JP2022104661A - Display device - Google Patents

Abstract

To provide a display device which offers improved visibility and attractivity of a second display portion.SOLUTION: A display device comprises: a first display portion 30 with a first display pattern 34 including achromatic and chromatic areas; and a second display portion 40 located on a projection surface of the first display portion 30 and provided with a chromatic second display pattern 44 different from that of the first display portion 30. When the first display portion 30 and the second display portion 40 are displayed, the second display pattern 44 of the second display portion 40 remains chromatic.SELECTED DRAWING: Figure 3

Description

Embodiments of the present invention relate to display devices that display differently.

Conventionally, in a display device such as a guide light, a second display unit having a different display is arranged on the back side of the first display unit that always displays, and the display of the second display unit is transmitted through the first display unit. Some are configured to display.

In such a display device, when the second display unit is displayed on top of the first display unit that is always displayed, the visibility and attractiveness of the second display unit may not be good, and the visibility of the second display unit may not be good. , Improvement of attractiveness is desired.

Japanese Unexamined Patent Publication No. 2009-277545

An object of the present invention to be solved is to provide a display device capable of improving the visibility and attractiveness of the second display unit.

The display device of the embodiment is arranged on a first display unit having a first display pattern including an achromatic color and a chromatic color region and a projection surface of the first display unit, and has a display different from that of the first display unit. It is provided with a second display unit having a second display pattern of coloring. When the first display unit and the second display unit are displayed, the second display pattern of the second display unit maintains a chromatic color.

According to the display device of the embodiment, it can be expected that the visibility and the attractiveness of the second display unit will be improved.

It is a perspective view of the display device which shows one Embodiment. The second display unit of the display unit of the same display device is a front view in a turned-off state. Same as above The second display unit of the display unit is a front view in a lit state. It is sectional drawing of the same above-mentioned display unit. It is a circuit diagram which shows the direct-upper floor cooperation of the 2nd display control unit of the above-mentioned display device. Same as above It is a circuit diagram which shows the cooperation between the 2nd display control unit of a display device, and the blinking induction sound control unit. It is a chromaticity diagram which defines the chromatic color and the achromatic color of the 2nd display part of the same display device. Same as above It is a timing chart showing the operation sequence of the display device. Same as above It is a timing chart showing an operation sequence when a signal is processed by the same processing circuit of the display device.

Hereinafter, one embodiment will be described with reference to the drawings.

FIG. 1 shows the display device 10. The display device 10 is a guide light that is installed on the ceiling surface or the wall surface corresponding to an evacuation route such as an emergency exit and guides the evacuation route. Further, the display device 10 positively guides the user to the guidance path by blinking and a guidance sound in response to an operation signal which is a guidance signal from a signal device linked to the facility's automatic fire alarm, and also from the automatic fire alarm. It corresponds to a dynamic evacuation guidance system that stops active evacuation guidance to the guidance route and displays prohibition of entry in response to the guidance stop signal or the guidance stop signal that is the detection signal from the smoke detector.

The display device 10 includes a housing 11, a display unit 12 provided on the front side of the housing 11, a blinking display unit 13 provided on the lower side of the housing 11, and an induction sound provided on the front side of the housing 11. It is equipped with an output unit 14, a monitor unit 15 provided on the lower surface side of the housing 11, an operation check switch 16, and the like. Further, although not shown in FIG. 1, a storage battery that supplies power in the event of a power failure, a control device that controls the display device 10, and the like are arranged in the housing 11.

A display window 17 in which the display unit 12 is arranged and an opening 18 in which the induction sound output unit 14 is arranged are provided on the front surface of the housing 11. The display unit 12 always displays guidance and displays prohibition of entry in response to the guidance stop signal. The blinking display unit 13 has a translucent cover protruding from the lower surface side of the housing 11, and a blinking light source arranged inside the translucent cover blinks in response to an operation signal. The guidance sound output unit 14 outputs a guidance sound including voice guidance according to the operation signal. The monitor unit 15 is arranged with an inspection switch, a plurality of monitor lamps for charging and a light source, and the like. As these monitor lamps, LEDs having different emission colors and the like are used. The operation confirmation switch 16 makes it possible to confirm whether or not the blinking display unit 13 and the guidance sound output unit 14 operate by operation.

Then, the display unit 12 of the display device 10 displays the guidance at all times and at the time of a power failure, and displays the entry prohibition according to the guidance stop signal. The blinking display unit 13 and the guidance sound output unit 14 are configured to output a guidance sound including a voice for guiding the blinking operation and evacuation guidance according to the operation signal, so that the evacuation guidance effect is further exerted. There is.

Next, the display unit 12 is shown in FIGS. 2 to 4.

It includes a frame-shaped unit main body 21 that opens back and forth, and a first display unit 22 and a second display unit 23 arranged in the unit main body 21.

The first display unit 22 is arranged so as to face the front opening of the housing 11. The first display unit 22 includes a first light source unit 31, a first light guide plate 32 arranged on the display surface side of the housing 11, and a first display plate 33 arranged on the front side of the first light guide plate 32. Have. The first display pattern 34 is displayed on the first display board 33. The first display board 33 is configured as the first display unit 30.

The first light guide plate 32 is formed in the shape of a quadrangular plate by a synthetic resin having light transmission such as acrylic resin and polycarbonate resin. The first light guide plate 32 has an incident surface on which light is incident on the upper end surface facing the first light source unit 31, and has an exit surface on which light incident from the incident surface is emitted on one main surface on the front surface side. .. The first light guide plate 32 may be provided with light distribution means on the surface opposite to the emission surface so that the light incident from the incident surface is emitted from the emission surface. Light distribution means include dot printing in which ink containing a light transmission control material (white pigment) is regularly printed, prism cut shape or dot processing that provides multiple irregularities on the surface facing the emission surface, and dot processing on the emission surface. Rough surface processing that polishes the facing surfaces to provide fine irregularities is included.

The first display plate 33 is formed in the shape of a quadrangular sheet by a synthetic resin having light transmission. The first display board 33 is composed of a region in which the first display pattern 34 including pictograms such as a pattern, characters, and arrows indicating guidance is formed, and another region in which the first display pattern 34 is not formed. ing. In addition, in FIGS. 1 and 2, the first display pattern 34 is simplified and shown in a square shape for the sake of simplicity, but in reality, a pattern or the like indicating evacuation guidance is displayed. The first display pattern 34 is formed by printing with green ink, for example, silk screen printing or inkjet printing. Further, the region of the first display plate 33 other than the first display pattern 34 is formed by printing with white ink, for example, silk screen printing or inkjet printing. Then, light is emitted from the first light guide plate 32 to the first display plate 33, the first display pattern 34 is displayed in green, and the region without the first display pattern 34 is displayed in white. Therefore, the first display unit 30 has two color regions, a green chromatic region with the first display pattern 34 and a white achromatic region without the first display pattern 34. The first display plate 33 may be integrally formed with the first light guide plate 32, or the first display pattern 34 may be formed on the front surface side of the first light guide plate 32.

The first light source unit 31 is composed of a light emitting module. The first light source unit 31 has a substrate 35 and a first light source 36 which is a solid-state light emitting element such as an LED element mounted on the substrate 35. The first light source 36 emits, for example, white light. The first light source 36 faces the incident surface of the first light guide plate 32 and radiates light from the incident surface into the first light guide plate 32. Then, the first light source 36 is constantly turned on by the power of an external power source or a storage battery, and the first display unit 30 is constantly displayed.

Further, the second display unit 23 is arranged further in front of the first display unit 22 arranged in the unit main body 21. The second display unit 23 includes a second display unit 40 and a second light source unit 41 that emits red light.

The second display unit 40 is arranged to face the front side of the first display unit 30 arranged in the unit main body 21. That is, the second display unit 40 is arranged on the projection surface of the first display unit 30 and is configured so that the light emitted from the first display unit 30 passes through. Further, the second display unit 40 is arranged so as to be separated from the first display unit 30 in the front.

The second display unit 40 is formed by a second light guide plate 42 arranged on the front surface side of the first display unit 30. The second light guide plate 42 is formed in the shape of a square plate by a colorless transparent synthetic resin having light transmittance such as acrylic resin and polycarbonate resin. The second light guide plate 42 has an incident surface on which red light is incident on the upper end surface facing the second light source unit 41, and the red light incident on the incident surface guides the red light toward the lower end surface.

On the back side of the second light guide plate 42, a second display pattern 44 is formed as a display pattern including pictograms such as a pattern indicating prohibition of entry and characters. The second display pattern 44 is formed in the pattern shape of "x" by, for example, printing such as white silk screen printing or inkjet printing, or uneven processing. Then, the red light guided through the second light guide plate 42 is diffusely reflected by the second display pattern 44 and emitted to the front side of the second display unit 40. As a result, the second display unit 40 displays the shape of the second display pattern 44 with red light, which is a chromatic color. Therefore, the display by the second display unit 40 is different in color and shape from the first display unit 30. The area provided with the second display pattern 44 of the second display unit 40 has a predetermined transmittance, and the area without the second display pattern 44 has a higher transmittance than the area provided with the second display pattern 44. It is a rate. Therefore, the light radiated from the front surface side of the first display unit 30 is attenuated at a predetermined transmittance in the region where the second display pattern 44 is provided, and the second light guide plate 42 is colorless and transparent in the other regions. Is transparent to almost as it is.

The second light source unit 41 is composed of a light emitting module. The second light source unit 41 has a substrate 45 and a second light source 46 which is a solid-state light emitting element such as an LED element mounted on the substrate 45. The second light source 46 emits, for example, red light. The second light source 46 is opposed to the incident surface of the second light guide plate 42, and the light is incident on the second light guide plate 42 from the incident surface.

In the unit main body 21, a first display control unit that controls the display of the first display unit 30, a second display control unit that controls the display of the second display unit 40, a blinking light source unit 13, and an induction sound output unit are included. A blinking induction sound control unit that controls 14 is provided. A storage battery, which is a rechargeable and dischargeable secondary battery that supplies electric power in the event of a power failure, is used for each of these units.

The first display control unit converts the power of the external power supply into a predetermined power when the external power supply such as a commercial AC power supply is supplied, that is, at all times, turns on the first light source 36, and displays the first display unit 30. The storage battery is charged, and when the external power supply is cut off, that is, when a power failure occurs, the power of the storage battery is converted into a predetermined power, the first light source 36 is turned on, and the first display unit 30 is displayed. The second display control unit and the blinking induction sound control unit will be described later.

Further, as shown in FIG. 1, the display device 10 is a single-sided display type in which only one side on the front side is the display surface side, but the display device 10 is a double-sided display type in which both sides opposite to the front side are the display surface side. May be good.

Next, FIG. 5 shows a second display control unit 50 that controls lighting of the second display unit 40 of the display device 10. In FIG. 5, in the dynamic evacuation guidance system installed in the facility, the second display control unit 50 of the display device 10 installed on a certain floor and the floor directly above the floor on which the display device 10 is installed are shown. The case where the second display control unit 50 of the display device 10 to be installed cooperates with the second display control unit 50 is shown. The broken line in FIG. 5 indicates the boundary between a certain floor and the floor directly above.

The second display control unit 50 includes a power conversion circuit 51 that converts the power supplied from an external power source E such as a commercial AC power supply into a predetermined power such as 17V after rectification. As the power conversion circuit 51, a DC-DC converter such as a flyback converter that insulates the primary side and the secondary side is used.

The anode of the diode D1 is connected to the output end of the power conversion circuit 51, and the charging circuit 52 is connected to the cathode of the diode D1. The charging circuit 52 converts the DC voltage supplied from the power conversion circuit 51 into a predetermined DC voltage such as 7 to 10.5 V and supplies the DC voltage to the storage battery B1 to charge the storage battery B1.

A lighting circuit 53 is connected between the charging circuit 52 and the storage battery B1. The lighting circuit 53 converts the DC voltage constantly supplied from the charging circuit 52 or the DC voltage supplied from the storage battery B1 in the event of a power failure into a predetermined lighting voltage and supplies the DC voltage to the second light source 46 to light the second light source 46. Let me. In the lighting circuit 53 of the present embodiment, the DC voltage supplied from the charging circuit 52 or the storage battery B1 is boosted to, for example, 24V and supplied.

The anode of the diode D2 is connected between the cathode of the diode D1 on the output side of the power conversion circuit 51 and the charging circuit 52, and the anode of the diode D3 is connected between the charging circuit 52 and the storage battery B1. The input end of the voltage generator 54 is connected to the cathode of D3. The voltage generation unit 54 of the present embodiment is a booster circuit 55 that constantly boosts the DC voltage supplied from the power conversion circuit 51 or the DC voltage supplied from the storage battery B1 in the event of a power failure to a detection voltage (contact voltage) such as 24V. Is used. The booster circuit 55, which is the voltage generation unit 54 of the present embodiment, boosts the voltage to a detection voltage higher than the control voltage described later.

A series circuit of the current limiting resistor R1 and the diode D4 to which the anode is connected to the current limiting resistor R1 is connected to the output end of the booster circuit 55. The cathode of the diode D4 is connected to the contact control terminal 56, which is a contact provided in the power supply unit 21 of the display device 10. The contact control terminal 56 is a contact that is connected to an automatic fire alarm and operates in response to an input of a guidance stop signal, which is an entry prohibition signal. A voltage detection unit 57 that detects a change in voltage according to an induction stop signal for the contact control terminal 56 is connected between the cathode of the diode D4 and the contact control terminal 56. The voltage detection unit 57 is an induction stop signal detection unit that detects an induction stop signal, and sends a detection result to a control circuit 58 that is a control unit.

Then, the power supplied from the power conversion circuit 51 at all times or the power supplied from the storage battery B1 in the event of a power failure is determined by the booster circuit 55, the diodes D2, D3, D4, the current limiting resistor R1, etc., which are the voltage generation units 54. A voltage supply circuit 59 that converts the detected power into power and supplies it to the contact control terminal 56 with the automatic fire alarm is configured.

Further, the control circuit 58 controls the operation of the power conversion circuit 51, the charging circuit 52, the lighting circuit 53, and the booster circuit 55. The control circuit 58 monitors the voltage detected by the voltage detection unit 57, and when it detects an induction stop signal from the automatic fire alarm in response to a change in voltage, it operates the lighting circuit 53 to light the second light source 46. Let me.

The control circuit 58 operates by the control voltage supplied from the control power supply circuit 61. The control power supply circuit 61 is composed of a regulator 62. On the output side of the power conversion circuit 51, the anode of the diode D5 is connected between the cathode of the diode D1 and the charging circuit 52, and the anode of the diode D6 is connected between the charging circuit 52 and the storage battery B1, and these diodes D5, The regulator 62 is connected to the cathode of D6. As the regulator 62, a voltage regulator such as a 3-terminal regulator is used, and the DC voltage constantly supplied from the power conversion circuit 51 through the diode D5 or the DC voltage supplied from the storage battery B1 through the diode D6 in the event of a power failure is, for example, 3.3 V. It is converted into the predetermined control power of the above and supplied to the control circuit 58.

The power conversion circuit 51, the charging circuit 52, the lighting circuit 53, the control circuit 58, the control power supply circuit 61, and the like constitute an emergency light unit 63 that can respond even in the event of a power failure.

Further, when the display device 10 has a function of actively performing evacuation guidance by blinking display or guidance sound, the second display control unit 50 can cooperate with the blinking guidance sound control unit that controls the blinking display or guidance sound. It is configured as follows. The blinking guidance sound control unit controls the blinking display and the output of the guidance sound according to the operation signal from the signal device linked to the automatic fire alarm. The second display control unit 50 includes an operation signal processing circuit 64 in order to cooperate with the blinking induction sound control unit. The operation signal processing circuit 64 processes the operation signal from the signal device linked to the automatic fire alarm, and sends the processed operation signal to the control circuit 58. The operation signal processing circuit 64 insulates the primary side to which the signal device is connected and the secondary side to which the control circuit 58 is connected by using, for example, a photocoupler.

The operation signal processing circuit 64 is configured so that a voltage-bearing operation signal is input from the signal device during normal operation, and no operation signal is input from the signal device when evacuation is required, such as in the event of a fire. In this case, in the control circuit 58 that inputs the signal processed by the operation signal processing circuit 64, the guidance signal is not input when the operation signal is input to the operation signal processing circuit 64, and the guidance signal is input when the operation signal is no longer input. Judge and process.

In addition, the control function on the immediate upper floor of the second display control unit 50 is subject to the condition that the display device 10 cannot actively guide evacuation because the smoke detector 78 on the installation floor of the display device 10 and near the installation location detects smoke. When it occurs, it is treated as not being able to actively guide evacuation even on the display device 10 on the floor directly above the floor where the condition occurs, and it is a function to stop active evacuation guidance on the display device 10 on the floor directly above.

The second display control unit 50 includes a direct upper floor control circuit 65 that controls the display device 10 on the immediate upper floor. The direct upper floor control circuit 65 is connected to the contact control terminal 56 of the display device 10 installed on the direct upper floor, and the guidance stop signal is output to the contact control terminal 56 of the display device 10 on the direct upper floor under the control of the control circuit 58. ..

Then, the second display control unit 50 controls the lighting of the second light source 46 to improve the brightness of the second display unit 40 in order to improve the attractiveness of the second display unit 40 when the second display unit 40 is lit. It is configured to change the light source. The change in the brightness of the second display unit 40 is a blinking that repeatedly turns on and off the second display unit 40, and a blinking that repeats light and dark by dimming control while maintaining the lighting state of the second display unit 40. It may be either.

The blinking of the second display unit 40 is basically based on the first operation time T ₁ = 50 msec when the light is on or light, and the second operation time T ₂ = 450 msec when the light is off or dark. These first operation time and second operation time are the same as the lighting time and the extinguishing time specified for the blinking of the blinking display unit 13.

The blinking cycle of the second display unit 40 is represented by n × T ₁ + m × T ₂ . n and m are arbitrary values, and when the ratio of the first operation time is increased, the n value is increased, the m value is decreased, and when the ratio of the first operation time is decreased, the n value is decreased. Increase the m value. However, there is a relationship of n> m.

The blinking cycle of the second display unit 40 is preferably in the range of 0 <(n × T ₁ ) / (n × T ₁ + m × T ₂ ) ≦ 0.5. Alternatively, the blinking cycle of the second display unit 40 is preferably in the range of 0.5 ≦ (n × T ₁ ) / (n × T ₁ + m × T ₂ ) <1.0. The blinking cycle of the second display unit 40 is preferably a blinking cycle in which blinking is easily perceived. I am trying to.

Further, the control circuit 58 of the second display control unit 50 blinks the blinking display unit 13 by inputting the induction signal and outputs the induction sound from the induction sound output unit 14, and when the induction stop signal is input, the blinking display unit In addition to stopping the blinking of 13 and the output of the guidance sound from the guidance sound output unit 14, the second display unit 40 is controlled to be displayed.

Even if the guidance signal is input while the guidance stop signal is input and the second display unit 40 is displayed, the control circuit 58 continues the stop state of the blinking display unit 13 and the guidance sound output unit 14, and the second display unit 40 is displayed. 2 Control so that the display of the display unit is continued.

The control circuit 58 continues the display of the second display unit 40 even if the guidance stop signal is input to display the second display unit 40 and the guidance stop signal is not input while the induction signal is being input. To control. Further, when the guidance stop signal and the guidance signal are no longer input, the display of the second display unit 40 is controlled to be stopped.

Next, FIG. 6 shows the cooperation between the second display control unit 50 included in the display device 10 and the blinking induction sound control unit 70.

The blinking induction sound control unit 70 controls the blinking display unit 13 and the induction sound output unit 14. The blinking induction sound control unit 70 includes a power conversion circuit 71 that converts the power supplied from an external power source E such as a commercial AC power supply into a predetermined power such as 17V after rectification. As the power conversion circuit 71, a DC-DC converter such as a flyback converter that insulates the primary side and the secondary side is used.

The anode of the diode D11 is connected to the output end of the power conversion circuit 71, and the charging circuit 72 is connected to the cathode of the diode D11. The charging circuit 72 converts the DC voltage supplied from the power conversion circuit 71 into a predetermined DC voltage such as 7 to 10.5 V and supplies the DC voltage to the storage battery B2 to charge the storage battery B2.

A discharge circuit 73, which is a lighting circuit or a blinking circuit, is connected between the charging circuit 72 and the storage battery B2. The discharge circuit 73 converts the DC voltage constantly supplied from the charging circuit 72 or the DC voltage supplied from the storage battery B2 in the event of a power failure into a predetermined lighting voltage, supplies the DC voltage to the blinking light source 74 of the blinking display unit 13, and blinks. Blink the light source 74. In the discharge circuit 73 of the present embodiment, the DC voltage supplied from the charging circuit 72 or the storage battery B2 is boosted to, for example, 24V and supplied.

A discharge circuit 75, which is an inductive sound output circuit, is connected between the charging circuit 72 and the storage battery B2. The discharge circuit 75 drives the speaker 76 included in the induction sound output unit 14, and outputs an induction sound including a voice such as “This is the emergency exit”.

The anode of the diode D12 is connected between the charging circuit 72 and the storage battery B2, and the input end of the voltage generation circuit 77 for the smoke detector is connected to the cathode of the diode D12. The smoke detector voltage generation circuit 77 constantly boosts the DC voltage supplied from the power conversion circuit 71 or the DC voltage supplied from the storage battery B2 in the event of a power failure to an operating voltage such as 24V.

A series circuit of a current limiting resistor R11 and a diode D13 to which an anode is connected to the current limiting resistor R11 is connected to the output end of the voltage generation circuit 77 for a smoke detector. The cathode of the diode D13 is connected to a smoke detector 78 installed near the installation site on the installation floor of the display device 10. The smoke detector 78 operates by receiving an operating voltage supplied from the smoke detector voltage generation circuit 77, and generates a signal that becomes an induction stop signal at the time of smoke detection.

A control circuit 65 directly above the second display control unit 50 is connected between the cathode of the diode D13 and the smoke detector 78. When the direct upper floor control circuit 65 outputs an inductive stop signal to the contact control terminal 56 of the display device 10 on the direct upper floor, the inductive stop signal is also output between the cathode of the diode D13 and the smoke detector 78.

A voltage detection unit 79 that detects a change in voltage in response to an input of an induction stop signal from the second display control unit 50 or the smoke detector 78 is connected between the cathode of the diode D13 and the smoke detector 78. There is. The voltage detection unit 79 is an induction stop signal detection unit that detects an induction stop signal from the smoke detector 78, and sends the detection result to the control circuit 80 that is the control unit.

Further, the control circuit 80 controls the operation of the power conversion circuit 71, the charging circuit 72, the discharging circuits 73, 75, and the voltage generation circuit 77 for the smoke detector. The control circuit 80 monitors the voltage detected by the voltage detection unit 79, and when it detects an induction stop signal from the second display control unit 50 or the smoke detector 78 in response to a change in voltage, the discharge circuit 73 is stopped. The flashing light source 74 is turned off, the discharge circuit 75 is stopped, the output of the guidance sound from the speaker 76 is stopped, and the active evacuation guidance is stopped.

The control circuit 80 operates by the control voltage supplied from the control power supply circuit 81. The control power supply circuit 81 is composed of a regulator 82. On the output side of the power conversion circuit 71, the anode of the diode D14 is connected between the cathode of the diode D11 and the charging circuit 72, and the anode of the diode D15 is connected between the charging circuit 72 and the storage battery B2. The regulator 82 is connected to the cathode of D15. As the regulator 82, a voltage regulator such as a 3-terminal regulator is used, and the DC voltage always supplied from the power conversion circuit 71 through the diode D14 or the DC voltage supplied from the storage battery B2 through the diode D15 in the event of a power failure is, for example, 3.3 V. It is converted into the predetermined control power of the above and supplied to the control circuit 80.

Further, the blinking induction sound control unit 70 includes an operation signal processing circuit 83 that processes an operation signal input from a signal device linked to an automatic fire alarm and sends the processed signal to the control circuit 58. The operation signal processing circuit 83 processes the operation signal from the signal device linked to the automatic fire alarm, and sends the processed operation signal to the control circuit 58. The operation signal processing circuit 83 insulates the primary side to which the signal device is connected and the secondary side to which the control circuit 80 is connected by using, for example, a photocoupler.

The operation signal processing circuit 83 is configured so that a voltage-bearing operation signal is input from the signal device during normal operation, and no operation signal is input from the signal device when evacuation is required, such as in the event of a fire. In this case, in the control circuit 80 that inputs the signal processed by the operation signal processing circuit 83, the guidance signal is not input when the operation signal is input to the operation signal processing circuit 83, and the guidance signal is input when the operation signal is no longer input. Judge and process.

In addition, the control function on the floor directly above the blinking guidance sound control unit 70 is subject to the condition that the display device 10 cannot actively guide evacuation because the smoke detector 78 on the installation floor of the display device 10 and near the installation location detects smoke. When it occurs, it is treated as not being able to actively guide evacuation even on the display device 10 on the floor directly above the floor where the condition occurs, and it is a function to stop active evacuation guidance on the display device 10 on the floor directly above.

The blinking induction sound control unit 70 includes a direct upper floor control circuit 84 that controls the display device 10 on the immediate upper floor. The control circuit 84 on the immediately above floor is connected to the smoke detector terminal of the blinking induction sound control unit 70 of the display device 10 installed on the immediately above floor, and the induction stop signal is blinked on the display device 10 on the immediately above floor under the control of the control circuit 80. Output to the induction sound control unit 70. The connection between the control circuit 84 on the immediately above floor and the blinking induction sound control unit 70 of the display device 10 installed on the floor directly above is not shown.

The blinking induction sound control unit 70 is also connected to the contact control terminal 56 of the display device 10 having the same signal output end of the direct upper floor control circuit 84 in order to cooperate with the second display control unit 50 of the same display device 10. It is connected. When the direct upper floor control circuit 84 outputs an induction stop signal to the contact control terminal 56 of the display device 10 on the immediate upper floor, the induction stop signal is also output to the contact control terminal 56 of the same display device 10.

Further, in the display device 10, when the first display unit 30 and the second display unit 40 are displayed at the same time, the second display unit 40 is second so as to improve the visibility and attractiveness of the second display unit 40. The display pattern 44 is configured to maintain chromatic colors.

Further, when the first display unit 30 and the second display unit 40 are displayed at the same time, the second display pattern 44 of the second display unit 40 overlaps with the first display pattern 34 of the first display unit 30 and becomes achromatic. In this case, when the brightness of the area where the second display pattern 44 of the second display unit 40 overlaps with the first display pattern 34 of the first display unit 30 and becomes achromatic is displayed only in A and the first display unit 30. Assuming that the brightness of the achromatic region of the first display pattern 34 is B, the relationship is A> B. Alternatively, the relationship is A <B.

FIG. 7 shows the chromaticity diagram described in JIS Z 8110: 1995. The achromatic color is white or white, and the white area in the center of the chromaticity diagram is the achromatic area in the narrow sense, and the area around the achromatic area in the narrow sense, that is, greenish white, yellowish white, Light pink, purplish white, and bluish white areas are broadly achromatic areas.

The range of the achromatic color in the narrow sense on the black body locus is, for example, 4500 to 14000K duv ± 0.02, and the achromatic color in the narrow sense on the x and y coordinates of the chromaticity diagram is (0.2506, 0.2901). , (0.2800, 0.2521), (0.3698, 0.4146), (0.3531, 0.3203).

The straight line L1 of the alternate long and short dash line shown in FIG. 7 and the straight line L2 of the alternate long and short dash line are colors that can be reproduced by mixing red and green, respectively.

The straight line L1 of the alternate long and short dash line is a color that can be reproduced by mixing red and green without passing through an achromatic region in a narrow sense and a broad sense. That is, when the first display unit 30 and the second display unit 40 are displayed at the same time, the second display pattern 44 of the second display unit 40 is configured to maintain the chromatic color, and the second display unit 40 is visually recognized. It can improve sexuality and attractiveness.

The straight line L2 of the two-dot chain line passes through an achromatic region in a broad sense and is a color that can be reproduced by mixing red and green. In this case, when the first display unit 30 and the second display unit 40 are displayed at the same time, the second display pattern 44 of the second display unit 40 overlaps with the first display pattern 34 of the first display unit 30 and is achromatic. The brightness of the area where the second display pattern 44 of the second display unit 40 overlaps with the first display pattern 34 of the first display unit 30 and becomes achromatic is displayed only for A and the first display unit 30. Assuming that the brightness of the achromatic region of the first display pattern 34 is B, the visibility and attractiveness of the second display unit 40 can be improved by setting A> B.

That is, in the relationship of A> B, the red color of the “x” mark of the second display pattern 44 (+ the white color of the first display unit 30)> the achromatic color (the red color of the “x” mark of the second display pattern 44 + the first The relationship is as follows: green of the display unit 30)> white of the first display unit 30> green of the first display unit 30. As a result, the achromatic color of the second display pattern 44 (red of the “x” mark of the second display pattern 44 + green of the first display unit 30) and the white color of the first display unit 30 are different in brightness, resulting in contrast. Is clarified, so that the visibility and attractiveness of the display of the "x" mark in the second display pattern 44 can be improved.

Further, in some cases, the visibility and attractiveness of the second display unit 40 can be improved even in the relationship of A <B. In the relationship of A <B, the red color of the "x" mark of the second display pattern 44 (+ the white color of the first display unit 30)> the white color of the first display unit 30> the achromatic color (the "x" of the second display pattern 44). The relationship is as follows: red of the mark + green of the first display unit 30)> green of the first display unit 30. In this case, it can be realized by lowering the brightness of the green color by lowering the transmittance of the green color of the first display unit 30. Even in this case, the brightness between the achromatic color of the second display pattern 44 (red of the “x” mark of the second display pattern 44 + green of the first display unit 30) and the white color of the first display unit 30. Since the contrast becomes clear when the colors are different, the visibility and attractiveness of the display of the “x” mark in the second display pattern 44 can be improved.

Next, the overall operation of the display device 10 will be described.

As shown in FIG. 2, the display device 10 constantly displays the first display unit 30 of the display unit 12 and displays the evacuation route. The second display unit 40 does not display when the guidance stop signal is not input from the automatic fire alarm, the display device 10 on the immediately lower floor, or the blinking guidance sound control unit 70 to the contact control terminal 56.

Further, when a guidance stop signal is input to the contact control terminal 56 from the automatic fire alarm, the display device 10 on the immediately lower floor, or the blinking guidance sound control unit 70, as shown in FIG. 3, the second display of the display unit 12 is displayed. Part 40 is displayed, that is, the entry prohibition marked with "x" is displayed. As a result, the evacuees can confirm the display of the "x" mark on the display device 10 to prohibit entry and evacuate toward another evacuation route. At this time, by blinking the second display unit 40, it is possible to improve the attractiveness of the second display unit 40 from the evacuees.

Then, the first display control unit that controls the first display unit 30 constantly lights the first display unit 30 and charges the storage battery by the electric power from the external power source E, and also from the storage battery in the event of a power failure. The first display unit 30 is turned on by the discharged electric power.

Further, in the second display control unit 50 that controls the second display unit 40, the control power supply circuit 61 transfers the control power supply to the control circuit 58 by a predetermined DC voltage obtained by converting the external power supply E by the power conversion circuit 51 at all times. The charging circuit 52 charges the storage battery B1, and the voltage supply circuit 59 supplies the detected voltage to the contact control terminal 56. Further, in the second display control unit 50, the control power supply circuit 61 supplies the control power supply to the control circuit 58 by the DC voltage discharged from the storage battery B1 in the event of a power failure, and the voltage supply circuit 59 detects the contact control terminal 56. Supply voltage.

The control circuit 58 of the second display control unit 50 monitors the voltage detected by the voltage detection unit 57 at all times or during a power failure, and is transmitted from the automatic fire alarm, the display device 10 on the immediately lower floor, or the blinking induction sound control unit 70. Judges whether or not the guidance stop signal of is input.

When the control circuit 58 detects an induction stop signal from the automatic fire alarm, the display device 10 on the immediately lower floor, or the blinking induction sound control unit 70 in response to the voltage change detected by the voltage detection unit 57, the control circuit 58 turns on the lighting circuit 53. It is operated to turn on the second light source 46 and display the prohibition of entry marked with "x".

In the event of a power failure, the storage battery capacity and the like are set so that the displayable time of the second display unit 40 by the storage battery B1 is longer than the displayable time of the first display unit 30 by the storage battery.

Further, in the blinking induction sound control unit 70, the control power supply circuit 81 supplies the control power supply to the control circuit 80 by the predetermined DC voltage obtained by converting the external power supply E by the power conversion circuit 71, and the charging circuit 72 supplies the storage battery. B2 is charged, and the voltage generation circuit 77 for the smoke detector supplies the operating voltage to the smoke detector 78. Further, in the blinking induction sound control unit 70, in the event of a power failure, the control power supply circuit 81 supplies the control power supply to the control circuit 80 by the DC voltage discharged from the storage battery B2, and the discharge circuit 73 and the voltage generation circuit 77 for the smoke detector 77. Is operational.

The blinking induction sound control unit 70 controls blinking and output of the induction sound according to the operation signal from the signal device input to the operation signal processing circuit 64.

The control circuit 80 of the blinking induction sound control unit 70 monitors the voltage detected by the voltage detection unit 79, and determines whether or not the induction stop signal from the smoke detector 78 or the second display control unit 50 has been input. ..

Next, the operation sequence of the display device 10 will be described with reference to the timing chart of FIG.

The operation signal (signal device) is a signal input to the operation signal processing circuits 64 and 83 from the signal device linked to the automatic fire alarm. When the signal is "none", it is defined. In the control circuits 58 and 80 that input the signals processed by the operation signal processing circuits 64 and 83, when the signal is "yes" for the operation signal processing circuits 64 and 83, the induction signal is not input and the signal is "no". Occasionally, it is determined that there is an input of an induction signal and processed.

The induction stop signal (automatic fire alarm contact) is a signal input from the automatic fire alarm to the contact control terminal 56, and is a signal from the control circuit 84 directly above the blinking induction sound control unit 70 in the same display device 10. Also included, in FIG. 8, no signal is defined as High and with signal is defined as Low.

In FIG. 8, the smoke detector 78 is defined as High when the smoke detector 78 that senses smoke is operating, and Low when the smoke detector 78 that does not detect smoke is not operating.

The guidance stop signal (stopping the "blinking guidance sound" on the immediately above floor) is a signal that stops the blinking guidance sound operation of the display device 10 on the immediately above floor when the smoke detector 78 connected to the blinking guidance sound control unit 70 operates. In FIG. 8, the normal time without a signal is defined as High, and the time with a signal is defined as Low.

The guidance stop signal (displayed with "x" on the immediately above floor) is marked with "x" on the second display unit 40 of the display device 10 on the immediately above floor when the contact control terminal 56 connected to the second display control unit 50 operates. In FIG. 8, when there is no signal, it is defined as High, and when there is a signal, it is defined as Low.

Immediately before timing t1, in the normal state, the operation signal is "Yes" (non-induction), there is no induction stop signal (automatic fire alarm contact), the smoke detector 78 does not operate, and the induction stop signal (directly above). There is no floor "blinking guidance sound" stop) and guidance stop signal (immediately above floor "blinking guidance sound" stop), the blinking display unit 13 and the guidance sound output unit 14 are stopped, and the second display unit 40 is in a non-display state.

When the guidance stop signal (automatic fire alarm contact) from the automatic fire alarm is input at the timing t1, the display of the “x” mark is started on the second display unit 40 and the guide is directed to the display device 10 on the immediately above floor. Outputs a stop signal (displayed with an "x" on the upper floor). As a result, even in the display device 10 on the immediately above floor, the “x” mark is displayed on the second display unit 40.

When the operation signal is switched from "yes" (non-induction) to "no" (induction) at timing t2, the blinking display unit 13 and the induction sound output unit 14 normally operate to actively guide evacuation. , Since the input of the induction stop signal (automatic fire alarm contact) from the automatic fire alarm is continued, the blinking display unit 13 and the induction sound output unit 14 do not operate.

When the guidance stop signal (automatic fire alarm contact) from the automatic fire alarm is no longer input at timing t3, the display of the "x" mark on the second display unit 40 is normally stopped, but the operation signal is "none". "(Induction) continues, and the automatic fire alarm has not returned to normal, so the second display unit 40 continues to display the" x "mark.

At timing t4, when the operation signal is switched from "no" (induction) to "yes" (non-induction), the automatic fire alarm is assumed to have returned to normal, and the "x" mark on the second display unit 40 is displayed. It also stops, and the output of the guidance stop signal to the floor directly above (indicated by the "x" mark on the floor directly above) also stops.

Further, when the operation signal is switched from "Yes" (non-induction) to "No" (induction) at the timing t5, the blinking display unit 13 and the induction sound output unit 14 operate, and the blinking and the induction sound are positive. Evacuation guidance is provided.

When the smoke detector 78 detects smoke and operates while the blinking display unit 13 and the induction sound output unit 14 are operating at the timing t6, the operation of the blinking display unit 13 and the induction sound output unit 14 is stopped. At the same time, the display of the “x” mark is started on the second display unit 40, and the guidance stop signal (display of the “x” mark on the directly above floor) is output to the display device 10 on the immediately above floor. As a result, even in the display device 10 on the immediately above floor, the “x” mark is displayed on the second display unit 40.

At timing t7, when the smoke detector 78 does not detect smoke and does not operate, the display of the "x" mark on the second display unit 40 is normally stopped, or the guidance stop signal to the direct upper floor (the direct upper floor "" The output of "x" mark) is stopped, but the operation signal continues to be "absent" (induction), and the automatic fire alarm has not returned to normal, so the "x" mark is displayed on the second display. Is continued, and the output of the guidance stop signal (indicated by "x" on the floor directly above) to the floor directly above is continued.

At timing t8, when the operation signal returns from "no" (induction) to "yes" (non-induction), the automatic fire alarm is assumed to have returned to normal, and the display of the "x" mark on the second display unit 40 is stopped. However, the output of the guidance stop signal to the floor directly above (indicated by the "x" mark on the floor directly above) is also stopped.

Further, FIG. 9 shows an operation sequence when the operation signal, which is an induction signal, and the induction stop signal are processed by the same processing circuit of the second display control unit 50.

When the operation signal is switched from "Yes" (non-induction) to "No" (induction) at the timing t11, the blinking display unit 13 and the guidance sound output unit 14 operate, and the blinking and the induction sound actively guide the evacuation. I do.

When the operation signal is switched from "no" (induction) to "yes" (non-induction) at the timing t12, the operation of the blinking display unit 13 and the induction sound output unit 14 is stopped.

Between the timings t11 and t12, the input of the guidance stop signal (automatic fire alarm contact) is processed only while the blinking display unit 13 and the guidance sound output unit 14 are operating. The guidance stop signal (automatic fire alarm contact) is not processed except while the blinking display unit 13 and the guidance sound output unit 14 are operating.

As a result, both signals can be processed even when the operation signal and the induction stop signal, which are the induction signals, are processed by the same processing circuit.

Then, in the display device 10, when the second display unit 40 is lit and displayed, the second light source 46 is controlled to change the brightness of the second display unit 40, so that the attractiveness of the second display unit 40 can be improved.

When the brightness of the second display unit 40 changes, the second display unit 40 is repeatedly turned on and off, so that the difference in brightness between when the second display unit 40 is turned on and when the light is turned off is large, and the attractiveness of the second display unit 40 can be improved.

When the brightness of the second display unit 40 changes, the display of the second display unit 40 may disappear by blinking the light and dark repeatedly by dimming control while maintaining the lighting state of the second display unit 40. The second display unit 40 can be displayed even in the dark, and the attractiveness of the second display unit 40 can be improved.

The blinking of the second display unit 40 is based on the first operation time T ₁ = 50 msec and the second operation time T ₂ = 450 msec, and is the same as the lighting time and the extinguishing time specified for the blinking of the blinking display unit 13. By doing so, the attractiveness of the second display unit 40 can be improved.

Further, the blinking cycle of the second display unit 40 is within the range of 0 <(n × T ₁ ) / (n × T ₁ + m × T ₂ ) ≦ 0.5, so that the blinking cycle is easily perceived. It is possible to make it easier to perceive and improve the attractiveness by setting the lighting cycle to which the discomfort due to the blinking is likely to be given even in the blinking.

Alternatively, the blinking cycle of the second display unit 40 is within the range of 0.5 ≦ (n × T ₁ ) / (n × T ₁ + m × T ₂ ) <1.0, so that blinking is easily perceived. The blinking cycle can be set, and even among the blinking, the lighting cycle that tends to cause discomfort due to blinking makes it easier to perceive and improves the attractiveness.

Further, in the display device 10, when the first display unit 30 and the second display unit 40 are displayed at the same time, the second display pattern 44 of the second display unit 40 is configured to maintain a chromatic color. , The visibility and attractiveness of the second display unit 40 can be improved.

Further, when the first display unit 30 and the second display unit 40 are displayed at the same time, the second display pattern 44 of the second display unit 40 overlaps with the first display pattern 34 of the first display unit 30 and becomes achromatic. In this case, when the brightness of the area where the second display pattern 44 of the second display unit 40 overlaps with the first display pattern 34 of the first display unit 30 and becomes achromatic is displayed only in A and the first display unit 30. Assuming that the brightness of the achromatic region of the first display pattern 34 is B, the visibility and attractiveness of the second display unit 40 can be improved due to the relationship of A> B. That is, in the relationship of A> B, the red color of the “x” mark of the second display pattern 44 (+ the white color of the first display unit 30)> the achromatic color (the red color of the “x” mark of the second display pattern 44 + the first The relationship is as follows: green of the display unit 30)> white of the first display unit 30> green of the first display unit 30. As a result, the achromatic color of the second display pattern 44 (red of the “x” mark of the second display pattern 44 + green of the first display unit 30) and the white color of the first display unit 30 are different in brightness, resulting in contrast. Is clarified, so that the visibility and attractiveness of the display of the "x" mark in the second display pattern 44 can be improved.

Alternatively, in some cases, the visibility and attractiveness of the second display unit 40 can be improved even in the relationship of A <B. In the relationship of A <B, the red color of the "x" mark of the second display pattern 44 (+ the white color of the first display unit 30)> the white color of the first display unit 30> the achromatic color (the "x" of the second display pattern 44). The relationship is as follows: red of the mark + green of the first display unit 30)> green of the first display unit 30. In this case, it can be realized by lowering the brightness of the green color by lowering the transmittance of the green color of the first display unit 30. Even in this case, the brightness between the achromatic color of the second display pattern 44 (red of the “x” mark of the second display pattern 44 + green of the first display unit 30) and the white color of the first display unit 30. Since the contrast becomes clear when the colors are different, the visibility and attractiveness of the display of the “x” mark in the second display pattern 44 can be improved.

Then, by displaying the second display unit 40 having such a configuration, it is possible to display the evacuees with more emphasis on whether or not the evacuation route is safe.

Further, in the display device 10, when the guidance signal is input, the blinking display unit 13 blinks and the guidance sound output unit 14 outputs the guidance sound, and when the guidance stop signal is input, the blinking display unit 13 blinks and induces. In addition to stopping the output of the guidance sound from the sound output unit 14, the guidance can be stopped by displaying the guidance stop on the second display unit arranged on the projection surface of the first display unit 30 for guidance display. ..

Even if the guidance signal is input while the guidance stop signal is input and the second display unit 40 is displayed, the blinking display unit 13 and the guidance sound output unit 14 continue to be stopped and the display of the second display unit is displayed. By continuing, the induction stop state can be maintained.

Even if the guidance stop signal is input to display the second display unit 40 and the guidance stop signal is not input while the guidance signal is being input, the automatic fire alarm has not returned to normal, so the second display The display of part 40 can be continued. Further, when the guidance stop signal and the guidance signal are no longer input, the display of the second display unit 40 can be stopped.

The display device is not limited to the guide light, and can be applied to, for example, a display device that displays whether or not a person or a vehicle can enter at a gate or the like.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

10 Display device
30 1st display unit
34 1st display pattern
40 2nd display
44 Second display pattern

Claims (3)

With a first display unit having a first display pattern including achromatic and chromatic areas;
With a second display unit arranged on the projection surface of the first display unit and having a chromatic second display pattern with a display different from that of the first display unit;
It is a display device equipped with
A display device characterized in that when the first display unit and the second display unit are displayed, the second display pattern of the second display unit maintains a chromatic color. With a first display unit having a first display pattern including achromatic and chromatic colors;
With a second display unit arranged on the projection surface of the first display unit and having a chromatic second display pattern with a display different from that of the first display unit;
It is a display device equipped with
Brightness of a region where the second display pattern of the second display unit becomes achromatic when the first display unit and the second display unit are displayed, which overlaps with the first display pattern of the first display unit. The display device is characterized in that it has a relationship of A> B, where A is A and the brightness of the achromatic region of the first display pattern is B when only the first display unit is displayed. With a first display unit having a first display pattern including achromatic and chromatic colors;
With a second display unit arranged on the projection surface of the first display unit and having a chromatic second display pattern with a display different from that of the first display unit;
It is a display device equipped with
Brightness of a region where the second display pattern of the second display unit becomes achromatic when the first display unit and the second display unit are displayed, which overlaps with the first display pattern of the first display unit. The display device is characterized in that it has a relationship of A <B, where A is A and the brightness of the achromatic region of the first display pattern is B when only the first display unit is displayed.

Images