JP2015037920A - Railroad crossing interception bar - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a railroad crossing interception bar capable of being adjusted to various lengths as necessary, while performing light emission.SOLUTION: A cylindrical interception bar body 20 includes: a power generation part 51 that performs power generation by receiving light; an electricity storage part that stores electricity obtained from the power generation part 51; a light emission part that emits light by being supplied with the electricity from at least one of the power generation part 51 and the electricity storage part; and a control part that controls light emission of the light emission part. At least one end of the interception bar body is provided with connection parts 21 and 22 for connecting another interception bar body and fixing it in a serial state.

Description

  The present invention relates to a crossing barrier bar.

In recent years, from the viewpoint of preventing a level crossing accident, there has been proposed a level crossing device that draws attention by attaching a plurality of light emitting elements in parallel on the outer peripheral surface of a level crossing barrier to emit light.
This railroad crossing device is equipped with a box-shaped electric device main body outside the barrier, a panel-shaped solar cell is provided on the surface, and a storage battery and a light emitting element control circuit are provided inside (for example, , See Patent Document 1).
The control circuit includes a detection unit that detects the posture of the barrier rod, and performs control so that the light emitting element is turned off when the barrier rod is open and the light emitting element is turned on when the barrier rod is closed. ing.
The conventional railroad crossing device charges the storage battery with electric power obtained from the solar battery and supplies power to the light emitting element, thereby eliminating the need for power supply from the outside of the railroad crossing device. Further, in order to prevent power shortage, the light emitting element is allowed to emit light only when the barrier rod is closed to save power.

JP 07-228254 A

  By the way, it is necessary to match the length of the railroad crossing bar with the width of the road. However, since the conventional railroad crossing bar is not a structure considering length adjustment, it has been necessary to individually design and manufacture the crossing bar bar according to the width of the road.

  An object of the present invention is to provide a railroad crossing bar that can respond to various lengths as necessary while performing light emission by a light emitting unit.

The present invention
On the cylindrical barrier rod body,
A power generation unit that receives light to generate power;
A power storage unit that stores electricity obtained from the power generation unit;
A light emitting unit that emits light by being supplied with electricity from at least one of the power generation unit and the power storage unit;
A control unit for controlling light emission of the light emitting unit,
At least one end portion of the barrier rod main body is provided with a connecting portion for connecting another barrier rod main body and fixing it in series.

In addition, the crossing crossing bar is
An angle detection unit for detecting an inclination angle of the barrier rod main body,
The said control part is good also as a structure which makes the said light emission part light-emit based on the detection angle of the said shield rod main body by the said angle detection part.

In addition, the crossing crossing bar is
A light detection unit for detecting the light intensity around the barrier rod body;
The said control part is good also as a structure which makes the said light emission part light-emit based on the detection light intensity | strength around the said shield body by the said light detection part.

In addition, the crossing crossing bar is
It is good also as a structure which unitizes the said light emission part, its wiring, and the unit cover which stores the said light emission part.

In addition, the crossing crossing bar is
Equipped with a line of the light emitting unit and the power generation unit arranged in a row on the outer peripheral surface along the longitudinal direction of the barrier rod body, the wiring is covered by a plurality of unit covers,
It is good also as a structure which is not equipped with the said unit cover in the at least one end part side of the said shield rod main body.

Since the railroad crossing bar is provided with a power generation unit and a power storage unit, it is possible to eliminate the need to supply electric power for causing the light emitting unit to emit light from the outside.
In addition, since power supply from the outside is not required, even when connecting the end portions of the barrier bar body, new means such as wiring for supplying power from the outside to each level crossing bar bar are newly provided. Since there is no need, the connecting work itself becomes easy. For this reason, it is possible to provide a crossing barrier that can easily adjust the length according to the width of the road while having the function of emitting light.

It is a perspective view of a level crossing barrier bar which is an embodiment of the invention. FIG. 2A is a front view of a railroad crossing barge in the cut-off state, FIG. 2B is a plan view, and FIG. 2C is a side view. It is sectional drawing which showed the connection state of the edge parts of a blocking rod main body. It is a top view of the light-emitting device which abbreviate | omitted one part structure. It is a circuit diagram of a light-emitting device. It is a block diagram of a control board.

[Outline of Embodiments of the Invention]
A railroad crossing bar 10 which is an embodiment of the invention will be described with reference to FIGS.
The railroad crossing barrier 10 is held by a crossing device (not shown), and is provided with a pivoting operation within a range of approximately 90 ° between a horizontal blocking state and an upright passageable state. It is an instrument for informing the outside.
The railroad crossing bar 10 is mainly composed of a cylindrical barb main body 20 that is turned by a railroad crossing device, and a light emitting device 30 that is mounted on the barb main body 20.

[Blocking body]
The barrier rod main body 20 is a cylindrical member whose main material is a material having flexibility and strength, for example, glass fiber. The outer peripheral surface of the barrier rod main body 20 is colored so that black and yellow are alternately repeated at regular intervals along the longitudinal direction.
FIG. 2A is a front view in a state equipped with a crossing device. As illustrated, a plurality of LEDs (Light Emitting Diodes) 41, 41,... As light emitting portions of the light emitting device 30 are arranged along the longitudinal direction of the barrier rod main body 20 on the front side of the outer peripheral surface of the barrier rod main body 20. Equipped side by side. And each LED41, 41, ... is arrange | positioned so that it may oppose with respect to the pedestrian and driver | operator who wait for a crossing opening in front of the cutoff fence main body 20 of the interruption | blocking state, and is making the pedestrian etc. perform light irradiation .

The outer diameter of the barrier rod main body 20 is substantially constant over the entire length, and as shown in FIG. 3, the end portion (hereinafter referred to as the base end portion 21) side that is supported by the railroad crossing device gradually approaches the tip end. The outer peripheral surface is a gentle conical surface.
Further, the inner diameter of the barrier rod main body 20 is substantially constant over the entire length, and the end opposite to the base end portion 21 (hereinafter referred to as the rotation end portion 22) slightly expands toward the tip. It has a diameter.
The blocking rod main body 20 has a base end portion 21 and a rotating end portion 22 as a connecting portion, and the base end portion 21 of another blocking rod main body 20 is inserted into the rotating end portion 22 or the blocking rod main body. It is possible to insert the base end portion 20 of 20 into the rotation end portion 22 of the other barrier rod main body 20 and connect them in series. And by this connection structure, the breaking rod main bodies are fixed in a state of being arranged in series on the same straight line. In this way, by connecting a plurality of barrier rod main bodies 20 to each other, it is possible to adjust the length to an appropriate length for roads having different widths.
Further, the barrier rod main body 20 is usually provided with a resin cap 23 for preventing rainwater from entering the opening of the rotating end 22 thereof. The cap 23 is detachable, and can be removed when the other barrier rod main body 20 is connected.

Note that the crossing barrier bar 10 can be adjusted to a greater length by preparing a plurality of rail bar main bodies 20 having different lengths and combining them appropriately.
The blocking rod main body 20 may have a shape that gradually decreases in diameter as it goes toward the rotating end 22 over almost the entire length excluding the base end 21. In that case, it is possible to reduce the weight of the rotating end portion, and it is possible to reduce shake during rotation. In this case, when another blocking rod main body 20 is connected to the rotating end portion 22 side of the blocking rod main body 20, the other blocking rod main body 20 may have a base end 21 having a smaller diameter. desirable. Similarly, when the base end 21 of the blocking rod main body 20 is connected to another blocking rod main body 20, the other blocking rod main body 20 uses a rotating end 22 having a larger diameter. It is desirable to do.

[Light emitting device]
As shown in FIGS. 1 and 2, the light emitting device 30 mainly includes three LED units 40, 40, 40, two solar units 50, 50, and a control unit 60.
As shown in FIG. 2, each of the LED units 40 and the solar units 50 has the unit covers 43 and 52 alternately arranged in a line along the longitudinal direction of the blocking rod main body 20. It is mounted on the outer peripheral surface.

[LED unit]
As shown in FIGS. 2, 4, and 5, each of the three LED units 40 includes three LEDs 41, a support substrate 42 as a support frame that holds each LED 41, a long unit cover 43, LED 41 and lead wires 53, 54, and 55, which are wiring for solar panel 51 described later, are mainly provided.

  Each unit cover 43 has a rectangular shape when viewed from the front, and is provided on the outer peripheral surface of the unit cover 43 so as to be parallel to the blocking rod main body 20. Further, the unit cover 43 has a concave cross section perpendicular to the longitudinal direction, and houses the LED 41, the support substrate 42, and the lead wires 53, 54, 55 therein. Further, along the longitudinal direction on the front side of the unit cover 43, three window portions 431, 431, 431 for irradiating light from the internal LEDs 41, 41, 41 to the outside are formed. Each of the windows 431, 431, 431 is equipped with a transparent cover to prevent intrusion of rainwater, moisture, and the like.

  Each unit cover 43 is detachably attached to the outer peripheral surface side of the barrier rod main body 20 at both ends thereof by resin rivets 44 and 44. That is, the resin rivets 44 and 44 are provided with a screw at the center, and the screw can be attached to and detached from the mounting hole provided on the outer peripheral surface of the barrier rod main body 20.

The support substrate 42 is a long substrate that is somewhat shorter than the unit cover 43, and is stored and held inside the unit cover 43.
LEDs 41, 41, 41 are soldered to one side of the support substrate 42 at regular intervals along the longitudinal direction. In a state where the support substrate 42 is disposed in the unit cover 43, the LEDs 41, 41, 41 are disposed so as to face the three window portions 431, 431, 431 of the unit cover 43, respectively.

  In addition, lead wires 53, 54, 55 directed to solar units 50, 50 adjacent to both sides of the LED unit 40 are connected to both ends of the support substrate 42. The support substrate 42 is formed with wirings for connecting the lead wires 53, 54, 55 at both ends and supplying power to the LEDs 41, 41, 41.

Lead wires 53, 54, 55 on one end side of the support substrate 42 extend to the inside of a unit cover 52 (described later) of the solar unit 50 adjacent to the one end side, and a female end is provided on the extended end portion. A waterproof connector 57 on the side is provided. Further, the lead wires 53, 54, 55 on the other end side of the support substrate 42 extend to the inside of the unit cover 52 of the solar unit 50 adjacent to the other end side, A male waterproof connector 56 is provided.
The male and female waterproof connectors 56 and 57 are connected to the female or male waterproof connectors 57 and 56 of another LED unit 40 adjacent to each other with the solar unit 50 interposed therebetween. That is, each lead wire 53, 54, 55 extends into the unit cover 52 of the adjacent solar unit 50, and the other lead wire 53, 54, 55 is connected to the other inside via the female and male waterproof connectors 57, 56 inside the unit cover 52. It is connected to the lead wires 53, 54, and 55 of the LED unit 40.
The lead wires 53, 54, 55 on the other end side of the support substrate 42 of the LED unit 40 closest to the base end portion 21 of the blocking rod body 20 are connected to the female and male waterproof connectors 57, 56. The lead wires 53, 54, 55 connected to the control board 70 of the control unit 60 are connected.

  The lead wire 53 supplies power to each LED 41, the lead wire 54 is a ground wire, and the lead wire 55 transmits power from the solar panel 51 to the control unit 60.

[Solar unit]
As shown in FIGS. 2, 4, and 5, each of the two solar units 50 includes a solar panel 51, 51 as a power generation unit provided along the outer peripheral surface of the barrier rod body 20, and a long length The unit cover 52 is provided.

The solar panels 51, 51 are in the form of a sheet and are provided with solar cells that generate power upon receiving light irradiation. And each solar panel 51 and 51 is equipped in the position used as the upper side and lower side when the interruption | blocking gutter main body 20 will be in the interruption | blocking state mentioned above. The solar panel 51 may be attached by any method that can be fixed, such as adhesion, sticking with an adhesive tape, and fastening with a belt.
In this way, by individually installing the solar panels 51 and 51 on the upper and lower portions of the outer peripheral surface of the barrier rod main body 20, even when the barrier rod main body 20 rotates and faces in any direction, at least Either one of the solar panels 51, 51 can receive power and generate electricity.

The unit cover 52 has a rectangular shape when viewed from the front, and is provided on the outer peripheral surface of the unit cover 52 so as to be parallel to the blocking rod main body 20. Furthermore, the unit cover 52 has a concave cross-sectional shape perpendicular to the longitudinal direction, and lead wires 53, 54, 55 and waterproof connectors 56, 57 extending from the LED units 40, 40 adjacent to both sides are provided inside thereof. Contained. The two solar panels 51, 51 have respective end portions extending to the inside of the unit cover 52 and are connected to one lead wires 54, 55.
The unit cover 52 is also detachably attached to the outer peripheral surface side of the barrier rod main body 20 at both ends by resin rivets 58 and 58.

Furthermore, the unit cover 43 of each LED unit 40 and the unit cover 52 of each solar unit 50 are equipped in a line on the outer peripheral surface of the barrier rod main body 20 in a state where the ends of each unit abut each other. For this reason, the connection member 11 is equipped in the state which suspended between the edge parts of the unit covers 43 and 52 at the butt | matching edge part of each unit cover 43 and 52. FIG.
The connecting member 11 has boss-like projections at both ends, and is inserted into fitting holes (not shown) formed at the butted ends of the unit covers 43 and 52. As a result, the unit covers 43 and 52 are maintained in a connected state in which the end portions are butted together.
The entire LED unit 40 is coated with a physically and chemically stable resin to eliminate the influence of moisture and moisture, and the electrical connection of the lead wires 53, 54, and 55 is maintained.
In addition, a seal member may be interposed between the unit covers 43 and 52 and the outer peripheral surface of the barrier rod main body 20 to achieve watertightness inside the unit covers 43 and 52.

[Controller unit]
As shown in FIGS. 4 and 5, the control unit 60 includes a control board 70 as a control unit that performs light emission control of each LED 41, and a secondary battery 61 as a power storage unit that charges electric power obtained from each solar panel 51. And a waterproof case 64 for storing them.
The waterproof case 64 has a cylindrical shape and is hollow inside. The waterproof case 64 has a halved structure in which case members 62 and 63 are coupled via a waterproof seal member (not shown).
The waterproof case 64 of the control unit 60 is fixedly installed in the vicinity of the base end portion 21 inside the barrier rod main body 20. The waterproof case 64 may be fixed by any method such as screwing, bonding, adhesive tape, and fitting inside the barrier body 20. However, it is more desirable to fix it detachably.

Lead wires 53, 54, and 55 are connected to the control board 70 of the control unit 60. The lead wires 53, 54, and 55 connected to the support board 42 of the closest LED unit 40 and the waterproof connector 56, 57 is connected.
The lead wires 53, 54, 55 extending from the LED unit 40 pass through through holes formed in the outer peripheral surface of the barrier rod main body 20, and lead wires 53, 54, 54 on the control unit 60 side inside the barrier rod main body 20. 55 is connected.

  The secondary battery 61 is composed of, for example, two 1.2 [V] nickel-hydrogen batteries connected in series. However, this is an example, and the voltage can be changed as appropriate. The secondary battery is not limited to a nickel metal hydride battery, and may be a nickel cadmium battery, a lithium ion battery, a lead battery, or the like.

  As shown in FIG. 6, the control board 70 charges the secondary battery 61 with electricity obtained from each solar panel 51, and PWM (for controlling the light quantity of each LED 41 using the secondary battery 61 as a power source. Pulse Width Modulation) drive 72, charging control for the secondary battery 61, microcomputer 73 for performing light emission control for the LED 41, voltage regulator 74 for obtaining power for control using the secondary battery 61 as a power source, and inclination angle of the breaking rod body 20 And an illuminance sensor 76 as a light detection unit for detecting the light intensity around the barrier rod main body 20.

The charge control unit 71 optimizes the current value and voltage value to the secondary battery 61 and receives a control command from the microcomputer 73 to perform control to prevent overcharge and overdischarge.
The PWM drive 72 changes the duty ratio of the energization pulse to the LED 41 to emit light with an appropriate amount of light.
The voltage regulator 74 converts the voltage from the secondary battery 61 into an appropriate control voltage.

The inclination sensor 75 is, for example, a gyro sensor, and detects the inclination angle of the blocking rod main body 20. For example, when the crossing barrier 10 is installed in the crossing device, it is detected at which inclination angle the blocking rod main body 20 is in the state between the horizontal blocking state and the undulating passable state.
The illuminance sensor 76 is composed of, for example, a photodiode, a phototransistor, or the like, and detects the light intensity around the barrier body 20. In addition, the illuminance sensor 76 may be provided on the surface of the waterproof case 64 or the surface of the barrier rod main body 20 in order to detect the light intensity around the barrier rod main body 20 more accurately.
Further, instead of the illuminance sensor 76, the output of the solar panel 51 may be used as illuminance detection as the light intensity.

The microcomputer 73 includes a memory for storing a control program therein, and executes the following control according to the memory.
(1) Control of light emission pattern of LED The LED 41 is continuously lit, blinking, periodically blinking, etc., and the ability to alert the light emission by the LED 41 is improved.
The light emission pattern of the LED 41 may be changed by rewriting a control program in the microcomputer 73. A program for executing a plurality of types of light emission patterns may be prepared in the memory of the microcomputer 73 so that the light emission patterns can be selected by an input means such as a switch connected to the microcomputer 73.

(2) LED light emission control in conjunction with the inclination angle of the barrier rod main body The inclination sensor 75 determines whether the inclination angle of the barrier rod body 20 is within the cutoff angle range, and only when it is within the cutoff angle. The LED 41 is caused to emit light. In other words, each LED 41 is caused to emit light when the shut-off body that needs to be alerted to the surroundings is shut off.
The blocking angle may have an angular range width. For example, an angle range from a state in which the barrier rod main body 20 stands up to a blocked state after a certain angle (for example, 30 °) is allowed to be set as the blocking angle. Thereby, alerting can be performed from the stage before shutting off.
Note that the range of the cutoff angle is recorded in a memory in the microcomputer 73, and may be changed by rewriting data in the memory. Further, a plurality of cutoff angle ranges may be prepared in the memory of the microcomputer 73 so that the cutoff angle range can be selected by input means such as a switch connected to the microcomputer 73.

(3) LED light emission control in conjunction with the brightness of the surrounding area of the shut-off body The illuminance sensor 76 determines whether or not the surrounding area of the shut-off body 20 is less than a certain light intensity, and the light intensity is less than a certain value. Only when the LED 41 emits light. That is, each LED 41 is caused to emit light only when the surroundings are dark and it is difficult to visually recognize the blocking rod main body 20.
The light intensity sets a certain threshold value, and the LED 41 emits light when the ambient light intensity based on the detection of the illuminance sensor 76 is less than the threshold value.
The light intensity threshold value may be stored in a memory in the microcomputer 73 and can be changed by rewriting data in the memory. Alternatively, a plurality of light intensity threshold values may be prepared in the memory of the microcomputer 73 so that the light intensity threshold values can be selected by input means such as a switch connected to the microcomputer 73.

When both the light emission control of (2) and (3) is performed, it is desirable that the LED 41 emit light when both the light emission conditions in (2) and the light emission conditions in (3) are satisfied.
Further, the microcomputer 73 is provided with input means such as a switch so that the execution of each of the light emission control (2) and the light emission control (3) can be selected or the light emission conditions (2) and (3 It is also possible to make a setting such that light is emitted only when both of the light emission conditions (2) are satisfied, or light emission is performed if only one of the light emission conditions (2) and (3) is satisfied.

[Technical effects of the embodiment]
The railroad crossing bar 10 having the above-described configuration is provided with a plurality of LEDs 41 arranged on the front side of the barb main body 20 to emit light, so that it is possible to more effectively alert the railroad crossing.

Moreover, since the railroad crossing barrier 10 includes the solar panel 51 and the secondary battery 61 that is charged by the electric power obtained from the solar panel 51, it is not necessary to supply the electric power for causing each LED 41 to emit light from the outside. Is possible.
For this reason, when attaching the railroad crossing bar 10 to the railroad crossing device, wiring work for supplying power is not required, and handling can be facilitated.

Further, the railroad crossing barrier 10 includes a structure that allows the base end portion 21 of the barrier rod main body 20 to be connected in series with each other by inserting the base end portion 21 into the rotating end portion 22 side of the other barrier rod main body 20. Therefore, the length can be easily adjusted according to the width of the road by connecting the barrier rod main body 20.
In this case, as described above, the railroad crossing bar 10 does not require an external power supply, and therefore wiring connection work for supplying power to each of the crossing barbars 10 that are also connected at the time of connection, etc. Can be made unnecessary, and the connection work can be made easier.
Furthermore, by preparing a plurality of barrier rod main bodies 20 having different lengths, the length can be adjusted more finely.

The railroad crossing barrier 10 is equipped with a sheet-like solar panel 51 along the outer peripheral surface of the barrier main body 20.
The lead wires 53, 54 and 55 and the waterproof connectors 56 and 57 are stored in the rectangular unit covers 43 and 52, and the components of the LED unit 40 are stored in the rectangular unit cover 43 and each unit. The covers 43 and 52 are arranged in a line along the longitudinal direction on the outer peripheral surface of the barrier rod main body 20.
Further, the control board 70 and the secondary battery 61 are stored in a waterproof case 64, and the waterproof case 64 is provided inside the barrier rod main body 20.
As a result, each component of the light emitting device 30 is equipped so as not to be uneven as much as possible with respect to the outer shape of the barrier rod main body 20, so that the barrier rod main body 20 can maintain a substantially rod-like shape. It is possible to provide a level crossing bar with less change in appearance compared to a level crossing bar.
In addition, since the rod-like shape is maintained, even when a turning operation by the railroad crossing device is applied, a moment centering on the barrier rod main body 20 is less likely to be generated, and it is possible to suppress the occurrence of accidental vibration. Become. In particular, even when a plurality of barrier rod main bodies are connected, the influence of the vibration can be suppressed.

  Further, the railroad crossing bar 10 includes the inclination sensor 75, and the microcomputer 73 controls the LEDs 41 to emit light when the barb main body 20 is at the cut-off angle. It is possible to suppress light emission at the power source and realize power saving.

  The railroad crossing barrier 10 includes an illuminance sensor 76, and the microcomputer 73 controls the LEDs 41 to emit light when the periphery of the barrier rod main body 20 is below a certain light intensity. It is possible to save power by suppressing light emission in a bright time zone such as a low daytime.

  Further, the railroad crossing barrier 10 controls the microcomputer 73 so that each LED 41 emits light in various light emission patterns, so that it is possible to more effectively alert the railroad crossing.

  Further, the LED unit 40 is unitized by integrating the LED 41, the support substrate 42, the unit cover 43, the lead wires 53, 54, 55, and the waterproof connectors 56, 57. Accordingly, changes such as addition or reduction of the LED unit 40 can be easily performed, and manufacturing can be facilitated.

  In addition, the unit cover 43 of the LED unit 40 and the unit cover 52 of the solar unit 50 are arranged in a line on the outer peripheral surface along the longitudinal direction of the blocking rod main body 20, and the base end portion of the blocking rod main body 20 Since no unit covers 43 and 52 are provided on the side, the unit covers 43 and 52 do not hinder the connection between the crossing barriers 10 and can be easily connected.

[Others]
The railroad crossing bar 10 shown in the present embodiment is not limited to the above configuration.
For example, the railroad crossing bar 10 has been illustrated as being connectable to another railroad crossing bar 10 by the barb main body 20, but the present invention is not limited to this. You may connect with the other level crossing interruption | blocking fences which do not have (crossing interruption | blocking fence consisting only of the interruption | blocking fence main body 20).

Moreover, the structure of the connection part of the barrier rod main body 20 should just be detachable, and is not restricted to what is shown in FIG. For example, the structure of the connecting portion between the base end portion 21 and the rotating end portion 22 may be reversed. That is, it is good also as a shape where the internal diameter of the base end part 21 expands and the outer diameter of the rotation end part 22 reduces in diameter.
Further, a stepped portion may be provided on the base end portion 21 or the rotating end portion 22 of the blocking rod main body 20 so as to have a small diameter, so that it can be inserted into the other end side. Alternatively, a step portion may be provided on the base end portion 21 or the rotating end portion 22 of the blocking rod main body 20 to increase the diameter, and the other end portion may be inserted therein.
Alternatively, a male screw portion may be formed on one side of the blocking rod main body, and a female screw portion may be formed on the other side of the blocking rod main body so that one of them is screwed into the other to be connected.
Moreover, in the example of FIG. 3, although the both ends of the barrier rod main body 20 become a connection part which can be connected with another barrier rod main body, it is not limited to this. For example, only one of the base end portion 21 and the rotating end portion 22 of the barrier rod main body 20 can be connected to another barrier rod main body by providing a connecting portion by reducing the outer diameter or increasing the inner diameter. It is also good.

  The number of solar panels 51 and the shape thereof are arbitrary. Further, the solar panel 51 may be disposed on any of the crossing barriers 10 as long as it can receive light from the outside.

Moreover, the number of LED41 and the number of LED unit 40 and the solar unit 50 are illustrations, and can be increased / decreased suitably.
Further, the arrangement of each component of the LED unit 40 can be changed. For example, the LED unit 40 may be disposed inside the barrier rod main body 20. In that case, since the lead wires 53, 54, 55 are provided on the inner side, the unit covers 43, 52 can be dispensed with. In that case, it is desirable to form a window for irradiating the LED 41 on the outer peripheral surface of the barrier rod main body 20. In addition, it is desirable to provide a through hole for wiring in the shield rod main body 20 in order to connect the outer solar panel 51 and the lead wires 54 and 55.
And the window part of LED41 and the through-hole for wiring may be equipped with a sealing member, or you may cover the whole outer peripheral surface of the barrier rod main body 20 with a transparent sheet, and may waterproof.

  Moreover, although the control unit 60 is provided inside the barrier rod main body 20, the configuration may be stored in a unit cover like the LED unit 40 and disposed on the outer peripheral surface of the barrier rod main body 20. In that case, it is desirable to provide the unit cover with a watertight structure.

  Moreover, although the case where each LED41 emitted light according to the light emission pattern similarly was illustrated, it is not restricted to this. For example, the control board 70 performs various light emission controls such as increasing the number of control leads, causing each LED 41 or LED unit 40 to emit light with a different light emission pattern, or causing each LED 41 to emit light in order. May be.

  Each LED 41 is supplied with power from the secondary battery 61, but may be configured to receive power from either the secondary battery 61 or each solar panel 51.

Moreover, in the railroad crossing bar 10, the charging control unit 71 is provided on the control board 70 and charging control is performed to charge the secondary battery 61 from the solar panel 51. For example, without the charging control unit, Power storage from the solar panel 51 to the secondary battery 61 may be performed.
Moreover, although the control board 70 as a control part is set as the structure which performs the light emission control with respect to LED41, and the charge control with respect to the secondary battery 61, it is not limited to this.
For example, the control board 70 as a control unit may be provided with a control board as a charge control unit that exclusively performs light emission control on the LED 41 and exclusively performs charge control on the secondary battery 61 separately from the control board.

10 Crossing barrier 竿 20 竿 Main body 21 Base end (connecting part)
22 Rotating end (connecting part)
30 Light Emitting Device 40 LED Unit 41 LED (Light Emitting Unit)
42 Support Substrate 43 Unit Cover 50 Solar Unit 51 Solar Panel (Power Generation Unit)
52 Unit cover 53, 54, 55 Lead wire (wiring)
56, 57 Waterproof connector 60 Control unit 61 Secondary battery (power storage unit)
64 Waterproof case 70 Control board (control unit)
73 Microcomputer 75 Tilt sensor (angle detector)
76 Illuminance sensor (light detector)

Claims (5)

On the cylindrical barrier rod body,
A power generation unit that receives light to generate power;
A power storage unit that stores electricity obtained from the power generation unit;
A light emitting unit that emits light by being supplied with electricity from at least one of the power generation unit and the power storage unit;
A control unit for controlling light emission of the light emitting unit,
A crossing barrier bar having at least one end portion of the barrier bar main body provided with a connecting part for connecting another barrier bar main body and fixing it in series. An angle detection unit for detecting an inclination angle of the barrier rod main body,
The railroad crossing barge according to claim 1, wherein the control unit causes the light emitting unit to emit light based on a detected angle of the barb main body by the angle detection unit. A light detection unit for detecting the light intensity around the barrier rod body;
The railroad crossing barge according to claim 1 or 2, wherein the control unit causes the light emitting unit to emit light based on a light intensity detected around the barb main body by the light detection unit.   The railroad crossing barrier according to any one of claims 1 to 3, wherein the light emitting unit, its wiring, and a unit cover for storing the light emitting unit are unitized. Equipped with a line of the light emitting unit and the power generation unit arranged in a row on the outer peripheral surface along the longitudinal direction of the barrier rod body, the wiring is covered by a plurality of unit covers,
The crossing barrier bar according to any one of claims 1 to 3, wherein the unit cover is not provided on at least one end side of the barrier bar main body.

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