JP6001016B2 - Gaze guidance device - Google Patents

Description

  The present invention relates to a line-of-sight guidance device.

  When performing construction on the road on which the vehicle travels, it is necessary to guide the vehicle so that it does not enter the construction site in order to ensure the safety of the worker performing the construction and the safety of the traveling vehicle. There is. As a means for guiding the vehicle in this way, a line-of-sight guidance device including a plurality of light emitting devices is known.

  For example, the interlocking arrow plate device described in Patent Document 1 includes a hand controller that simultaneously sends a control signal in a non-contact manner to a plurality of arrow plates including an arrow-shaped light emitting unit that is a light emitting device, A plurality of blinking patterns when the arrow plate is lit are set in advance. In this interlocking arrow board device, the hand operator transmits a control signal to the arrow board by performing a blinking pattern selection operation with the hand operator. The arrow board that has received this control signal blinks in the selected blinking pattern, so that a plurality of arrow boards can blink in any blinking pattern. Can be guided by flashing.

Utility Model Registration No. 3165448

  However, as in Patent Document 1, in the configuration in which the blinking pattern of the arrow plate is switched using the hand controller, when using the arrow plate, a hand controller other than the arrow plate must be prepared. A control signal needs to be transmitted. For this reason, management of the hand controller is also important, and if the hand controller is lost, there is a possibility that it is impossible to switch the blinking pattern of the arrow plate.

  The present invention has been made in view of the above, and an object of the present invention is to provide a line-of-sight guidance device capable of controlling blinking without using a dedicated device for operation.

  In order to solve the above-described problems and achieve the object, a line-of-sight guidance device according to the present invention includes a light emitting unit that emits light, a control unit that performs blinking control of the light emitting unit, and a control signal from the control unit. A plurality of light-emitting devices each having a communication unit that transmits and receives wirelessly, and the control unit of each of the light-emitting devices transmits the control signal via wireless communication between the communication units of the respective light-emitting devices. It is possible to transmit and receive, and it is possible to set its own light emitting device as a parent device or a child device, and the control unit of the parent device controls blinking of the light emitting unit The control signal of the set flashing control is transmitted to the control unit of the slave unit via wireless communication between the communication units, and the control unit of the slave unit is From the control unit of the base unit The control signal of the flashing control received is transmitted to the control unit of the other slave unit via wireless communication between the communication units, and the control unit of each of the light emitting devices The light emitting unit is caused to blink on the basis of a blink control signal set by the control unit of the master unit.

  Further, in the line-of-sight guidance device, each of the control units performs a blinking control of the light emitting unit based on a control signal of the light emitting unit blinking control set by the control unit of the base unit. The light-emitting unit can be sequentially blinked between the light-emitting devices, and the control unit of the base unit can set the timing when the light-emitting unit is sequentially blinked between the plurality of light-emitting devices. It is preferable that

  In the line-of-sight guidance device, it is preferable that the control unit sets the light emitting device as the parent device or the child device by setting an address of the light emitting device.

  Moreover, in the said visual line guidance apparatus, it is preferable that the said communication part can change the frequency at the time of performing wireless communication.

  In the line-of-sight guidance device, the communication unit includes an antenna that transmits and receives radio waves used for wireless communication, and the antenna can be positioned above the light-emitting device when the light-emitting device is installed. Preferably there is.

  The line-of-sight guidance device according to the present invention has an effect that blinking control can be performed without using a dedicated device for operation.

FIG. 1 is a front view of an arrow plate provided in the line-of-sight guidance device according to the first embodiment. FIG. 2 is an AA arrow view of FIG. 3 is a BB arrow view of FIG. FIG. 4 is a perspective view of the control unit shown in FIG. FIG. 5 is a perspective view of the control unit shown in FIG. FIG. 6 is a perspective view of the control unit shown in FIG. 4 as viewed from the side opposite to the transparent cover side. FIG. 7 is a functional block diagram of the arrow plate shown in FIG. FIG. 8 is a perspective view of the installation state of the arrow plate shown in FIG. FIG. 9 is a perspective view of the arrow plate shown in FIG. 8 as viewed from the leg side. FIG. 10 is an explanatory diagram in the case of installation so that the arrow points to the left. FIG. 11 is an explanatory view showing a state in which a plurality of arrow plates shown in FIG. 8 are installed. FIG. 12 is an explanatory diagram illustrating a state in which an arrow plate included in the line-of-sight guidance device according to the second embodiment is viewed from the surface on the control unit side. FIG. 13 is a perspective view of the control unit shown in FIG. FIG. 14 is a perspective view of the control unit shown in FIG. FIG. 15 is a perspective view of the control unit shown in FIG. 13 as viewed from the side opposite to the transparent cover side. FIG. 16 is a perspective view of the power supply unit shown in FIG. FIG. 17 is a perspective view of the installation state of the arrow plate shown in FIG.

  Hereinafter, embodiments of a line-of-sight guidance device according to the present invention will be described in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same.

Embodiment 1
FIG. 1 is a front view of an arrow plate provided in the line-of-sight guidance device according to the first embodiment. FIG. 2 is an AA arrow view of FIG. The arrow board 10 shown in FIGS. 1 and 2 is configured as a light-emitting device in the line-of-sight guidance apparatus 1 (see FIG. 11) according to Embodiment 1, and the line-of-sight guidance apparatus 1 has a plurality of arrow boards 10. ing. The arrow plate 10 has a substantially rectangular plate-like panel 11, and the panel 11 is attached to a frame portion 12 that is a frame-like member formed in substantially the same shape as the outer peripheral shape of the panel 11. Yes.

  A display unit 15 for displaying desired information is formed on one surface of the panel 11 attached to the frame unit 12 by being formed in an arbitrary shape by a member having a color different from the color of the panel 11. . The display unit 15 is formed in, for example, an arrow-like shape that faces in one direction in the longitudinal direction of the rectangle that is the shape of the panel 11. It is possible to inform the user of the direction of the arrow, which is the shape.

  The arrow plate 10 thus formed is provided with a plurality of light emitting portions 16 that emit light. The light emitting unit 16 includes, for example, an LED (Light Emitting Diode), and a plurality of the light emitting units 16 are arranged on the display unit 15 along the shape of the display unit 15. For this reason, at the time of lighting of the plurality of light emitting units 16, a plurality of these light emitting units 16 can be turned on in a shape along the shape of the display unit 15.

  3 is a BB arrow view of FIG. The arrow plate 10 is provided with a leg portion 20 on the surface of the panel 11 opposite to the surface on which the display portion 15 is formed. The leg portion 20 has a leg body portion 21, which is a member formed in a substantially U-shape, and is attached to the frame portion 12 so as to be rotatable about a rotation portion 22. Specifically, the leg main body 21 has a width on the open side in the U-shape that is approximately the same as the width in the short direction of the panel 11 or the frame part 12. Both ends on the opening side of 21 are attached to the frame portion 12 by the rotating portion 22. The rotating part 22 connects the leg part main body part 21 to the frame part 12 so as to be rotatable with respect to the frame part 12 around a turning axis oriented along the short direction of the panel 11 or the like. .

  The rotating portion 22 is disposed at a position near one end in the longitudinal direction of the frame portion 12, and the leg main body portion 21 connected to the frame portion 12 by the rotating portion 22 extends along the frame portion 12. In the state, the closed side of the U-shape is formed in a shape that is located near the other end in the longitudinal direction of the frame portion 12.

  The leg main body 21 is provided with a grounding member 23 extending in the opposite direction of the U-shaped closing side from the position of the rotating unit 22 in the vicinity of the U-shaped opening side. That is, in the state where the leg main body portion 21 is along the frame portion 12, the grounding member 23 has a short side closer to the rotating portion 22 on the two short sides of the frame portion 12 from the leg main body portion 21. It is formed toward the direction. The grounding member 23 is provided on both ends of the leg body 21 on the opening side, and the width of the grounding members 23 is larger than the length of the frame 12 in the short direction. A grounding portion 24 is disposed at the tip of the grounding portion member 23 provided in this way. The grounding portion 24 is made of a material having elasticity such as a rubber member, and is provided in each of the two grounding portion members 23 so as to protrude outward in the short direction of the frame portion 12.

  Further, the arrow plate 10 has a control unit 30 for performing an input operation when setting the flashing mode of the light emitting unit 16, and the frame 12 is provided with a unit mounting portion 26 for attaching the control unit 30. It has been. The unit mounting portion 26 is disposed at a position near the end portion on the opposite side of the end portion of the leg portion 20 in the longitudinal direction of the frame portion 12. The control unit 30 is detachably mounted on both long sides.

  Further, the control unit 30 is connected to the wiring on the light emitting unit 16 side by a cord 58 through which a current or an electric signal can flow. The cord 58 is located on the surface of the panel 11 opposite to the surface on which the display unit 15 is formed, and is disposed on a surface different from the light emitting unit 16. 58 is connected through the panel 11. For this reason, the connection portion between the wiring on the light emitting portion 16 side and the cord 58 is covered with the connection portion cap 57 disposed on the surface of the panel 11 opposite to the surface on which the display portion 15 is formed. .

  FIG. 4 is a perspective view of the control unit shown in FIG. FIG. 5 is a perspective view of the control unit shown in FIG. The control unit 30 has a substantially rectangular parallelepiped casing 31, and a part of the casing 31 is a transparent cover 32 made of a light transmitting member. The control unit 30 can be attached to the unit attachment portion 26 by attaching the surface side of the casing 31 opposite to the surface where the transparent cover 32 is located to the unit attachment portion 26. In the housing 31, a control unit 60 (see FIG. 7) that performs electrical control of each part of the arrow plate 10 and a communication unit 35 that wirelessly transmits and receives control signals from the control unit 60 are disposed. Further, a power supply unit 40 that supplies power to the light emitting unit 16, the control unit 60, and the communication unit 35 is disposed in the housing 31.

  Among these, the communication unit 35 includes an antenna 36 that transmits and receives radio waves used for wireless communication, and the antenna 36 is disposed in the housing 31. The housing 31 is made of a member such as resin, and radio waves transmitted and received by the antenna 36 can pass through the housing 31. For this reason, the communication unit 35 can transmit and receive radio waves passing through the housing 31 by the antenna 36.

  The power supply unit 40 includes a solar battery 41 that converts light energy into electric power, and a secondary battery 42 that stores electric power converted by the solar battery 41. The solar battery 41 is disposed in the housing 31 at a position facing the transparent cover 32 from the inside of the housing 31. That is, the solar battery 41 is disposed at a position where it can receive the light that has passed through the transparent cover 32 from the outside of the control unit 30 and entered the housing 31, and can generate electric power using the received light. It has become. Further, the secondary battery 42 is electrically connected to the solar battery 41 and disposed in the housing 31.

  FIG. 6 is a perspective view of the control unit shown in FIG. 4 as viewed from the side opposite to the transparent cover side. The control unit 30 is provided with an operation unit 50 on the surface opposite to the side where the transparent cover 32 is provided. The operation unit 50 includes a switch 51 that performs an input operation, and an information display unit 55 that displays predetermined information when the control unit 30 is operated. Among these, the switch 51 has a power switch 52 for switching on / off of the power source, and an A button 53 and a B button 54 each assigned a predetermined function. Further, the information display unit 55 can display arbitrary information by using an LED, a liquid crystal panel, or the like.

  The control unit 30 is attached to the unit attachment portion 26 by the attachment member 33 in a state where the surface on which the operation portion 50 is provided faces the unit attachment portion 26 and is in contact with the unit attachment portion 26. At that time, the control unit 30 is attached to the unit attachment part 26 in a positional relationship where the operation part 50 is not covered by the unit attachment part 26. The attachment member 33 can be attached to the unit attachment portion 26 by being screwed to the control unit 30 with the unit attachment portion 26 sandwiched between the attachment member 33 and the control unit 30. Yes.

  As described above, the unit attachment portion 26 to which the control unit 30 can be attached is rotatably connected to the frame portion 12. Specifically, the unit mounting portion 26 is connected to the frame portion 12 so as to be rotatable about a rotation shaft extending in the longitudinal direction of the frame portion 12. As a result, when the control unit 30 is mounted, the unit mounting portion 26 is configured so that the control unit 30 is positioned on the surface side of the panel 11 on which the connection portion cap 57 is disposed. It is possible to rotate over the state of being located on the outer peripheral surface side.

  That is, for example, when the arrow plate 10 is installed in a direction in which the short direction of the frame portion 12 is in the vertical direction, when the control unit 30 is attached to the unit attachment portion 26 located on the upper side, the unit attachment portion 26 is The panel 11 is rotatable from a state positioned on the opposite side of the display unit 15 to a state positioned on the upper side of the frame unit 12.

  The orientation of the control unit 30 in this case is such that, when the panel 11 is located on the opposite side of the display unit 15, the surface on which the transparent cover 32 is located faces the panel 11, and the operation unit 50 is positioned on the panel 11. It is attached to the unit attachment part 26 in the direction facing the opposite side. That is, the control unit 30 is attached to the unit attachment portion 26 in such a direction that the operation portion 50 is located on the surface when the control unit 30 is located on the opposite side of the display portion 15 in the panel 11.

  The unit mounting portion 26 is rotated about 270 ° about the rotation axis of the unit mounting portion 26 from a state where the unit mounting portion 26 is located on the opposite side of the display portion 15 in the panel 11. It will be in the state located above the part 12. FIG. The orientation of the control unit 30 in this state is such that the operation unit 50 is positioned downward and facing downward, and the transparent cover 32 is positioned upward and facing upward.

  Since the control unit 30 can be positioned above the frame portion 12 in this way, the communication unit 35 is thus positioned above the arrow plate 10 when the arrow plate 10 is installed. It is possible to make it. At this time, since the control unit 30 can be disposed with the transparent cover 32 facing upward, the power source 40 emits light that is irradiated from above the arrow plate 10 and passes through the transparent cover 32 to the solar battery 41. It is possible to arrange in a state where it can be received.

  FIG. 7 is a functional block diagram of the arrow plate shown in FIG. The control unit 60 provided in the control unit 30 can control the blinking of the light emitting unit 16, and includes a processing unit having a CPU (Central Processing Unit), a RAM (Random Access Memory), and the like. It is comprised as an electronic control apparatus provided with a memory | storage part. The arrow plate 10 constituting the line-of-sight guidance device 1 is operated by the control unit 60, the light emitting unit 16, the operation unit 50, the communication unit 35, and the like by the power generated by the solar battery 41. The electric power of the part can be stored in the secondary battery 42. The control unit 60 is electrically connected to the light emitting unit 16, the operation unit 50, and the communication unit 35, and can control the blinking of the light emitting unit 16 based on various setting information input by the operation unit 50. It has become.

  The communication unit 35 includes an antenna 36 that transmits and receives radio waves, and a communication control unit 37 that performs control when transmitting and receiving signals using radio waves. For example, a frequency in the 2.4 GHz band Signals can be transmitted and received by using the radio waves. The plurality of arrow plates 10 constituting the line-of-sight guidance device 1 perform wireless communication between the arrow plates 10 by the communication unit 35 provided in each of them, so that signals such as a control signal when performing the blinking control of the light emitting unit 16 are transmitted. Transmission and reception can be performed between the control units 60. That is, the control part 60 of each arrow board 10 can transmit / receive a control signal via the radio | wireless communication between the communication parts 35 which each arrow board 10 has.

  In addition, the communication unit 35 can change the frequency when wireless communication is performed between the communication units 35 of the plurality of arrow plates 10, and the frequency is changed by an input operation on the operation unit 50. be able to. The line-of-sight guidance device 1 includes a plurality of arrow plates 10 configured as described above, and is configured to be able to perform wireless communication between the arrow plates 10.

  The line-of-sight guidance device 1 according to the first embodiment has the above-described configuration, and the operation thereof will be described below. When the line-of-sight guidance device 1 is used, a plurality of arrow plates 10 are installed and used at arbitrary locations. FIG. 8 is a perspective view of the installation state of the arrow plate shown in FIG. FIG. 9 is a perspective view of the arrow plate shown in FIG. 8 as viewed from the leg side. When the arrow plate 10 is installed, the leg part 20 is turned around the turning part 22 in a direction away from the panel 11, whereby the leg part 20 is pulled out and raised. As a result, the leg 20 is in a state in which the closed side of the U-shape which is the shape of the leg main body 21 is separated from the panel 11. Further, in this state, the grounding portion member 23 of the leg portion 20 is in a state in which the end portion on the side where the grounding portion 24 is disposed protrudes in the direction in which the display portion 15 in the panel 11 faces.

  In this state, the arrow plate 10 is arranged at an arbitrary position in such a direction that one end side in the short direction of the frame portion 12 is directed downward. As a result, the arrow plate 10 has a grounding portion 24 on the lower surface side among the grounding portion 24 of the leg portion 20, the U-shaped closing end portion of the leg main body portion 21, and the frame portion 12. Arranged. At that time, the control unit 30 is attached to the unit attachment portion 26 located on the upper side of the two unit attachment portions 26 when the arrow plate 10 is arranged, and the unit attachment portion 26 to which the control unit 30 is attached is Turn to the side. As a result, the control unit 30 is positioned above the frame portion 12. The arrow plate 10 is installed in such a state that the control unit 30 is positioned on the upper end side of the panel 11 as described above.

  In addition, in FIG. 8, when the arrow board 10 is seen from the surface side in which the display part 15 is provided, about the form in the case of installing the arrow board 10 so that the arrow which is the shape of the display part 15 turns rightward. Although described, the arrow plate 10 may be installed so that the arrow points to the left. FIG. 10 is an explanatory diagram in the case of installation so that the arrow points to the left. When the arrow plate 10 is installed so that the arrow that is the shape of the display unit 15 is directed to the left, the control unit 30 is configured so that the arrow of the two unit mounting portions 26 is directed to the left. When 10 is installed, it is attached to the unit attaching part 26 located on the upper side. In this state, the unit attachment portion 26 to which the control unit 30 is attached is rotated upward to position the control unit 30 above the frame portion 12. Thereby, even when the arrow board 10 is installed so that the arrow which is the shape of the display unit 15 is directed leftward, the control unit 30 can be installed at the upper end side of the panel 11.

  FIG. 11 is an explanatory view showing a state in which a plurality of arrow plates shown in FIG. 8 are installed. The line-of-sight guidance device 1 stands up the leg portions 20 of the plurality of arrow plates 10 of the line-of-sight guidance device 1 as described above, and further positions the control unit 30 on the upper end side when the arrow plate 10 is disposed. In the state, each arrow board 10 is arrange | positioned in arbitrary positions. Accordingly, since the transparent cover 32 is directed upward in the control unit 30, sunlight irradiated to the control unit 30 passes through the transparent cover 32 and is installed in the control unit 30 during the daytime. The solar battery 41 is irradiated. The solar battery 41 generates power using this sunlight, and the power generated by the solar battery 41 is stored in the secondary battery 42.

  In a situation where it is dark and it is difficult to visually recognize the surrounding state, such as at night, each electrical component constituting the arrow plate 10 is operated by the power stored in the secondary battery 42. When the line-of-sight guidance device 1 is used, the arrow board 10 generates power by light applied to the arrow board 10 during the day, stores the generated power, and emits light from the display unit 15 by the stored power when the surroundings become dark. By flashing the part 16, the light is flashed in the shape of an arrow.

  Moreover, each arrow board 10 blinks the light emission part 16 of the display part 15, synchronizing with the arrow boards 10 by radio | wireless communication. Thereby, when it sees in the some arrow board 10 whole, blinking is synchronized, or the arrow board 10 currently located in a line is blinked in order, and it is made to light as if the arrow-shaped light is moving. These blinking states are set by setting each arrow plate 10 as the parent device 65 or the child device 66, and setting the blinking state of the light emitting unit 16 by the parent device 65, whereby the light emitting units 16 of all the arrow plates 10 are set. Are flashed in the desired flashing state.

  In other words, each arrow plate 10 can set itself as the parent device 65 or the child device 66, and the parent device 65 and the light emitting unit 16 of each child device 66 are controlled to be blinking set by the parent device 65. Flashes based on the control signal. In order to realize these, the control unit 60 of each arrow plate 10 can set its own arrow plate 10 as the parent device 65 or the child device 66. Specifically, the arrow board 10 can set an address to be used when wireless communication is performed, and the control unit 60 sets the address of the own arrow board 10 so as to set its own arrow. It is possible to set the board 10 as the master unit 65 or the slave unit 66. That is, as for the plurality of arrow plates 10 constituting the line-of-sight guidance device 1 according to the first embodiment, any one of the arrow plates 10 can be set as the parent device 65, and the parent device 65 can be set. Other arrow plates 10 can be set as the slave units 66.

  Among the arrow plates 10 set as described above, the control unit 60 of the base unit 65 sets the control signal for the flashing control of the light emitting unit 16, and the control signal for the flashing control thus set is controlled by the slave unit 66. It is possible to transmit to the unit 60 via wireless communication between the communication units 35.

  On the other hand, the control unit 60 of the slave unit 66 transmits the control signal of the blink control transmitted from the control unit 60 of the master unit 65 to the control units 60 of the other slave units 66 by the communication units 35. Can be sent through. That is, the slave unit 66 that has received the control signal by wireless communication transmits a control signal to the adjacent slave unit 66 and repeats this to transmit the plurality of arrow boards 10 from the master unit 65. The control signal thus received can be received by all the arrow boards 10.

  As described above, the control unit 60 of the base unit 65 and the control unit 60 of each arrow board 10 that directly or indirectly receives the control signal transmitted from the base unit 65 are the control unit 60 of the base unit 65. The light emitting unit 16 can be blinked based on the control signal of the blinking control set in. Thereby, the light emission parts 16 of all the arrow boards 10 can be blinked in a desired blinking state, that is, the plurality of arrow boards 10 can be blinked in association with the blinking of the light emission parts 16.

  As a blinking state when the light emitting units 16 of the plurality of arrow plates 10 are blinked, for example, the light emitting units 16 of the arrow plates 10 arranged in a plurality can be sequentially blinked in the order in which they are arranged. That is, each control unit 60 performs the blinking control of the light emitting unit 16 based on the control signal for the blinking control of the light emitting unit 16 set by the control unit 60 of the parent device 65, so that the plurality of arrow plates 10 are connected. The light emitting unit 16 can be sequentially blinked. As described above, when the arrow plates 10 are sequentially blinked, the control unit 60 of the parent device 65 can set the timing for sequentially blinking the light emitting units 16 between the plurality of arrow plates 10.

  These blinking control settings and the settings of the master unit 65 and the slave unit 66 are set by performing an input operation on the operation unit 50 of the control unit 30 included in each arrow plate 10. Specifically, it is performed by operating the A button 53 and the B button 54 while visually confirming the display contents on the information display unit 55.

  Among these, the A button 53 can select a setting mode when setting with the operation unit 50, and the address setting mode for setting the address of its own arrow board 10 and the light emitting unit 16 can be selected. It is possible to select between a flashing mode setting mode for flashing and a channel setting mode for wireless communication using the arrow board 10.

  The B button 54 can set a setting value in the setting mode selected by the A button 53. For example, in the address setting mode, the address can be switched every time the B button 54 is pressed. That is, in the line-of-sight guidance device 1 according to the first embodiment, “No1” to “No10” can be selected as addresses, and the information display unit 55 is displayed each time the B button 54 is pressed. By changing in order from “No1” to “No10” and pressing the A button 53, the address can be determined. That is, when the A button 53 is pressed, the address displayed on the information display section 55 becomes the address of the arrow board 10. The addresses that can be selected in this way are stored in advance in the storage unit of the control unit 60, and one of the stored addresses is selected in the address setting mode.

  Note that, in this address, “No 1” is an address as the parent device 65, and “No 2” to “No 10” are addresses as the child device 66. For this reason, the address setting mode is also a mode for setting the master unit 65 among the plurality of arrow plates 10.

  In the flashing mode setting mode, the flashing mode can be switched every time the B button 54 is pressed. That is, in the line-of-sight guidance apparatus 1 according to the first embodiment, “F0” is set as the mode for causing the plurality of arrow plates 10 to blink simultaneously as the blinking mode. “F1” to “F9” are set, and each time the B button 54 is pressed, these can be switched. Note that “F1” to “F9”, which are modes for blinking and blinking, have different times for blinking to switch between adjacent arrow plates 10, that is, blinking flows between a plurality of arrow plates 10. The speed is different.

  In the flashing mode setting mode, each time the B button 54 is pressed, the display of the information display section 55 changes in order from “F0” to “F9”, and the flashing mode can be determined by pressing the A button 53. it can. That is, when the A button 53 is pressed, the flashing mode displayed on the information display unit 55 becomes the flashing mode that is actually used. The flashing modes that can be selected in this way are stored in advance in the storage unit of the control unit 60, and one of the stored flashing modes is selected as the flashing mode setting mode.

  Further, in the channel setting mode, every time the B button 54 is pressed, the channel used for wireless communication with the arrow board 10 can be switched. That is, in the line-of-sight guidance device 1 according to the first embodiment, “C0” to “C9” are set as channels during wireless communication, and these can be switched each time the B button 54 is pressed. In the channel setting mode, every time the B button 54 is pressed, the display of the information display section 55 changes in order from “C0” to “C9”, and the channel can be determined by pressing the A button 53. That is, when the A button 53 is pressed, the channel displayed on the information display unit 55 becomes the channel that is actually used. The channels that can be selected in this way are stored in advance in the storage unit of the control unit 60, and one of the stored channels is selected in the channel setting mode.

  Next, a procedure for actually installing the line-of-sight guidance device 1 having these functions will be described. In the following description, the number of installed arrow plates 10 is 10 and the blinking mode of the light emitting unit 16 is a case where the arrow plates 10 are blinked simultaneously.

  When the line-of-sight guidance device 1 is used, the address is set by turning on the power before the arrow plate 10 is installed. That is, the address setting is performed by the control unit 30 on each of the ten arrow plates 10, and the addresses are assigned from "No1" to "No10". Thus, among the ten arrow plates 10, the “No 1” arrow plate 10 used as the parent device 65 and the “No 2” to “No 10” arrow plates 10 used as the child device 66 are determined.

  In addition, when the address setting is performed as described above, it is preferable that the information display unit 55 display so that the parent device 65 can be recognized. For example, the information display unit 55 is provided with an LED for recognizing the base unit 65, and only the information display unit 55 of the control unit 30 included in the arrow board 10 set as the base unit 65 by address setting is lit. It is preferable that the user can recognize the parent device 65 at a glance. Further, when the address setting has already been completed at the start of use of the line-of-sight guidance device 1, it is not necessary to set the address again.

  When the address setting is completed, the arrow plates 10 are set at desired positions in order from “No1” to “No10”. In that case, the space | interval of the arrow boards 10 is made into the space | interval in the range which can communicate by the communication part 35 provided in the control unit 30. FIG.

  Next, a flashing mode is set on the parent device 65 which is the arrow plate 10 whose address is “No1”, and the flashing mode of the parent device 65 is set to “F0” which is a mode in which the light emitting unit 16 blinks simultaneously between the arrow plates 10. To. When the flashing mode is fixed to “F0” by the master unit 65, the master unit 65 sends a control signal to the slave unit 66 by the communication unit 35 to set the flashing mode to “F0” and to control the flashing of the light emitting unit 16. Wireless transmission.

  When this radio signal is received by the arrow board 10 of “No 2” that is the slave unit 66, the arrow board 10 of “No 2” transmits wirelessly to the arrow board 10 of “No 3”, and this radio signal is sent to “No 3”. ”Is received by the arrow board 10. By repeating these, the blinking mode determined by the parent device 65 is transmitted to all the child devices 66. As described above, the master unit 65 that has confirmed the blinking mode and the slave unit 66 that has received the blinking mode perform blinking control of the light emitting unit 16 while synchronizing blinking between the adjacent arrow plates 10. Thereby, as for the some arrow board 10, the light emission part 16 blinks synchronously.

  Similarly, when the flashing mode is set to flow flashing, if the master unit 65 is set to any one of “F1” to “F9”, the control signal indicating that the base unit 65 performs flash control of the light emitting unit 16 by flow flashing. Is transmitted wirelessly to the handset 66, and each arrow plate 10 controls the light emitting unit 16 to blink by flow blinking. That is, each arrow board 10 performs blink control of the light emission part 16 by the time difference with the arrow board 10 which adjoins. In that case, each arrow board 10 performs blink control by adjusting the time difference at the time of performing blink control with the time difference between the adjacent arrow boards 10 according to the selected blink mode.

  When the blinking mode is set to flow blinking, the light of the light emitting unit 16 that emits light in the shape of an arrow is obtained by performing blink control of the light emitting unit 16 with a time difference between the adjacent arrow plates 10 in this way. It can blink so that it flows in the direction that the arrow is pointing. Moreover, the speed at which the arrow-shaped light flows can be changed by changing the time difference between the blinking of the adjacent arrow plates 10 in the flow blinking according to the set blinking mode.

  In the line-of-sight guidance apparatus 1 according to the first embodiment, control signals are transmitted and received by performing wireless communication between the arrow plates 10 as described above, but there is a similar line-of-sight guidance apparatus 1 in the vicinity. If there is a device that performs wireless communication using radio waves of the same frequency, there may be interference. For this reason, when the line-of-sight guidance apparatus 1 is used in a situation where there is a possibility of interference, the channel at the time of wireless communication is changed by changing the channel setting, and the frequency of the radio wave used in the wireless communication is changed.

  When performing channel setting, the operation unit 50 of the control unit 30 of the parent device 65 is operated to set the channel setting mode, and the channel of the parent device 65 is any one of “C0” to “C9”. Select. When the channel of the master unit 65 is selected, the channel of each slave unit 66 is set to the same channel as the channel of the master unit 65. Thereafter, by turning the power of the base unit 65 back on, the frequency at the time of performing wireless communication between the arrow plates 10 can be set to the frequency of the set channel. The frequency of radio waves at the time of wireless communication can be set according to the channel by setting the channel as described above. Therefore, when changing the frequency at the time of wireless communication, the channel is switched by the channel setting. Thus, the frequency can be changed.

  Further, when performing blinking control of the light emitting unit 16 while performing wireless communication between the arrow plates 10, the blinking control is performed while displaying the operation state on the information display unit 55 of the control unit 30. As an operation state displayed on the information display unit 55, for example, a charge amount of the secondary battery 42 or a communication state by wireless communication is displayed. That is, the information display unit 55 is provided with an LED for displaying information on the charge amount of the secondary battery 42 and an LED for displaying a communication state by wireless communication in advance, so that the charge amount of the secondary battery 42 is reduced, When reception by communication is interrupted, these LEDs indicate a decrease in charge amount or communication interruption.

  In the line-of-sight guidance device 1 according to the first embodiment described above, one of the plurality of arrow plates 10 included in the line-of-sight guidance device 1 is set as the parent device 65 and the rest is set as the child device 66 and set by the parent device 65. Based on the blinking mode of the light emitting unit 16 that has been performed, the blinking control of the light emitting units 16 of all the arrow plates 10 can be performed. Thereby, when performing blink control of the light emission part 16 of the arrow board 10, it can control using one arrow board 10 among the several arrow boards 10. FIG. As a result, the blinking can be controlled without using a dedicated device for operation.

  In addition, the arrow plate 10 can sequentially blink the light emitting units 16 between the plurality of arrow plates 10, and the control unit 60 of the base unit 65 sequentially switches the light emitting units 16 between the plurality of arrow plates 10. Since the timing for blinking can be set, the blinking control in accordance with the user's intention can be performed by setting the blinking control in the parent device 65. As a result, the desired blinking can be controlled more reliably without using a dedicated device for operation.

  In addition, each arrow plate 10 can set its own arrow plate 10 as the parent device 65 or the child device 66 by setting the address of its own arrow plate 10. In addition, it can be flexibly set as the master unit 65 or the slave unit 66. As a result, it is possible to easily control blinking without using a dedicated device for operation.

  In addition, since the communication unit 35 can change the frequency at which wireless communication is performed, when there is a possibility of interference with other devices by wireless communication, the channel setting is performed when wireless communication is performed. Interference can be prevented by changing the frequency. As a result, the control signals can be transmitted and received more reliably between the arrow plates 10 by wireless communication, and the blinking control of the light emitting unit 16 can be performed.

  Further, since the control unit 30 can be positioned above the arrow plate 10 when the arrow plate 10 is installed, the antenna 36 included in the communication unit 35 can be positioned above the arrow plate 10. Thereby, since the distance between the antenna 36 and the ground can be increased, the attenuation of radio waves when transmitting radio waves from the antenna 36 can be reduced. Therefore, the communicable distance when communicating between the arrow plates 10 can be increased, and the maximum distance between the arrow plates 10 when the arrow plates 10 are installed can be increased. As a result, with the plurality of arrow plates 10, the flashing of the light emitting unit 16 can be more reliably linked and flashed.

  Moreover, since the power supply part 40 is equipped with the solar battery 41 and the secondary battery 42, it produces electric power with the solar battery 41 in the daytime, and the generated electric power is stored in the secondary battery 42, and the secondary battery at night. Each part can be operated by the electric power stored in 42. Thereby, the power supply part 40 can supply electric power to each part of the arrow board 10, without receiving supply of electric power from the outside. As a result, the arrow plate 10 can be operated without incurring costs associated with the use of power.

[Embodiment 2]
The line-of-sight guidance device 1 according to the second embodiment has substantially the same configuration as the line-of-sight guidance device 1 according to the first embodiment, but is characterized in that a dry cell is used as a power source for the arrow plate. Since other configurations are the same as those of the first embodiment, the description thereof is omitted and the same reference numerals are given.

  FIG. 12 is an explanatory diagram illustrating a state in which an arrow plate included in the line-of-sight guidance device according to the second embodiment is viewed from the surface on the control unit side. The arrow board 70 included in the line-of-sight guidance apparatus 1 according to the second embodiment is similar to the arrow board 10 included in the line-of-sight guidance apparatus 1 according to the first embodiment, and includes a substantially rectangular panel 11, legs 20, and two locations. A unit mounting portion 26 is provided. In the second embodiment, unlike the first embodiment, the power supply unit 90 is separated from the control unit 75 and is disposed on the surface of the panel 11 on the side where the connection portion cap 57 is disposed. The connection portion is covered with the connection portion cap 57 and is connected to the wiring on the light emitting portion 16 side.

  Similarly to the first embodiment, the control unit 75 is electrically connected to the wiring on the light emitting unit 16 side by the cord 78 and is attached to the unit attachment portion 26 by the attachment member 33. In the second embodiment, the control unit 75 is electrically connected to the power supply unit 90 by the cord 78, and the power supply from the power supply unit 90 to the control unit 75 is performed by the cord 78. A connecting portion between the cord 78 and the power supply unit 90 is also covered with the connecting portion cap 57.

  FIG. 13 is a perspective view of the control unit shown in FIG. FIG. 14 is a perspective view of the control unit shown in FIG. The control unit 75 has a substantially rectangular parallelepiped casing 76, and a part of the casing 76 is a transparent cover 77 made of a member that transmits light. The control unit 75 can be attached to the unit attachment portion 26 by attaching the surface side of the casing 76 opposite to the surface where the transparent cover 77 is located to the unit attachment portion 26. In the casing 76, a communication unit 35 having an antenna 36 for transmitting and receiving radio waves is disposed.

  An information display unit 85 is provided in the casing 76 of the control unit 75. As the information display unit 85, a character display unit 86 that displays characters, and a monitor lamp 87 that includes LEDs and emits light. ,have. Both of the character display portion 86 and the monitor lamp 87 are disposed at a position facing the transparent cover 77 from the inside of the housing 76. That is, the character display portion 86 and the monitor lamp 87 are disposed at positions that can be seen from the outside through the transparent cover 77.

  FIG. 15 is a perspective view of the control unit shown in FIG. 13 as viewed from the side opposite to the transparent cover side. The control unit 75 is provided with an operation unit 80 on the surface opposite to the side on which the transparent cover 77 is provided. The operation unit 80 includes a switch 81 for performing an input operation. The switch 81 includes an A button 82 and a B button 83 each assigned a predetermined function. The control unit 75 is attached to the unit attachment portion 26 by the attachment member 33 in a state where the surface on which the operation portion 80 is provided faces the unit attachment portion 26 and is in contact with the unit attachment portion 26. At that time, the control unit 75 is attached to the unit attachment portion 26 in a positional relationship where the operation portion 80 is not covered by the unit attachment portion 26.

  FIG. 16 is a perspective view of the power supply unit shown in FIG. In the arrow plate 70 included in the line-of-sight guidance device 1 according to the second embodiment, a dry battery 92 is used for the power supply unit 90, and each electric component included in the arrow plate 70 is operated by electric power supplied from the dry battery 92. To do. For this reason, the power supply unit 90 has a battery case 91 that accommodates a plurality of dry batteries 92 and can extract power from the dry batteries 92. When the arrow plate 70 is used, the power supply unit 90 is disposed on the surface of the panel 11 opposite to the surface on which the display unit 15 is formed in a state in which a plurality of dry batteries 92 are accommodated. It is electrically connected to the unit 75. The dry battery 92 used in the power supply unit 90 may be a primary battery or a secondary battery.

  The line-of-sight guidance device 1 according to the second embodiment is configured as described above, and the operation thereof will be described below. Also in the arrow board 70 included in the line-of-sight guidance device 1 according to the second embodiment, the control unit 75 operates the operation unit 80 to set the address setting mode, the flashing mode setting mode of the light emitting unit 16, and the wireless The mode can be switched to and set to the communication channel setting mode. Each arrow plate 70 is operated by the power supplied from the dry battery 92 of the power supply unit 90, so that the light emitting unit 16 blinks or wireless communication is performed between the arrow plates 70.

  When using the line-of-sight guidance apparatus 1 according to the second embodiment, first, the address of each arrow plate 70 is set by operating the operation unit 80 while visually recognizing the information display unit 85 of the control unit 75. As a result, the parent device 65 and the child device 66 are set. When the address setting is completed, each arrow plate 70 is installed at a desired position.

  FIG. 17 is a perspective view of the installation state of the arrow plate shown in FIG. When the arrow plate 70 is installed, the leg portion 20 provided on the arrow plate 70 is pulled out to bring the leg portion 20 into an upright state, and one end side in the short direction of the frame portion 12 of the arrow plate 70 is downward. The arrow plate 70 is arranged at an arbitrary position in the direction. At that time, the arrow plate 70 is installed in a state where the control unit 75 is positioned on the upper end side of the panel 11.

  Next, the blinking mode of the light emitting unit 16 is set by operating the control unit 75 of the parent device 65. When the blinking mode is determined by the parent device 65, the parent device 65 transmits a control signal related to the blinking mode to the child device 66 by wireless communication. The slave unit 66 that has received this signal further transmits it to the adjacent slave unit 66, and by repeating this, the blinking mode determined by the master unit 65 is transmitted to all the slave units 66. Each arrow plate 70 can be caused to blink in association with the blinking of the light emitting unit 16 by the plurality of arrow plates 70 by performing blink control of the light emitting unit 16 based on this blinking mode.

  In addition, when the line-of-sight guidance device 1 is used, if there is a possibility that the radio wave frequency used when performing wireless communication between the arrow plates 70 may interfere with other devices, the channel is set in a mode in which the channel is not interfered. Select. Thereby, radio | wireless communication can be performed appropriately between the arrow boards 70, and blinking of the light emission part 16 can be linked appropriately.

  The line-of-sight guidance device 1 according to the second embodiment uses the dry battery 92 in the power supply unit 90 of the arrow plate 70, and operates each part of the arrow plate 70 with the electric power supplied from the dry battery 92. Regardless of the irradiation condition of the sunlight to 70, it can be operated stably. Thereby, the light emission part 16 can be blinked stably by each arrow board 70, and the cooperation of blinking by the several arrow board 70 can be performed stably. Further, when the power is reduced, the power can be recovered only by replacing the dry battery 92. Therefore, the recovery when the power is reduced can be easily performed. As a result, it is possible to control blinking in a state where the power supply status is more stable.

[Modification]
In the line-of-sight guidance device 1 according to the first and second embodiments, the light emitting device having the light emitting unit 16 is described using the arrow plates 10 and 70 having the arrow-shaped display unit 15. Other than the arrow plates 10 and 70 may be used. For example, the light emitting device may display an arbitrary character when the light emitting unit 16 is turned on. Even in the case where characters are displayed when the light emitting unit 16 is turned on, the content of the characters for the person who visually recognizes the line-of-sight guidance device 1 by blinking the light emitting unit 16 in cooperation with a plurality of light emitting devices. And flashing cooperation can be transmitted together, and arbitrary information can be transmitted effectively.

  In the line-of-sight guidance device 1 according to the first and second embodiments, when the arrow plates 10 and 70 are installed, the communication unit 35 is moved to the arrow position by positioning the control units 30 and 75 at the upper ends of the arrow plates 10 and 70. Although it is located above the plates 10 and 70, the entire communication unit 35 may not be located above the arrow plates 10 and 70. For example, the communication unit 35 is provided with a communication control unit 37 that performs communication control at a position other than the control units 30 and 75, and only the antenna 36 is disposed in the control units 30 and 75. The antenna 36 may be positioned above the arrow plates 10 and 70 during installation. Since the antenna 36 directly transmits and receives radio waves used for communication, the antenna 36 is positioned above the arrow plates 10 and 70 when the arrow plates 10 and 70 are installed, regardless of the arrangement of the communication control unit 37. By doing so, the communicable distance when communicating between the arrow plates 10 and 70 can be increased.

1 Gaze guidance device 10, 70 Arrow plate (light emitting device)
DESCRIPTION OF SYMBOLS 11 Panel 12 Frame part 15 Display part 16 Light emission part 20 Leg part 26 Unit attachment part 30, 75 Control unit 31, 76 Case 32, 77 Transparent cover 33 Attachment member 35 Communication part 36 Antenna 37 Communication control part 40, 90 Power supply part 41 Solar battery 42 Secondary battery 50, 80 Operation part 51, 81 Switch 53, 82 A button 54, 83 B button 55, 85 Information display part 57 Connection part cap 60 Control part 65 Parent machine 66 Child machine 91 Battery case 92 Dry battery

Claims (3)

A light emitting unit that emits light;
A control unit that performs flashing control of the light emitting unit and includes a storage unit;
A communication unit that wirelessly transmits and receives a control signal from the control unit; and
A power supply unit that supplies power to the light emitting unit, the control unit, and the communication unit;
An information display unit having at least an LED for recognizing the parent device and displaying arbitrary information;
An antenna for transmitting and receiving radio waves used in wireless communication, the communication unit;
A control unit for installing the control unit and the communication unit;
An operation unit provided in the control unit;
A unit attaching portion that is rotatably connected to a frame portion to which a panel on which the light emitting portion is provided is attached, and capable of detachably attaching the control unit;
A plurality of light emitting devices having
The unit mounting portion is connected to the upper and lower ends of the frame portion in the state where the two light emitting devices are installed,
The two unit attachment portions are rotated with respect to the frame portion, thereby positioning the control unit attached to the unit attachment portion on the opposite side of the panel where the light emitting portion is provided. And a state in which the control unit is positioned on the upper side of the frame portion when the light-emitting device is installed. Makes it possible to position the antenna above the light emitting device,
The control unit is attached to the unit attachment part in a direction where the operation part is located on the surface in a state of being located on the opposite side of the panel where the light emitting part is provided,
The control unit of each of the light emitting devices can transmit and receive the control signal through wireless communication between the communication units of the respective light emitting devices, and the storage unit By selecting one of the addresses stored in the address and setting the address of the light emitting device of itself, it is possible to set the light emitting device of the self as the parent device or the child device. ,
The information display unit displays the address set as the address of the light-emitting device of itself, and the LED lights only in the information display unit of the light-emitting device set as the master unit,
The control unit of the base unit sets a control signal for flashing control of the light emitting unit and wirelessly communicates the set control signal for flashing control to the control unit of the slave unit between the communication units. Send through
The control unit of the slave unit transmits the control signal of the blinking control transmitted from the control unit of the master unit to the control units of other slave units by wireless communication between the communication units. Send through
The line-of-sight guidance device, wherein the control unit of each of the light-emitting devices blinks the light-emitting unit based on a blink control signal set by the control unit of the parent device. Each of the control units performs the blinking control of the light emitting unit based on a control signal of the flashing control of the light emitting unit set by the control unit of the base unit, and thereby the light emission between a plurality of the light emitting devices. Parts can be blinked sequentially,
The line-of-sight guidance device according to claim 1, wherein the control unit of the base unit can set a timing for sequentially blinking the light emitting units among the plurality of light emitting devices.   The line-of-sight guidance device according to claim 1, wherein the communication unit can change a frequency when performing wireless communication.

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