JP6848764B2 - Circuit breaker - Google Patents

Description

The techniques disclosed herein relate to barriers.

In Patent Document 1, a balance weight is attached to the base end of the rod, and the first rod and the second rod, which are rotatably supported by a shaft near the balance weight, are arranged facing each other. A barrier-type safety fence that is installed and opens and closes from both sides is disclosed.

Jikkenhei 5-3596 Gazette

Conventionally, in a breaker provided with two cutoff rods, a configuration in which the two cutoff rods are operated in synchronization with only a mechanical configuration is not known.

The technique disclosed herein is intended to provide a barrier that allows passers-by to safely pass through a passage by operating two barrier bars in synchronization with only a mechanical configuration.

The breakers disclosed by the present specification include a first blocking position that blocks the passage of the first passage and a first standing position that stands up from the first blocking position and allows the passage of the first passage. A first blocking rod that is rotatable between the first blocking rods and is configured to lie down from the first standing position to the first blocking position by its own weight, and the first blocking rod that is attached to the first blocking rod. A first shaft forming a rotation shaft between the cutoff position and the first standing position, a second shaft that rotates in conjunction with the rotation of the first shaft, and a second shaft attached to the second shaft. A transmission member that transmits power from the second shaft, a second blocking position that blocks the passage of the second passage, and a second that stands up from the second blocking position and allows the passage of the second passage. A second blocking rod that is rotatable between the standing position and is configured to stand up from the second blocking position to the second standing position by its own weight, and the second blocking rod are placed in the second blocking position. With a lock mechanism that can be locked to the above, the power transmitted from the transmission member as the first blocking rod is changed from the first blocking position to the first standing position is utilized. In a state where the second blocking rod is changed from the second standing position to the second blocking position and the second blocking rod is locked to the second blocking position by the locking mechanism, the first blocking rod is locked by its own weight. In the process of changing from the first standing position to the first blocking position and changing the first blocking rod to the first blocking position, the locking mechanism utilizes the power transmitted from the transmission member. The lock of the second blocking rod is released, and the second blocking rod unlocked by the locking mechanism is configured to be changed from the second blocking position to the second standing position by its own weight.

According to such a barrier, a person passing through the first passage changes the first barrier rod from the first barrier position to the first standing position, thereby changing the second barrier rod to the second barrier position. can do. Then, after the first blocking rod is changed from the first blocking position to the first standing position, the first blocking rod is automatically changed from the first standing position to the first blocking position, and after a lapse of a predetermined time, The second blocking rod is automatically changed from the second blocking position to the second standing position. For this reason, the two blocking rods are operated in synchronization only with a mechanical configuration, and when a person passing through the first passage passes through the second passage until a predetermined time elapses. It is possible to block the passage of people, and it is possible to safely pass through the passage without crossing the two.

In the above configuration, the first shaft and the second shaft may be arranged in a relationship of an intersecting shaft or a staggered shaft, and further provided with a conversion mechanism for converting the rotation direction of the first shaft and transmitting it to the second shaft. Good. According to such a configuration, at the intersection of the first passage and the second passage that intersect each other, when a person passing through the first passage crosses the second passage, the passage of the second passage is performed. It can be blocked. Therefore, a person passing through the first passage can safely cross the second passage.

In the above configuration, a damper may be further provided that imparts resistance to the operation in which the first blocking rod falls down from the first standing position to the first blocking position due to its own weight. According to such a configuration, the timing at which the lock of the second blocking rod is released by the locking mechanism can be adjusted, and the time for blocking the passage of the second passage by the second blocking rod can be appropriately set. it can.

In the above configuration, the lock mechanism engages with the ratchet claw when the second blocking rod rotates from the second blocking position to the second standing position, and the second blocking is engaged with the pawl portion having the ratchet claw. The transmission member is composed of a ratchet gear that separates from the ratchet claw when the rod rotates from the second standing position to the second blocking position, and the transmission member is stopped at the first blocking position of the first blocking rod. It may be configured to disengage the ratchet claw and the ratchet gear by abutting against the portion. According to such a configuration, it is possible to preferably realize the locking and unlocking of the second blocking rod by the locking mechanism.

According to the technique disclosed herein, it is possible to provide a barrier that allows a passerby to safely pass through a passage by operating two barrier rods in synchronization with only a mechanical configuration.

Explanatory drawing which shows the initial operation mode of the breaker which concerns on one Embodiment Explanatory drawing which shows operation mode of a breaker before a predetermined time elapses after operation Explanatory drawing which shows operation mode of the breaker when the 1st break bar is in a bent posture Front view of the barrier seen from the front Side view of the barrier seen from the inside A plan view of the breaker viewed from above at the first cutoff position of the first cutoff rod (the upper part is omitted from the upper mounting surface of the base). A plan view of the breaker viewed from above at the first standing position of the first cutoff rod (the upper part is omitted from the upper mounting surface of the base). Enlarged side view of the breaker viewed from the outside at the first cutoff position of the first cutoff rod. Enlarged side view of the breaker viewed from the outside in the process of changing the first cutoff bar from the first cutoff position to the first standing position. Enlarged side view of the breaker viewed from the outside at the first standing position of the first cutoff rod. Enlarged side view of the barrier viewed from the outside in the process of changing the first blocking rod from the first standing position to the first blocking position. An enlarged side view of the breaker viewed from the outside just before the lock state of the second break bar is released. Explanatory drawing which shows the mode that the lock mechanism in a locked state is changed to the unlocked state. Enlarged side view of the breaker viewed from the outside after the lock state of the second break bar is released.

An embodiment of the present invention will be described with reference to FIGS. 1 to 14. In the present embodiment, the breaker 10 installed at the intersection of the first passage 11 and the second passage 12 is illustrated. The first passage 11 is a passage for pedestrians, and the second passage 12 is a passage for vehicles such as forklifts. In each figure, the extending direction of the first passage 11 is represented by the X-axis direction, the extending direction of the second passage 12 is represented by the Y-axis direction, and the vertical direction is represented by the Z-axis direction.

As shown in FIGS. 4 and 6, the breaker 10 includes a first cutoff rod 30, a first shaft 41, a second shaft 44, a transmission member 60, a second cutoff rod 70, and a lock mechanism 80. (See FIG. 13) and. Further, in the present embodiment, the breaker 10 has a conversion mechanism 40 that converts the rotation direction of the first shaft 41 and transmits the rotation direction to the second shaft 44, and a damper 50 that imparts resistance to the operation of the first cutoff rod 30. (See FIG. 5). The breaker 10 is integrally provided so that each of these parts is supported by the base 20. In the following description, the breaker 10 will be described with the right side of FIG. 4 as the inner side, the left side as the outer side, the left side of FIG. 5 as the front side, and the right side as the rear side.

As shown in FIGS. 1 to 3, a pair of breakers 10 are provided at the opposing corners 14A and 14B at the intersection of the first passage 11 and the second passage 12. The pair of breakers 10 and 10 have the same configuration as each other. Each breaker 10 is installed so that the inner side surface 20B of the base 20 faces the first passage 11 and the front surface 20A of the base 20 faces the second passage 12. Then, in the barrier 10, the first blocking rod 30 arranged on the front surface 20A side of the base 20 blocks the passage of the first passage 11 in a posture of crossing the first passage 11, and the base 20 is also used. The second blocking rod 70 arranged on the outer surface 20C side of the above is configured to block the passage of the second passage 12 in a posture of crossing the second passage 12. The installation mode of the breaker 10 is not limited to this, and can be changed as appropriate. For example, when the first passage 11 is a one-way street, one barrier 10 may be used alone. Further, when the second passage 12 is a one-way street or the like, a pair of breakers having a structure symmetrical with each other may be provided at the corners 14A and 14C located so as to sandwich the second passage 12.

As shown in FIGS. 4 and 5, the base 20 has a yagura structure and is installed on a horizontal ground or floor near the waist position of a passerby P passing through the first passage 11. It has an upper mounting surface 21 located and a lower mounting surface 22 located below the upper mounting surface 21. Further, the base 20 is located at the same height as the upper mounting surface 21, and the first support portion 24 that supports the first blocking rod 30 from below and the first support portion 24 above the upper mounting surface 21. A first stopper portion 26 that restricts further rotation of the blocking rod 30, a second supporting portion 27 that supports the second blocking rod 70 from behind above the upper mounting surface 21, and an upper mounting surface 21. It is located at the same height as the above, and has a second stopper portion 28 that restricts further rotation of the second blocking rod 70. A cover member is attached to the base 20 so as to cover most of the base 20 except for the first blocking rod 30 and the second blocking rod 70. The cover member is omitted for convenience.

As shown in FIGS. 6 and 7, the first blocking rod 30 has a longitudinal first mounting plate portion 31 attached to the first shaft 41 and a longitudinal direction from one end of the first mounting plate portion 31. A first rod-shaped member 33 extending along the line and a first weight portion 35 provided at the other end of the first mounting plate portion 31 are provided. The first blocking rod 30 is rotatably supported by the first shaft 41 with respect to the base 20, and the first rod-shaped member 33 is provided so as to extend from the base 20 in a cantilever shape. Hereinafter, in the first blocking rod 30, the end portion on the side extending from the base 20 is referred to as an extension tip portion 30A, and the end portion on the opposite side thereof is referred to as an extension base end portion 30B.

As shown in FIGS. 6 and 7, the first weight portion 35 constitutes the counter weight of the first blocking rod 30 at the extension base end portion 30A of the first blocking rod 30. The first weight portion 35 is a transmission member via the first shaft 41 and the second shaft 44 and the force acting by the weight of the portion on the extension base end portion 30B side of the rotation shaft of the first blocking rod 30. The magnitude of the force acting on the sum of the forces acting from 60 is set to be smaller than the magnitude of the force acting on the weight of the portion on the extension tip portion 30A side of the rotation axis of the first blocking rod 30. There is.

As shown in FIGS. 1 and 2, the first blocking rod 30 stands at a first blocking position that blocks the passage of the first passage 11 and stands up from the first blocking position to pass the passage 11 of the first passage 11. It is rotatable to and from the permissible first standing position. The first blocking rod 30 has a rotation angle smaller than 90 degrees, is arranged in a posture in which the longitudinal direction is along the horizontal direction at the first blocking position, and is arranged in the vertical direction in the longitudinal direction at the first standing position. It is arranged in a slightly inwardly collapsed position. The first blocking rod 30 is configured to lie down from the first standing position to the first blocking position due to its own weight. In addition, not only the weight of the first blocking rod 30 but also the weight of the transmission member 60 transmitted via the first shaft 41 and the second shaft 44 acts on the operation of the first blocking rod 30 to lie down. The lodging operation of the first blocking rod 30 will be described later.

As shown in FIG. 6, the first blocking rod 30 has a hinge portion 37 near the corner between the front surface 20A and the inner side surface 20B of the base 20, and is provided on the front surface 20A and the inner side surface 20B of the base 20. It is configured so that it can be bent and deformed along it. The hinge portion 37 has a rotation axis extending in the vertical direction, and the first blocking rod 30 has an extension tip portion 30A directed rearward along the rotation axis of the hinge portion 37 in the horizontal direction. It is rotatable. In other words, the first blocking rod 30 has a configuration that can be changed between a linear posture extending linearly and a bending posture bent by the hinge portion 37. In FIG. 6, the first blocking rod 30 in the bent posture is shown by a chain double-dashed line. The hinge portion 37 is provided with an urging member (not shown) that urges the first blocking rod 30 to take a linear posture. Then, in the natural state, the first blocking rod 30 is maintained in a linear posture and is changed to a bent posture only while an external force is applied. Further, the hinge portion 37 is configured so that the extension tip portion 30A of the first blocking rod 30 can be rotated rearward, but cannot be rotated forward. With such a configuration, the passerby P who has crossed the second passage 12, that is, the passerby P who travels from the front to the rear of the barrier 10 on the corner 14B side, bends the first barrier bar 30. (See Fig. 3).

As shown in FIGS. 6 and 7, the first shaft 41 is attached to the first blocking rod 30 and constitutes a rotation axis between the first blocking position and the first standing position. The first shaft 41 is arranged along the X-axis direction and is rotatably fixed to the upper mounting surface 21 of the base 20 via a fixing member (not shown). The front end portion of the first shaft 41 extends forward from the upper mounting surface 21 and is immovably connected to the first blocking rod 30. Further, the first shaft 41 is provided with a first gear 42, which is a bevel gear constituting the conversion mechanism 40, at the rear end portion.

As shown in FIGS. 6 and 7, the second shaft 44 is configured to rotate in conjunction with the rotation of the first shaft 41. The second shaft 44 is arranged along the Y-axis direction and is rotatably fixed to the upper mounting surface 21 of the base 20 via a fixing member (not shown). The outer end of the second shaft 44 extends outward from the upper mounting surface 21 and is immovably connected to the transmission member 60. Further, the second shaft 44 is provided with a second gear 45, which is a bevel gear constituting the conversion mechanism 40, at the inner end portion.

The first shaft 41 and the second shaft 44 are arranged in a cross-axis relationship as shown in FIGS. 6 and 7. Specifically, the first shaft 41 and the second shaft 44 are arranged on the upper mounting surface 21 so that the axial angle is 90 °.

As shown in FIGS. 6 and 7, the conversion mechanism 40 is configured to convert the rotation direction of the first shaft 41 and transmit it to the second shaft 44. The conversion mechanism 40 is composed of a first gear 42 and a second gear 45, and is a miter gear having a gear ratio of 1: 1. In the conversion mechanism 40, when the first shaft 41 rotates counterclockwise when viewed from the front (first blocking rod 30 side), the second shaft 44 rotates clockwise when viewed from the outside (second blocking rod 70 side). When the first shaft 41 rotates clockwise when viewed from the front, the second shaft 44 rotates counterclockwise when viewed from the outside. The conversion mechanism 40 is configured so that when the first shaft 41 rotates at a predetermined rotation angle, the second shaft 44 rotates at the same rotation angle.

As shown in FIGS. 5 and 7, the damper 50 is configured to provide resistance to the operation of the first blocking rod 30 lying down from the first standing position to the first blocking position due to its own weight. In the present embodiment, the damper 50 is composed of rotary dampers 51 and 53 that generate torque in one direction. The rotary damper 51 has a gear 51B that is fixed to the upper mounting surface 21 of the base 20 and meshes with the gear 51A provided on the first shaft 41. The rotary damper 51 is configured to give resistance to the first shaft 41 that rotates clockwise when viewed from the front. The rotary damper 53 has a gear 53D that is fixed to the lower mounting surface 22 of the base 20 and meshes with the gear 53C connected to the second shaft 44 via the sprockets 55A and 55B interlocked by the chain 54. The sprocket 55A interlocking with the second shaft 44 and the sprocket 55B interlocking with the gear 55C have a gear ratio of 4: 1, and a torque four times the torque generated by the rotary damper 55 acts on the second shaft 44. .. The rotary damper 53 is configured to give resistance to the second shaft 44 that rotates clockwise when viewed from the outside.

As shown in FIGS. 7 and 11, the transmission member 60 is attached to the second shaft 44 and is configured to transmit power from the second shaft 44. The transmission member 60 is provided at the longitudinal transmission member side mounting plate portion 61 attached to the second shaft 44 and at the lower end portion of the transmission member side mounting plate portion 61 at the first blocking position of the first blocking rod 30. The transmission member side weight portion 63, the second blocking rod transmitting portion 65 that transmits power to the second blocking rod 70, and the lock mechanism transmitting portion 67 that abuts on the lock mechanism 80 and transmits power to the lock mechanism 80. , Equipped with. The transmission member 60 rotates with a rotation angle smaller than 90 degrees about the second shaft 44 in conjunction with the rotation of the first blocking rod 30 between the first blocking position and the first standing position. To do. The transmission member 60 is arranged at a transmission member standing position in which the longitudinal direction is slightly tilted forward from the vertical direction at the first blocking position of the first blocking rod 30, and at the first standing position of the first blocking rod 30. It is arranged at the lodging position of the transmission member along the horizontal direction in the longitudinal direction.

As shown in FIGS. 7 and 11, the transmission member side weight portion 63 constitutes the counter weight of the first blocking rod 30 in the transmission member 60. The weight portion 63 on the transmission member side is set so that the magnitude of the force acting on the first blocking rod 30 via the first shaft 41 and the second shaft 44 allows the first blocking rod 30 to fall down due to its own weight. ing. The second blocking rod transmission portion 65 rises outward from the transmission member side mounting plate portion 61, and is configured to be engaged with the second mounting plate portion 71 of the second blocking rod 70, which will be described later. The lock mechanism transmission unit 67 rises outward from the transmission member side mounting plate portion 61, and is configured to be able to press the pawl portion 81 of the lock mechanism 80, which will be described later. A mode in which power is transmitted to the second blocking rod 70 and the locking mechanism 80 via the second blocking rod transmission unit 65 and the locking mechanism transmission unit 67 will be described later.

As shown in FIGS. 6 and 8, the second blocking rod 70 is formed by a longitudinal second mounting plate portion 71 rotatably supported by the base 20 and a second mounting plate portion 71. A second rod-shaped member 73 extending from one end in the longitudinal direction and a second weight portion 75 provided at the other end of the second mounting plate 71 are provided. The second blocking rod 70 is rotatably supported with respect to the base 20 independently of the first shaft 41 or the second shaft 44, and the second rod-shaped member 73 extends cantilevered from the base 20. It is provided to do so. Hereinafter, in the second blocking rod 70, the end portion on the side extending from the base 20 is referred to as an extension tip portion 70A, and the end portion on the opposite side thereof is referred to as an extension base end portion 70B.

As shown in FIGS. 6 and 8, the second weight portion 75 constitutes the counter weight of the second blocking rod 70 at the extension base end portion 70B of the second blocking rod 70. In the second weight portion 75, the magnitude of the force acting by the weight of the portion on the extension base end portion 70B side of the rotation shaft of the second blocking rod 70 is larger than that of the rotation shaft of the second blocking rod 70. It is set so as to be larger than the magnitude of the force acting by the weight of the portion on the extension tip portion 70A side.

As shown in FIGS. 1 and 2, the second blocking rod 70 stands at a second blocking position that blocks the passage of the second passage 12 and stands up from the second blocking position to pass the passage 12 of the second passage 12. It is rotatable to and from the allowed second standing position. The second blocking rod 70 has a rotation angle smaller than 90 degrees, is arranged in a posture in which the longitudinal direction is along the horizontal direction at the second blocking position, and is slightly longer than the vertical direction at the second standing position. Arranged in a forward-falling position. The second blocking rod 70 is configured to stand up from the second blocking position to the second standing position by its own weight. The standing operation of the first blocking rod 30 will be described later.

As shown in FIG. 13, the lock mechanism 80 can lock the second blocking rod 70 to the second blocking position. The lock mechanism 80 is composed of a pawl portion 81 having a ratchet claw 82 and a ratchet gear 85. In the lock mechanism 80, the pawl portion 81 is pivotally supported with respect to the base 20, and the ratchet gear 85 is attached to the second blocking rod 70 below the pawl portion 81.

As shown in FIG. 13, the pawl portion 81 is provided with a ratchet claw 82 at one end thereof so as to project downward. The pawl portion 81 is configured such that one end side rotates downward due to its own weight with the rotation shaft as an axis. The pawl portion 81 is provided with an disengagement portion 83 for disengaging the engagement with the ratchet gear 85 on the other end side of the rotation shaft. The ratchet claw 82 and the ratchet gear 85 of the disengagement portion 83 are formed by the lock mechanism transmission portion 67 of the transmission member 60 abutting on the upper surface thereof and the pawl portion 81 rotating counterclockwise when viewed from the outside. It is configured to release the engagement with.

As shown in FIG. 13, the ratchet gear 85 engages with the ratchet claw 82 when the second blocking rod 70 rotates from the second blocking position to the second standing position, and the second blocking rod 70 is in the second standing position. It is configured to be separated from the ratchet claw 82 when it is rotated to the second blocking position. Specifically, the ratchet gear 85 has a plurality of teeth 86 projecting rearward arranged side by side around the rotation axis of the second blocking rod 70 at the upper end portion thereof, and the rear surface of the plurality of teeth 86 is a ratchet. It can be engaged with the claw 82. Therefore, when the first blocking rod 30 is changed to the first standing position, the locking mechanism 80 locks the second blocking rod 70 at a plurality of positions having a rotation angle smaller than 90 ° from the first blocking position. Is feasible.

Subsequently, the operation mode of each part will be described. In the initial state shown in FIG. 8, the barrier 10 blocks the passage of the passerby P passing through the first passage 11 with the first blocking rod 30 arranged at the first blocking position, and the second blocking rod 70. Is arranged in the second standing position, and is in a state of allowing the passage of the vehicle V passing through the second passage 12.

As shown in FIGS. 9 and 10, the breaker 10 utilizes the power transmitted from the transmission member 60 as the first cutoff rod 30 is changed from the first cutoff position to the first standing position. Therefore, the second blocking rod 70 is changed from the second standing position to the second blocking position. Specifically, the first blocking rod 30 is lifted by a passerby P traveling through the first passage 11 from the rear to the front, and the extension tip portion 30A rotates upward from the first blocking position. (See Fig. 1). No resistance is provided by the damper 50 to this operation, and the balance is appropriately adjusted by the first weight portion 35 and the transmission member side weight portion 63, so that the first blocking rod 30 is displaced from the rotation shaft. The passerby P who grips the distant position can displace the first blocking rod 30 with a relatively small load. Then, when the first shaft 41 is linked with the first blocking rod 30 and rotates counterclockwise when viewed from the front, the second shaft 44 rotates clockwise when viewed from the outside via the conversion mechanism 40. Then, the transmission member 60 rotates from the transmission member standing position to the transmission member lodging position with the second shaft 44 as the rotation axis. Then, when the second blocking rod transmitting portion 65 of the transmission member 60 comes into contact with the second blocking rod 70 and the power directed clockwise when viewed from the outside is transmitted to the second blocking rod 70, the second blocking rod 70 Starts rotation toward the second cutoff position. When the transmission member 60 starts to rotate, the lock mechanism transmission portion 67 separates from the disengagement portion 83 of the pawl portion 81, and the ratchet claw 82 rotates downward, but the second blocking rod 70 During the above-mentioned rotation operation, the teeth 86 of the ratchet gear 85 are not separated from the ratchet claw 82, and the lock mechanism 80 does not hinder the rotation of the second blocking rod 70. Then, the first blocking rod 30 reaches the first standing position at or before the position where it comes into contact with the first stopper portion 26, and the rotation of the first blocking rod 30 is stopped. Then, the rotation of the transmission member 60 also stops, and the second blocking rod 70 stops rotating at the second blocking position. Then, the passerby P passes below the first blocking rod 30, releases the hand from the first blocking rod 30, and the second blocking rod 70 rotates from the second blocking position to the second standing position by its own weight. When the ratchet claw 82 of the lock mechanism 80 engages with the ratchet gear 85, the second blocking rod 70 is locked to the second blocking position.

Then, as shown in FIG. 11, in the breaker 10, in a state where the second cutoff rod 70 is locked to the second cutoff position by the lock mechanism 80, the first cutoff rod 30 is moved from the first standing position to the second by its own weight. It is changed to 1 cutoff position. Specifically, when the passerby P releases his hand from the first blocking rod 30, the extension tip portion 30A of the first blocking rod 30 starts to rotate downward due to the action of gravity. A resistor 50 is added to this operation, and the balance is appropriately adjusted by the first weight portion 35 and the transmission member side weight portion 63, so that the first blocking rod 30 requires a predetermined time. To return to the first cutoff position. This predetermined time is appropriately determined in consideration of the time required for the passerby P to cross the second passage 12. Then, when the first shaft 41 is linked with the first blocking rod 30 and rotates clockwise when viewed from the front, the second shaft 44 rotates counterclockwise when viewed from the outside via the conversion mechanism 40. Then, the transmission member 60 rotates with the second shaft 44 as the rotation axis from the transmission member tilted position to the transmission member upright position. When the transmission member 60 starts rotating, the second blocking rod transmission unit 65 is separated from the second blocking rod 70, and the power from the transmission member 60 does not act on the second blocking rod 70, but the second blocking rod The 70 is locked to the second shutoff position by the lock mechanism 80, and stays in the second shutoff position until a predetermined time elapses.

As shown in FIGS. 12 and 14, the breaker 10 uses the power transmitted from the transmission member 60 in the process of changing the first cutoff rod 30 to the first cutoff position by the lock mechanism 80. The lock of the second blocking rod 70 is released. In the present embodiment, the transmission member 60 comes into contact with the pawl portion 81 at the first blocking position of the first blocking rod 30 to release the engagement between the ratchet claw 82 and the ratchet gear 85 (see FIG. 13). Specifically, when the first blocking rod 30 approaches the first blocking position, the transmission member 60 approaches the transmission member standing position, and the lock mechanism transmission unit 67 directs the disengagement portion 83 of the pawl portion 81 downward. Press. Then, the ratchet claw 82 located on the side opposite to the disengagement portion 83 with the rotation shaft interposed therebetween rotates upward and retracts to a position where it does not mesh with the teeth 86 of the ratchet gear 85. Then, the engagement between the ratchet claw 82 and the ratchet gear 85 is released, and the ratchet gear 85 can rotate with respect to the ratchet claw 82. When the first blocking rod 30 reaches the first blocking position, the first blocking rod 30 is supported by the first support portion 24 and stops rotating, and the rotation of the transmission member 60 also stops. At this point, a predetermined time required for the passerby P in the first passage 11 to cross the second passage 12 elapses.

Then, as shown in FIG. 14, in the breaker 10, the second cutoff rod 70 unlocked by the lock mechanism 80 is changed from the second cutoff position to the second standing position by its own weight. Specifically, the extension tip 70A of the second blocking rod 70 starts rotating upward due to the action of gravity. The balance of the second blocking rod 70 is appropriately adjusted by the second weight portion 75, so that the second blocking rod 70 quickly returns to the second standing position. Then, in the second standing position, the second blocking rod 70 is supported by the second support portion 27, and the rotation of the second blocking rod 70 is stopped. In the present embodiment, the second support portion 27 is provided with a shock absorber that absorbs the impact when the second blocking rod 70 comes into contact with the second support portion 27. As described above, the breaker 10 returns to the initial position after a lapse of a predetermined time, and the passage of the vehicle V in the second passage 12 is resumed.

Subsequently, the effect of this embodiment will be described. According to the barrier 10 of the present embodiment, a person passing through the first passage 11 changes the first blocking rod 30 from the first blocking position to the first standing position, thereby changing the second blocking rod 70 to the first standing position. 2 Can be changed to the blocking position. Then, after the first blocking rod 30 is changed from the first blocking position to the first standing position, the first blocking rod 30 is automatically changed from the first standing position to the first blocking position, and a predetermined time elapses. Later, the second blocking rod 70 will be automatically changed from the second blocking position to the second standing position. Therefore, the two blocking rods 30 and 70 are operated in synchronization with only the mechanical configuration, and when a person passing through the first passage 11 passes through, the second blocking rod 30 and 70 are operated until a predetermined time elapses. It is possible to block the passage of a person passing through the passage 12, and the passages 11 and 12 can be safely passed without crossing the two.

Further, in the present embodiment, the first shaft 41 and the second shaft 44 are arranged in a relationship of intersecting axes, and further include a conversion mechanism 40 that converts the rotation direction of the first shaft 41 and transmits it to the second shaft 44. Therefore, at the intersection of the first passage 11 and the second passage 12 that intersect each other, when a person passing through the first passage 11 crosses the second passage 12, the passage of the second passage 12 is performed. It can be blocked. Therefore, a person passing through the first passage 11 can safely cross the second passage 12.

Further, in the present embodiment, a damper 50 that imparts resistance to the operation of the first blocking rod 30 lying down from the first standing position to the first blocking position due to its own weight is further provided. Therefore, the timing at which the lock mechanism 80 unlocks the second blocking rod 70 can be adjusted, and the time for blocking the passage of the second passage 12 by the second blocking rod 70 can be appropriately set. ..

Further, in the present embodiment, the lock mechanism 80 is composed of a pawl portion 81 and a ratchet gear 85, and the transmission member 60 comes into contact with the pawl portion 81 at the first shutoff position of the first shutoff rod 30 to ratchet. It is configured to disengage the claw 82 from the ratchet gear 85. Therefore, it is possible to preferably realize the locking and unlocking of the second blocking rod 70 by the locking mechanism 80.

<Other Embodiments>
The present invention is not limited to the embodiments described in the above description and drawings, and for example, the following embodiments are also included in the technical scope of the present invention.
(1) In the above embodiment, the configuration in which the barriers block the passage of the first passage and the second passage that intersect each other is illustrated, but the present invention is not limited to this. For example, the barrier may be configured to block the passage of the first passage and the second passage parallel to each other. Further, the person passing through the first passage is not limited to a pedestrian, but may be a vehicle. Further, the person passing through the second passage is not limited to a vehicle, but may be a pedestrian, a transported object, or the like.
(2) In the above embodiment, the first shaft and the second shaft are arranged in the relationship of the intersecting axes, but the first shaft and the second shaft may be arranged in the relationship of the staggered axes. In this case, a hypoid gear or the like can be used as a conversion mechanism that converts the rotation direction of the first shaft and transmits it to the second shaft. In addition to the above embodiment, the intersection angle between the first shaft and the second shaft can be appropriately changed according to the intersection angle between the first passage and the second passage.
(3) In addition to the above embodiment, the shape, position, and configuration of each part can be changed as appropriate. For example, the damper is not limited to the rotary damper, and may be composed of an elastic member such as a spring. Further, the lock mechanism is not limited to the fitting of the ratchet claw and the ratchet gear, and various types of lock mechanisms that can be released by the power of the transmission member can be adopted.

10 ... breaker, 11 ... first passage, 12 ... second passage, 30 ... first cutoff rod, 40 ... conversion mechanism, 41 ... first shaft, 44 ... second shaft, 50 ... damper, 60 ... transmission Member, 70 ... 2nd blocking rod, 80 ... Lock mechanism, 81 ... Stopping part, 82 ... Ratchet claw, 85 ... Ratchet gear

Claims (4)

It is made rotatable between the first blocking position that blocks the passage of the first passage and the first standing position that stands up from the first blocking position and allows the passage of the first passage, and by its own weight. A first blocking rod configured to lie down from the first standing position to the first blocking position,
A first shaft that is attached to the first blocking rod and constitutes a rotation axis between the first blocking position and the first standing position.
A second shaft that rotates in conjunction with the rotation of the first shaft,
A transmission member attached to the second shaft and transmitting power from the second shaft,
It is made rotatable between a second blocking position that blocks the passage of the second passage and a second standing position that stands up from the second blocking position and allows the passage of the second passage, and by its own weight. A second blocking rod configured to stand up from the second blocking position to the second standing position,
A lock mechanism capable of locking the second blocking rod at the second blocking position is provided.
The second blocking rod is moved from the second standing position by utilizing the power transmitted from the transmission member as the first blocking rod is changed from the first blocking position to the first standing position. It was changed to the second blocking position,
In a state where the second blocking rod is locked to the second blocking position by the locking mechanism, the first blocking rod is changed from the first standing position to the first blocking position by its own weight.
In the process of changing the first blocking rod to the first blocking position, the lock of the second blocking rod is released by the locking mechanism by utilizing the power transmitted from the transmission member.
A breaker configured such that the second blocking rod unlocked by the locking mechanism is changed from the second blocking position to the second standing position by its own weight. The first aspect of claim 1, wherein the first shaft and the second shaft are arranged in a relationship of an intersecting shaft or a staggered shaft, and further include a conversion mechanism that converts the rotation direction of the first shaft and transmits it to the second shaft. Breaker. The barrier according to claim 1 or 2, further comprising a damper that imparts resistance to the operation in which the first blocking rod is tilted from the first standing position to the first blocking position by its own weight. The lock mechanism is
A pawl with ratchet claws and
When the second blocking rod rotates from the second blocking position to the second standing position, it engages with the ratchet claw, and when the second blocking rod rotates from the second standing position to the second blocking position. It is composed of a ratchet gear that separates from the ratchet claw.
According to claim 1, the transmission member is configured to release the engagement between the ratchet claw and the ratchet gear by contacting the pawl portion at the first blocking position of the first blocking rod. Item 3. The breaker according to any one of items 3.

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