 2 and is also linked to an authentication unit (not shown). An operator who is permitted to authenticate by the authentication unit can lock and unlock the door. It can be carried out.

  The power generation device 6 has an operating body 7 that is a rectangular bar-shaped member for making the door 2 unopenable, and the operating body 7 is moved in the engagement direction (left direction). Thus, the front end portion is inserted into and engaged with a receiving seat 8 (engaged portion) formed on the other door 2, and the door 2 cannot be opened. Further, when the operating body 7 is moved in the release direction (rightward direction), the distal end portion thereof is detached from the receiving seat 8 formed on the other door 2, and the door 2 can be opened.

  Next, the power generator 6 will be described in detail. As shown in FIGS. 3 and 5, the power generation device 6 is provided on the rear surface side of the front plate 12 constituting the front surface of the door 2, and the power generation device 6 is a substantially plate attached to the front plate 12 on the rear surface side. A mounting bracket 13 is formed. The mounting bracket 13 is provided with a guide portion 14 (path) formed by two upper and lower ridges to guide the operating body 7 in a straight line. The moving body 7 can move in the left-right direction along the guide portion 14.

  The knob 4 described above has a substantially circular shape when viewed from the front, and is arranged in a knob arrangement member 15 provided on the front plate 12. An operation gear 16 that is rotated simultaneously with the rotation of the knob 4 is provided on the rear surface side of the knob 4. The tooth portion 17 of the operation gear 16 is formed on a part of the circumference of the circular operation gear 16. In addition, the knob | pick part 4 and the operation gear 16 are relatively fixed by the interlocking shaft 18 (refer FIG. 3). An operation pin 19 provided near the circumference of the operation gear 16 is provided on the rear surface side of the operation gear 16.

  As shown in FIG. 5, the operating body 7 is formed with a long hole 20 extending vertically to engage the operation pin 19. When the operator rotates the knob 4, the operation gear 16 is rotated in the circumferential direction, and the position of the operation pin 19 is moved along with the rotation of the operation gear 16. The force is transmitted from the long hole 20 to the operation body 7 through the operation pin 19. In this embodiment, when the operator rotates the knob 4 counterclockwise, the operating body 7 moves in the engagement direction (left direction), and the operator rotates the knob 4 clockwise. Thus, the operating body 7 moves in the detaching direction (right direction).

  By operating the knob 4 in this way, the rotation direction of the operation gear 16 and the movement direction of the operating body 7 are operated in the engagement direction (forward direction) or the release direction (reverse direction), respectively. Yes.

  Moreover, the generator 21 (power generation part) is attached to the rear part of the mounting bracket 13 of the power generation device 6 (see FIG. 3). The generator 21 generates a direct current (first function). A power generation gear 22 that drives the generator 21 is provided above the operation gear 16. The power generation gear 22 is fixed relative to the drive shaft 24 of the generator 21, and the power generation gear 22 is rotated around the drive shaft 24. The power generation gear 22 is formed with teeth 23 around the entire periphery thereof, and the teeth 17 of the operation gear 16 are engaged with the power generation gear 22.

  Furthermore, the power generation gear 22 has a pair of left and right coil springs 25 configured as elastic members having elasticity at the left and right ends thereof. One end of the coil spring 25 is attached to the power generation gear 22, and the other end of the coil spring 25 is attached to the mounting bracket 13. The power generation gear 22 is rotatable in the circumferential direction. However, the power generation gear 22 is stably held at a fixed position in the circumferential direction by the urging forces of the left and right coil springs 25. ing. The power generation gear 22 and the coil spring 25 constitute energy storage means in this embodiment.

  Further, in the vicinity of the right end side of the guide portion 14, a substantially circular rotating body 27 (regulating member) that is rotatable by a rotating shaft 26 is provided. A part of the rotating body 27 is cut out linearly to form a cutout portion 28. As shown in FIG. 5, when the rotating body 27 is rotated and the cutout portion 28 is in the lower position, the operating body 7 can move to the detachment position on the rightmost side. As shown in FIG. 13, when the rotating body 27 is rotated and the cutout portion 28 is in the upper position, a part of the rotating body 27 is arranged inside the guide portion 14, and the operating body 7 rotates. The moving operation is restricted (locked) by contacting the body 27.

  As shown in FIG. 5, a permanent magnet 29 (magnetic member) having magnetism is provided inside the rotating body 27. The rotating body 27 is rotated by applying a magnetic force to the permanent magnet 29 from the outside. When the cutout portion 28 of the rotating body 27 is in the lower position, the direction of the magnetic pole of the permanent magnet 29 is N pole on the left side and S pole on the right side. An electromagnet 30 (magnetic force switching means) that applies a magnetic force to the rotating body 27 is disposed above the rotating body 27. The electromagnet 30 has a coil formed of a copper wire arranged around an iron core. The rotating body 27 and the electromagnet 30 constitute an operating part in this embodiment.

  As shown in FIG. 4, electric wires 32 extend from the two electrodes 31 of the generator 21, and the electric wires 32 are connected to the coil of the electromagnet 30. The electric wire 32 is provided with an ON / OFF switch 33 controlled by authentication means (not shown). When the authentication is permitted, the switch 33 between the generator 21 and the electromagnet 30 is turned on (energized state). Further, when the authentication is impossible, the switch 33 between the generator 21 and the electromagnet 30 is turned off (energization disabled state).

  As shown in FIG. 5, when an operator performs a locking operation, authentication is first performed by an authentication unit (not shown). When the authentication is permitted, the switch 33 between the generator 21 and the electromagnet 30 is turned on (energized state). Thereafter, the operator rotates the knob 4 counterclockwise. Then, the operating body 16 is rotated in accordance with the rotation of the knob 4 so that the operating body 7 is moved in the engaging direction (left direction).

  As shown in FIG. 6, when the operating body 7 is moved by a predetermined amount, that is, when the operation gear 16 is rotated by a predetermined amount, the tooth portion 17 of the operation gear 16 engages with the tooth portion 23 of the power generation gear 22. The gears 16 and 22 are linked to each other. As the operation gear 16 rotates counterclockwise, the power generation gear 22 rotates clockwise. As the power generation gear 22 rotates, the left and right coil springs 25 of the power generation gear 22 start to extend.

  As shown in FIG. 7, when the knob 4 is rotated by the manual operation of the operator and the operation gear 16 is continuously rotated, the energy by the manual operation applied to the knob 4 extends the coil spring 25. In the coil spring 25, a stroke associated with the movement of the operating body 7, that is, a part of the stroke associated with the rotation of the knob 4 is stored as mechanical energy that is an extension of the coil spring 25.

  As shown in FIG. 8, when the operation gear 16 is further rotated by a predetermined amount, the tooth portion 17 of the operation gear 16 is disengaged from the tooth portion 23 of the power generation gear 22, and the linked state of the gears 16 and 22 is cut off. And the coil spring 25 shortens at a stretch by the restoring force which the coil spring 25 has, mechanical energy stored in the coil spring 25 is instantaneously released, and the power generation gear 22 is rotated counterclockwise.

  The generator 21 generates power by the rotation of the power generation gear 22. At this time, the electric power generated by the generator 21 is a direct current. Furthermore, since the mechanical energy stored in the coil spring 25 is released instantaneously, a high voltage can be generated. Note that the tooth release portion 17 of the operation gear 16 is disengaged from the tooth portion 23 of the power generation gear 22, and the linkage state of the gears 16 and 22 is cut off, whereby the instantaneous release means in this embodiment is configured.

  Further, the electric power generated by the generator 21 is supplied to an electromagnet 30 disposed above the rotating body 27. Then, the energized electromagnet 30 is temporarily magnetized to generate a magnetic field in which the left end of the electromagnet 30 has an N pole and the right end has an S pole (see FIG. 15). At this time, due to the magnetic force generated by the electromagnet 30, the permanent magnet 29 inside the rotating body 27 is affected by the magnetic force, so that the rotating body 27 is rotated about the rotating shaft 26 and its direction is switched. Yes. Note that the direction of the rotating body 27 is switched by being rotated 180 °. Note that the operating body 7 can move to the leftmost engagement position regardless of the orientation of the rotating body 27.

  As shown in FIGS. 7 and 8, the cutout portion 28 of the rotating body 27 is disposed at a lower position before the direction of the rotating body 27 is switched. After the electromagnet 30 is energized, a part of the rotating body 27 is arranged in the guide portion 14 after the direction of the rotating body 27 is switched. A part of the rotating body 27 disposed in the guide portion 14 serves as a regulating member that regulates (locks) the movement of the operating body 7 as will be described later.

  As shown in FIG. 15, the rotating body 27 is disposed at an intermediate position T between both magnetic poles (both ends) of the electromagnet 30, and the rotating shaft 26, which is the center of the rotating body 27, is intermediate between both magnetic poles of the electromagnet 30. Arranged from the position T toward either one of the two magnetic poles. In the present embodiment, the rotating shaft 26 is arranged slightly closer to the left side.

  By doing so, the direction of the rotating body 27 is determined along the direction of the magnetic field lines of both magnetic poles of the electromagnet 30, and the magnetic force generated from each magnetic pole is applied to the rotating body 27 in a slightly unbalanced state. When the magnetic force of the electromagnet 30 is generated, the direction of the rotating body 27 can be easily switched, and the direction of the rotating body 27 can be switched even if the amount of electric power supplied to the electromagnet 30 is very small.

  As shown in FIG. 16 (a), the rotating body 27 has a notch 28 formed by cutting out a part of a perfectly circular virtual circle E in a straight line, and the notch 28 is formed. The weight of the rotating body 27 is reduced by that amount, and the center of gravity G of the rotating body 27 is arranged at a position deviating from the center position C of the virtual circle E. Therefore, the center of the rotating shaft 26 is modified and arranged so as to coincide with the center of gravity G of the rotating body 27. In this way, by correcting the center of gravity position G deviating from the center position C of the virtual circle E of the rotating body 27 to the rotation shaft 26, the center of gravity correcting means is configured.

  By doing so, the moment of inertia when the rotating body 27 is rotated about the rotating shaft 26 is minimized, and the rotating body 27 becomes easy to rotate, that is, a small amount of work, that is, electric power supplied to the electromagnet 30. Even if the amount is small, the direction of the rotating body 27 can be switched.

  As shown in FIG. 9, when the operator performs unlocking, authentication is first performed by an authentication means (not shown). When the authentication is permitted, the switch 33 between the generator 21 and the electromagnet 30 is turned on (energized state). Thereafter, the operator rotates the knob 4 clockwise. Then, the operating body 16 is rotated in accordance with the rotation of the knob 4 so that the operating body 7 is moved in the detaching direction (right direction).

  When the operating body 7 is moved by a predetermined amount, that is, when the operation gear 16 is rotated by a predetermined amount, the tooth portion 17 of the operation gear 16 is engaged with the tooth portion 23 of the power generation gear 22, and the gears 16 and 22 are mutually connected. It is supposed to be linked. Then, along with the clockwise rotation of the operation gear 16, the power generation gear 22 is rotated counterclockwise. As the power generation gear 22 rotates, the left and right coil springs 25 of the power generation gear 22 start to extend.

  As shown in FIG. 10, when the knob 4 is rotated by the manual operation of the operator and the operation gear 16 is continuously rotated, the energy by the manual operation applied to the knob 4 extends the coil spring 25. In the coil spring 25, a stroke associated with the movement of the operating body 7, that is, a part of the stroke associated with the rotation of the knob 4 is stored as mechanical energy that is an extension of the coil spring 25.

  As shown in FIG. 11, when the operation gear 16 is further rotated by a predetermined amount, the tooth portion 17 of the operation gear 16 is disengaged from the tooth portion 23 of the power generation gear 22, and the linked state of the gears 16 and 22 is cut off. And the coil spring 25 shortens at a stretch by the restoring force which the coil spring 25 has, mechanical energy stored in the coil spring 25 is instantaneously released, and the power generation gear 22 is rotated clockwise. The generator 21 generates power by the rotation of the power generation gear 22. At this time, the electric power generated by the generator 21 is a direct current like the electric power generated during the locking operation described above, but the polarity of the electrodes is reversed.

  That is, the electric power generated by the generator 21 is supplied to an electromagnet 30 disposed above the rotating body 27. In the electromagnet 30, a magnetic field in which the left end portion of the electromagnet 30 is an S pole and the right end portion is an N pole. Will occur. Thus, the polarity of the electrode of the generator 21 when the knob 4 is operated in the engaging direction (forward direction) and the generator 21 when the knob 4 is operated in the detaching direction (reverse direction). The polarities of the electrodes are reversed from each other.

  The permanent magnet 29 inside the rotator 27 is influenced by the magnetic force generated by the electromagnet 30, and the rotator 27 is rotated around the rotation shaft 26, and the direction is switched. In this manner, the rotating body 27 that operates with the electromagnet 30 can be controlled by the magnetic poles of the electromagnet 30, and the rotating body 27 can be controlled by the operator manually operating the knob 4.

  As shown in FIG. 12, after the direction of the rotating body 27 is switched, the cutout portion 28 of the rotating body 27 is disposed at the lower position, and the operating body 7 can move to the detaching position. The operator can open the fixture 1 and the door 2 by rotating the knob 4 clockwise to move the operating body 7 to the detachment position.

  When an operator performs a locking operation or an unlocking operation, authentication is first performed by an authentication unit (not shown). If authentication is not possible, the generator 21 and the electromagnet 30 are connected. In the meantime, the switch 33 is turned off (unenergized state) (see FIG. 4). When the operator rotates the knob 4 in this state, the operation gear 16 and the power generation gear 22 are rotated, but the switch 33 between the generator 21 and the electromagnet 30 is in the OFF state (energization is not possible). Therefore, the electromagnet 30 is not energized, and the rotating body 27 is not rotated.

  For example, as shown in FIG. 13, when authentication is not possible, even if the operator operates the knob 4 when unlocking, the end of the operating body 7 contacts the rotating body 27. The movement is regulated. In this state, the distal end portion of the operating body 7 is inserted and engaged with a receiving seat 8 (engaged portion) formed on the other door 2, and the door 2 can be opened. Can not.

  Further, as shown in FIG. 14, when the distance between the center of the rotating shaft 26 of the rotating body 27 and the circumferential portion (edge) of the rotating body 27 is L1, the distance from the center of the rotating shaft 26 of the rotating body 27 is as follows. When the distance to the guide part 14 that is the movement path of the operating body 7 is L2, the relationship between L1 and L2 is L1> L2.

  In this way, the distance from the rotation shaft 26 of the rotating body 27 to the circumferential portion of the rotating body 27 is larger than the distance L2 from the rotating shaft 26 of the rotating body 27 to the guide portion 14 that is the moving path of the operating body 7. Because the distance L1 is long, when the operating body 7 moves along the guide portion 14, the operating body 7 contacts the rotating body 27, and the rotating body 27 rotates due to the force applied to the rotating body 27 from the contacted position. It can be added toward the shaft 26 to restrict further movement of the operating body 7.

  That is, when the end of the operating body 7 comes into contact with the rotating body 27, the corner of the end of the operating body 7 contacts the circumference of the rotating body 27 and is applied to the rotating body 27 from the contacted portion. The vector α (force) becomes a vector β applied to the rotating shaft 26 of the rotating body 27, and the rotating body 27 is prevented from being rotated by the vector α (force) applied to the rotating body 27 by the contact of the operating body 7. And the restriction of movement of the operating body 7 can be maintained.

  That is, the part other than the notch 28 in the rotating body 27 (circumferential part of the rotating body 27) is a restricting part that regulates the operating body 7 when the corner of the operating body 7 is contacted. The movement of the operating body 7 is restricted by this restriction part. Then, the movement of the operating body 7 can be regulated by the rotating body 27, and the rotating body 27 that can be rotated by the rotating shaft 26 can switch its direction with a small amount of electric power (work amount). The restriction of the operating body 7 can be released by switching the direction of the body 27. The cutout portion 28 of the rotating body 27 is a non-regulated portion that is not restricted in movement in the moving path of the operating body 7.

  As described above, the movement of the operating body 7 can be regulated by the rotating body 27 and the direction of the rotating body 27 at the center of the rotating shaft 26 can be changed with a small amount of work. And its release can be done with a small force. Further, at least a part of the rotating body 27 is notched, and the notched portion 28 is a non-regulated portion that does not block the path of the operating body 7, so that the notched portion 28 is formed in the rotating body 27. The movement of the operating body 7 can be allowed with a simple configuration.

  In the power generation device 6 in the present embodiment, the rotating body 27 that can be rotated by the rotating shaft 26 can switch the direction with a small amount of electric power (work amount), and the position of the rotating body 27 does not change. By switching the direction, the operating body 7 that physically operates along the guide portion 14 can be regulated or released, and the operating body 7 can be regulated or released with a small amount of electric power. .

  In addition, the rotating body 27 has a permanent magnet 29, and an electromagnet 30 is disposed in the vicinity of the rotating body 27, and the direction of the rotating body 27 is switched by energizing the electromagnet 30. With a simple configuration of the rotating body 27 having the permanent magnet 29 and the electromagnet 30, the operation body 7 can be regulated or released. Further, the amount of power consumed by the electromagnet 30 only needs to be able to secure the amount of power that can switch the direction of the rotating body 27, so that the operation body 7 can be regulated or released with less power consumption, and the power consumption can be reduced. The power generation device 6 can be obtained.

  Further, the direction of the rotating body 27 can be switched by the magnetic force, and it is not necessary to provide a mechanical element such as a spring member that performs a mechanical operation in addition to the rotating body 27 for switching the direction of the rotating body 27. The direction of the rotating body 27 can be switched with a small amount of work.

  Thus, since the electric power generated using the manual operation of the operator is used for the operation of the power generation device 6 having the rotating body 27 that performs the operation of the physical machine, the power consumption of the entire fixture 1 can be suppressed. it can.

  As described above, the operation gear 16 and the power generation gear 22 are linked when the operator rotates the knob 4 by a manual operation to move the operating body 7 by a predetermined amount. That is, the operating body 7 is operated along the guide portion 14 by manual operation, and the operation gear 16 and the power generation gear 22 are linked while the operating body 7 is operating in a region away from the rotating body 27 in the guide portion 14. The coil spring 25 stores a part of the stroke associated with the movement of the operating body 7 as mechanical energy.

  In this way, a part of the stroke accompanying the movement of the operating body 7 can be applied to the coil spring 25 regardless of the direction in which the rotating body 27 regulates the operating body 7 or the direction in which the regulation is released. Can be stored as mechanical energy, and the generator 21 generates power using the mechanical energy released when the linkage state of the operation gear 16 and the power generation gear 22 is cut off. When the direction is switched, since the operating body 7 is in a region away from the rotating body 27, there is no possibility that the rotating of the rotating body 27 is obstructed by the operating body 7.

  As described above, in the rotating body 27 of the present embodiment, the center of gravity is corrected by correcting the center of the rotating shaft 26 so as to coincide with the center of gravity G of the rotating body 27. Next, a rotating body 27 as a modification will be described.

  As shown in FIG. 16 (b), in the rotating body 27a in the first modification, a part of the phantom circle E having a perfect circle shape is notched in a straight line to form the first notch portion 28. In addition, a second cutout portion 28 ′ is formed on the circumference facing the first cutout portion 28 with the rotation shaft 26 interposed therebetween. The second cutout portion 28 ′ is formed by cutting out a part of the circumference of the rotating body 27 a into a semicircular shape. In the first modification, when the first cutout portion 28 is formed at a position below the rotation shaft 26, the second cutout portion 28 ′ is formed at a position above the rotation shaft 26. By forming the second cutout portion 28 ′, the center of gravity G of the rotating body 27 is arranged at the center position C of the virtual circle E. The second notch 28 'constitutes the center of gravity correcting means of this embodiment.

  As shown in FIG. 16 (c), in the rotating body 27b in the second modification, a part of the virtual circle E in which the rotating body 27b is a perfect circle is cut out in a straight line to form a cutout portion 28. Further, in addition to the portion where the notch portion 28 is formed around the rotation shaft 26, a lightening portion 34 having a predetermined size is formed. The hollow portion 34 is a hole formed in the rotating body 27b. In the second modification, when the cutout portion 28 is formed at a position below the rotation shaft 26, the lightening portions 34 are formed at three positions, the upper position and the left and right positions of the rotation shaft 26. By forming the cutout portion 34, the center of gravity G of the rotating body 27 is arranged at the center position C of the virtual circle E. In addition, this thinning part 34 comprises the gravity center correction | amendment means of a present Example.

  In the first embodiment, when the operating body 7 moves along the guide portion 14, the operating body 7 comes into contact with the rotating body 27, and further operation is performed by the force applied to the rotating body 27 from the contacted position. Although the movement of the body 7 can be regulated, the moving body 7 contacts a predetermined portion of the guide portion 14 (path), and the further moving body is applied by the force applied to the guide portion 14 from the contacted portion. 7 movement may be restricted.

  As shown in FIG. 17 (a), in the power generation device 6 'according to the second embodiment, the guide portion 14 has a non-linear shape, and a part thereof is bent upward. The bent portion of the guide portion 14 is provided with a slope-like slope portion 14a on which the operating body 7 rides.

  As shown in FIG. 17B, when the rotating body 27 is rotated and the cutout portion 28 is in the lower position, the operating body 7 is allowed to move upward, and the slope 14a of the guide section 14 is moved to the operating body 7. , And the moving body 7 is moved in the release direction (right direction).

  As shown in FIG. 17C, when the rotating body 27 is rotated and the notch 28 is in the upper position, the rotating body 27 comes into contact with the upper end of the operating body 7 and the operating body 7 moves upward. Is restricted, and the operating body 7 cannot ride on the slope 14a of the guide section 14, the tip of the operating body 7 comes into contact with the slope section 14a of the guide section 14, and the presence of this slope section 14a causes the further operating body 7 Movement in the release direction (right direction) is regulated.

  Although the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. It is.

  For example, in the said Example, although the electric power generating apparatus 6 to which this invention was applied with respect to the door 2 of the fixture 1 installed in an office etc. is provided, the electric power generator 6 is not only the door 2 of the fixture 1. Electricity is required in combination with the drawer and lid locking device provided in the fixture 1 or the like, or the locking device that locks not only the fixture 1 but also the doors and windows of the entrance of the house, and manual operation by humans It is clear that the present invention can be applied to a wide range of fields such as machine tools.

  Moreover, in the said Example, although the electric power supplied with electricity to the electromagnet 30 is supplied from the generator 21 which generate | occur | produces by an operator's manual operation, the electric power supplied with the electromagnet 30 is except generator 21. The battery may be supplied from a battery or the like.

  In the said Example, although the locking device of this invention is applied to a locking / unlocking apparatus and an engaging member is illustrated as an operation body which a rotation body controls a movement, it is applicable also to another use. For example, a linearly moving member such as a sliding door may be used as an operating body, and the movement may be regulated by bringing a rotating body into contact with a part of the sliding door or the like. A rotating knob provided on a board or the like may be an operating body, and the movement may be regulated by bringing the rotating body into contact with a part of the knob. As described above, the present invention can be applied not only to furniture installed in an office or the like but also to other uses.

1 Furniture (door device)
4 Picking part (operation part)
6,6 'Power generation device (lock device)
7 Action body 14 Guide part (route)
14a Sakabe 16 Operation gear 21 Generator (Power generation part)
22 Power generation gear (energy storage means)
25 Coil spring (energy storage means)
27 Rotating body (actuating part, regulating member)
27a Rotating body (actuating part, regulating member)
27b Rotating body (actuating part, regulating member)
28 Notch part, 1st notch part 28 '2nd notch part 29 Permanent magnet (magnetic member)
30 Electromagnet (actuating part)
34 Meat extraction part (center of gravity correction means)

Claims (2)

An operating body that performs a predetermined operation and a rotating body that is rotatable by a rotating shaft are provided, and the rotating body protrudes into a moving path of the operating body and restricts movement of the operating body. And a non-regulated portion that does not restrict movement of the operating body in the moving path of the operating body,
The rotating body has a magnetic pole in the vicinity of the external and the rotating body of the operation body electromagnet is disposed, the electromagnet, characterized in that Ru changing the orientation of the rotating body by being energized Locking device. The rotating body is disposed between the magnetic poles of the electromagnet, the rotation axis of the rotating body, to claim 1, characterized in that it is arranged close to either side of said magnetic poles The locking device as described.

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