JP5421557B2 - Guide light - Google Patents

Description

  The present invention relates to a guide light.

  Conventionally, various types of in-floor type guide lights have been provided, but this kind of guide lights are usually covered with a protective cover or the like because they are installed in, for example, a passage that can be stepped on by a person. Therefore, in order to check the state of the monitor lamp housed inside, the outer parts such as the protective cover and other frames have to be removed, which is not convenient.

  Therefore, in order to improve convenience, it is conceivable to provide a monitor structure on the outer parts such as a frame, but in this case, it is necessary to prevent the intrusion of dust from the protective structure of the monitor structure part and the part, There is a problem that the structure becomes complicated and the cost increases.

  In addition, it has been proposed that a monitor lamp is arranged in the gap between the frame and the display plate or between the frame and the light guide plate so that the monitor lamp can be seen from a direction perpendicular to the floor surface. As a result, the appearance aesthetics are impaired.

Furthermore, in recent years, there has also been proposed a system in which the state of the monitor lamp can be confirmed using a remote control transmitter in consideration of the above problems (see, for example, Patent Document 1). This guide light uses a material having a high light transmittance as a material of the display board, and by disposing the monitor lamp close to the display board, the lamp light transmitted through the display board can be visually recognized from the outside. Yes.
Japanese Unexamined Patent Publication No. 2007-250267 (paragraph [0019] -paragraph [0040] and FIGS. 1 to 4)

  Although the guide light shown in the above-mentioned Patent Document 1 can check the state of the monitor lamp without removing the outer parts such as the protective cover and the frame, the exit surface of the monitor lamp faces the display plate. (In other words, since the monitor lamp is arranged so that the lamp axis is substantially orthogonal to the display panel), the emitted light is diffused, but the lamp light cannot be visually recognized unless it is close to the guide light. As a result, there are a plurality of guide lights. In some cases, the confirmation work was time-consuming.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a guide light with improved convenience, appearance aesthetics, and workability while suppressing an increase in cost. .

The invention of claim 1 is a guide lamp embedded in a floor surface, comprising a light guide plate that irradiates light from a light source incident from an end face forward, and an opening portion of a frame body disposed forward. disposed in front of the light guide plate so as to face a display panel for performing predetermined display by transmitting light from the light guide plate, a protective cover of translucent disposed in front of the display panel to protect the table示板, and a monitor lamp for performing an operation display, protective cover, at least a portion of the light guide plate projecting portion projecting outward is formed than the light guide plate, passes through the lamp light Izuru Cho section of the monitor lamp as is irradiated from the opening of the frame body obliquely forward, characterized in that the monitor lamp is located.

  The invention of claim 2 is characterized in that a reflector for reflecting the lamp light is provided so that at least a part of the lamp light passes through the inside of the protective cover and is irradiated obliquely forward from the opening of the frame. And

  According to the first aspect of the present invention, since the monitor lamp can be viewed from an oblique direction, the status of the monitor lamp can be confirmed even from a position away from the guide lamp. Even so, the confirmation time can be shortened, and workability can be improved as compared with the guide light shown in Patent Document 1. Further, it is not necessary to remove outer parts such as a protective cover and a frame as in the conventional example, and further, for example, other remote control operations can be performed simultaneously while checking the monitor lamp, so that convenience is improved. In addition, the frame can be made simpler than the case where the monitor lamp is provided on an outer part such as a frame, so that the cost increase can be suppressed, and further, between the frame and the display plate or between the frame and the light guide plate. Since there is no need to provide a gap, it is difficult to see the internal structure and the appearance is improved.

  According to the second aspect of the present invention, even if the direct light from the monitor lamp cannot be visually recognized due to variations during manufacturing of parts or variations in fitting during construction, the reflected light from the reflector can be visually recognized. There is an effect that the state of the monitor lamp can be surely confirmed.

  Embodiments of a guide light according to the present invention will be described below with reference to FIGS. The guide lamp according to the present invention is embedded in a construction surface such as a floor surface and used as a sign for evacuation guidance. In the following description, unless otherwise specified, the direction of the arrow ab in FIG. 4A is the vertical direction, the direction of the arrow cd is the front-rear direction, and the direction of the arrow ef is the left-right direction. To do.

  As shown in FIG. 3, the guide light A of the present embodiment includes a frame 1, a packing 2, a protective cover 3, a display plate 4, a light guide plate 5, a reflection plate 6, a base 7, and a lamp body. 8 and is housed in, for example, a rectangular box-shaped embedding box 9 embedded in the floor surface.

  The frame body 1 is made of, for example, stainless steel and is formed in a horizontally long rectangular frame shape having a rectangular opening 1a in the center, and a screw insertion hole through which a fixing screw 10 is inserted into the outer peripheral portion of the frame body 1. A plurality (six in this embodiment) of 1b are provided at predetermined positions. Here, the opening dimension of the opening 1a is set to be approximately the same as the outer dimension of the upper cover 3a constituting the protective cover 3 to be described later. In the assembled state, the upper surface of the upper cover 3a is directed upward through the opening 1a. It is exposed (see FIG. 1).

  The packing 2 is, for example, a synthetic resin molded product, and is formed in a rectangular frame shape having substantially the same outer dimensions as the frame body 1, and an opening portion 2 a that opens to approximately the same size as the opening portion 1 a is provided in the center portion. It has been. Similarly, screw insertion holes 2b through which the fixing screws 10 are inserted are respectively penetrated at portions corresponding to the respective screw insertion holes 1b.

  The protective cover 3 is made of, for example, transparent tempered glass, and is formed in a double structure with a substantially rectangular plate-like upper cover 3a and lower cover 3b. The upper cover 3a is formed to have substantially the same outer dimensions as the light guide plate 5 described later, the lower cover 3b is longer and wider than the upper cover 3a, and the overhanging portion 3c projects outward from the light guide plate 5. Are integrally formed over the entire circumference.

  The display board 4 is, for example, a synthetic resin molded product, is formed in a horizontally long substantially rectangular plate shape, and a display pattern P configured by a pictogram simulating an arrow or a person pointing in the left-right direction on the upper surface of the display board 4. Is formed by printing. In the present embodiment, the outer dimension of the display plate 4 is set to be substantially the same as the opening size of the opening 1a of the frame 1 so that the entire upper surface of the display plate 4 can be viewed from above. ing.

  The light guide plate 5 is, for example, a transparent acrylic resin molded product, and is set to have substantially the same dimensions as the outer dimensions of the display plate 4 described above, and is disposed below the display plate 4 in an assembled state. Light source blocks 11, 11 are arranged opposite to each other in the assembled state on the left and right end surfaces of the light guide plate 5, and the light emitted from each light source block 11 is inside the light guide plate 5. And is irradiated upward (that is, on the display panel 4 side).

  The reflection plate 6 has a horizontally long, substantially rectangular plate shape, and both end portions in the front-rear direction are bent upward, and are arranged so as to hold the light guide plate 5 from below. In addition, light receiving holes 6a and 6a are provided in the main surface of the reflecting plate 6 at point-symmetric positions. Note that one of the light receiving holes 6a is arranged in a shape facing a light receiving element 19 of a remote control light receiving block 23 to be described later in an assembled state, and a wireless signal (for example, infrared light) transmitted from a remote control transmitter (not shown). Etc.) can be received. Here, since the light receiving holes 6a, 6a are provided at point-symmetrical positions, even if the reflecting plate 6 is mounted with the left and right sides switched, one of the light receiving holes 6a faces the light receiving element 19. Therefore, it is possible to reliably receive a wireless signal and to prevent a mounting error of the reflector 6.

  The base 7 is a case for storing electrical components to be described later, and a power supply terminal block 22 and a storage battery 24 for supplying power in the event of a power failure are provided inside a horizontally long rectangular box-shaped base body 7a opened upward. Or the lighting control block 12 is accommodated. The lighting control block 12 has a self-checking function for checking the lighting circuit (not shown), the status of the cold cathode fluorescent lamp 21 and the storage battery 24 constituting the light source block 11 (for example, the charging state of the storage battery 24). A control circuit for controlling the lighting circuit is incorporated. Further, the light source blocks 11 and 11 are disposed at both left and right ends of the base body 7a so as to face each other. As described above, in the assembled state, each light source block 11 is disposed at both the left and right ends of the light guide plate 5, respectively. Arranged to face each other. Further, a switch block 13 and a remote control light receiving block 23 attached to the mounting bracket 20 are also housed inside the base body 7a.

  As shown in FIG. 1, the mounting bracket 20 has mounting pieces 20b and 20c formed in a substantially L shape, which are integrally bent via a connecting piece 20a, and the other mounting piece 20c is a connecting piece. It is bent so as to be inclined obliquely upward with respect to 20a. Further, a light receiving hole 20e is provided in a portion corresponding to the light receiving element 19 in the mounting piece 20b, and monitor lamps 15 and 16 constituting the switch block 13 are provided in a portion corresponding to the switch block 13 in the mounting piece 20c. A notch 20f that exposes the inspection switch 17 and the self-inspection switch 18 is provided (see FIG. 4B). Here, the switch block 13 is attached to the mounting piece 20c using a fixing screw as shown in FIG. 1, and the remote control light receiving block 23 is attached to the mounting piece 20b using a fixing screw.

  As shown in FIG. 3, the light source block 11 includes a lamp holder 25 formed in a substantially U-shape and a straight tube type cold cathode fluorescent lamp 21, and each cold cathode fluorescent lamp 21 includes an electric wire. 26 are respectively connected to the output terminals of the lighting control block 12 (see FIG. 5).

  As shown in FIG. 3, the lamp body 8 has a horizontally long, substantially rectangular box shape with an upper surface opened, and an opening edge of the lamp body 8 is provided with a flange portion 8a extending outward. ing. Further, the flange portion 8a is provided with screw holes 8b into which the fixing screws 10 are screwed in portions corresponding to the screw insertion holes 1b of the frame body 1 and the screw insertion holes 2b of the packing 2, respectively.

  Next, the circuit configuration of the guide light A of the present embodiment will be described. FIG. 5 shows a schematic block diagram of the guide lamp A of the present embodiment, and the lighting control block 12 is connected with a power terminal block 22, a storage battery 24, a remote control light receiving block 23, a switch block 13 and a cold cathode fluorescent lamp 21, respectively. Yes. Here, the lighting control block 12 generates operation power from the commercial power supply AC supplied from the power supply terminal block 22 at normal times, charges the storage battery 24 while supplying power to the lighting circuit (not shown), and at the time of power failure. An operating power source is generated from the discharged power from the storage battery 24, and power is supplied to the lighting circuit. When the lighting power is supplied to each cold cathode fluorescent lamp 21 from the lighting circuit, each cold cathode fluorescent lamp 21 is turned on. The power supply terminal block 22 is provided with a regular turn-off switch 22a. When an inspector or the like presses the regular turn-off switch 22a, the lighting control block 12 cuts off the supply of the commercial power supply AC to the lighting circuit. As a result, the cold cathode fluorescent lamps 21 and 21 of both the light source blocks 11 and 11 are turned off.

  The switch block 13 includes monitor lamps 15 and 16, a check switch 17, and a self-check switch 18, and the monitor lamp 15 is made of, for example, a red LED and is lit, extinguished or blinking according to the state of the cold cathode fluorescent lamp 21. To do. For example, when the cold-cathode fluorescent lamp 21 is normal, the monitor lamp 15 is turned off, is turned on when an abnormality such as detachment or breakage of the lamp, and further blinks when the lamp replacement time has elapsed. On the other hand, the monitor lamp 16 is made of, for example, a green LED, and is turned on, turned off, or blinked according to the state of the storage battery 24. For example, the monitor lamp 16 is turned on when the storage battery 24 is normal, is turned off when the battery is disconnected, and blinks when the battery replacement time has passed.

  The inspection switch 17 is, for example, a momentary type push button switch, and is lit in an emergency state only while this switch is being pressed. That is, while the inspection switch 17 is being pressed, the lighting control block 12 stops the supply of the commercial power supply AC to the lighting circuit, and the cold cathode fluorescent lamp 21 is lit based on the discharge power from the storage battery 24. . Further, the self-inspection switch 18 is, for example, a momentary type pushbutton switch. When the self-inspection switch 18 is pressed, the lighting control block 12 cuts off the supply of the commercial power supply AC and the storage battery 24 uses the cold cathode fluorescent lamp 21. Is lit for emergency at the rated time, and after the rated time has elapsed, it is automatically switched to regular lighting (that is, the lighting state by the commercial power supply AC) (hereinafter referred to as self-inspection). At this time, the lighting control block 12 also checks the states of the cold cathode fluorescent lamp 21 and the storage battery 24 and displays the inspection result via the monitor lamps 15 and 16 described above.

  The remote control light receiving block 23 includes a light receiving element 19 for receiving a wireless signal transmitted from a remote control transmitter (not shown). When the light receiving element 19 receives the wireless signal, the remote control light receiving block 23 corresponds to the received wireless signal. A signal is input to the lighting control block 12. In the lighting control block 12, various control operations are executed in accordance with the input signal. For example, when an inspection switch (not shown) provided in the remote control transmitter is pressed, a wireless signal corresponding to the inspection switch is transmitted from the remote control transmitter (a signal corresponding to self-inspection in the present embodiment) and received. When the element 19 receives this wireless signal, the lighting control block 12 performs the self-check described above. In the guide light A of the present embodiment, since the remote control light receiving block 23 is disposed below the reflecting plate 6, the light receiving hole 6 a is provided in the portion corresponding to the light receiving element 19 in the reflecting plate 6. In the state, the reflector 6, the mounting bracket 20, and the remote control light receiving block 23 are arranged so that the center axes of the light receiving hole 6 a, the light receiving hole 20 e provided in the mounting bracket 20, and the light receiving element 19 substantially coincide with each other. .

  Next, the assembly procedure of the guide light A will be described. In the following description, the light source block 11, the lighting control block 12, the power terminal block 22, the storage battery 24, the switch block 13 and the remote control light receiving block 23 are stored in the base 7 in advance, and the electric wires (not shown) are connected between the electrical components. Will be described as being connected in advance. First, the lamp body 8 is housed in the embedded box 9 embedded in the floor, and the power line 14 introduced into the embedded box 9 through the electric wire hole 9a is passed through the electric wire hole (not shown). It is introduced into the main body 8. Next, after the base 7 is housed in the lamp body 8, the power line 14 is connected to the input end of the power terminal block 22. After that, the reflective plate 6, the light guide plate 5, the display plate 4, and the protective cover 3 are stacked in this order on the base 7. At this time, the reflecting plate 6 is disposed so that one light receiving hole 6 a faces the light receiving element 19 of the remote control light receiving block 23. Finally, the packing 2 and the frame body 1 are arranged in this order from above, and the fixing screws 10 inserted through the screw insertion holes 1b and 2b are screwed into the corresponding screw holes 8b, respectively. Completion (see FIG. 4A).

  Here, FIG. 1 is a cross-sectional view showing an example of the assembly state of the guide light A, and the light receiving element 19 constituting the remote control light receiving block 23 is arranged so that the light receiving surface faces the light receiving holes 6a and 20e. On the other hand, in the monitor lamps 15 and 16 (only the monitor lamp 16 is shown in FIG. 1) constituting the switch block 13, the mounting piece 20c for mounting the switch block 13 is inclined with respect to the connecting piece 20a as described above. Therefore, light emitted from the monitor lamps 15 and 16 (hereinafter referred to as direct light) is emitted in an oblique direction, but in the present embodiment, the lower cover 3b of the protective cover 3 is disposed outside the light guide plate 5. Therefore, the direct light from the monitor lamps 15 and 16 is transmitted obliquely upward from the opening 1a of the frame body 1 (in FIG. 1). In the direction of arrow a). The monitor lamps 15 and 16 used in the present embodiment are configured such that direct light diffuses at an angle of θ1 (θ1 = 12.4 °) around the arrow a, and the maximum visible angle is from the floor surface. θ2 (θ2 = 75 °).

  Thus, according to the guide light A shown in FIG. 1, the monitor lamps 15 and 16 can be viewed from an oblique direction so that the status of the monitor lamps 15 and 16 can be confirmed even from a position away from the guide light A. Therefore, even when there are a plurality of guide lights A, the confirmation time can be shortened, and workability can be improved as compared with the guide lights shown in Patent Document 1. Further, it is not necessary to remove the outer parts such as the protective cover and the frame as in the conventional example, and further, for example, remote control operation can be performed simultaneously while checking the monitor lamps 15 and 16, so that convenience is improved. In addition, since the frame 1 can have a simple structure as compared with the case where the monitor lamp is provided in an outer part such as a frame, the increase in cost can be suppressed, and furthermore, between the frame and the display plate or between the frame and the light guide plate. Since it is not necessary to provide a gap, the internal structure becomes difficult to see and the appearance aesthetics are improved.

  Here, FIG. 2 is a cross-sectional view showing another example of the assembly state of the guide light A in the present embodiment. For example, due to a manufacturing error of the protection cover 3, the end surface of the upper cover 3a constituting the protection cover 3 in the assembly state 3d is located on the inner side (left side in FIG. 2) than the regular position (position shown in FIG. 1). In this case, the direct light from the monitor lamps 15 and 16 (only the monitor lamp 16 is shown in FIG. 2) is irradiated in the direction of the broken line b in the figure, but as shown in FIG. 2, the end face 3d of the upper cover 3a. The lamp light cannot be confirmed from above because it is blocked by. Therefore, in the present embodiment, the reflecting piece 20d (reflecting plate) is provided at the tip of the mounting piece 20c so that the lamp light of the monitor lamps 15 and 16 can be confirmed even if there is a manufacturing error of the protective cover 3. (See FIGS. 6 and 7).

  First, FIG. 6 shows a case where the protective cover 3 is manufactured with dimensions without manufacturing errors (that is, as in FIG. 1). In this case, the monitor lamps 15 and 16 (only the monitor lamp 16 is shown in FIG. 6). Direct light is irradiated obliquely upward (in the direction of arrow a in FIG. 6). In this case as well, similar to the guide light A shown in FIG. 1, the direct light from the monitor lamps 15 and 16 diffuses at an angle of θ1 (θ1 = 12.4 °) around the arrow a. In addition, the maximum visible angle is θ2 (θ2 = 75 °) from the floor surface. Further, a part of the lamp light of the monitor lamps 15 and 16 is reflected by the reflection piece 20d, passes through the inside of the protective cover 3, and obliquely above the opening 1a of the frame 1 (indicated by the arrow c in FIG. 6). Direction). The reflected light is diffused at an angle of θ3 (θ3 = 13.5 °) around the arrow c, and the maximum angle at which the reflected light can be visually recognized is θ4 (θ4 = 47 °) from the floor surface. ). That is, in the case of the present embodiment, both direct light and reflected light of the monitor lamps 15 and 16 can be visually recognized.

  On the other hand, FIG. 7 shows a case where the protective cover 3 is manufactured with dimensions including manufacturing errors. In this case, the direct light from the monitor lamps 15 and 16 is blocked by the end face 3d of the upper cover 3a as in the case of FIG. And cannot be seen from above. However, a part of the lamp light of the monitor lamps 15 and 16 is reflected by the reflecting piece 20d, passes through the inside of the protective cover 3, and obliquely above the opening 1a of the frame 1 (indicated by the arrow c in FIG. 7). Direction). That is, in the present embodiment, the direct light from the monitor lamps 15 and 16 cannot be visually recognized, but the reflected light can be visually recognized.

  Here, the reflection piece 20d is disposed above (frontward) the monitor lamps 15 and 16, and the reflected light (solid line c in FIG. 7) of the monitor lamps 15 and 16 is the display plate 4 and the reflection plate 6. Is reflected at an angle that does not interfere with the light. The reflected light is reflected at an angle shallower than the direct light (broken line a in FIG. 7) described above and at an angle not hitting the end surface 3d of the upper cover 3a. That is, by reflecting the light so as to satisfy all the above conditions, the lamp light can be visually recognized from the outside, and the lamp light can be visually recognized even from a position far from the direct light.

  Thus, according to the guide light A shown in FIGS. 6 and 7, direct light from the monitor lamps 15 and 16 due to variations in manufacturing parts and fitting variations in construction (for example, manufacturing error of the protective cover 3). Even if it is not visible, since the reflected light from the reflecting piece 20d can be visually recognized, the state of the monitor lamps 15 and 16 can be confirmed reliably.

  Here, FIG. 8 shows a case where self-inspection is performed on the guide light A of the present embodiment using the remote control transmitter 27, and an area d in the figure is a direct light from a monitor lamp (not shown). A visually recognizable region and a region e indicate regions where the reflected light can be visually recognized. Assuming that the horizontal distance L from the guide light A to the inspector X is 1.5 m and the height H of the inspector X is 1.6 m, the angle at which the inspector X looks down at the monitor portion of the guide light A Since θ5≈47 °, it substantially coincides with θ4 described above, and the inspector X can see the reflected light of the monitor lamp. In this case, the remote control operation can be performed while checking the monitor lamp, so that there is an advantage that convenience is improved.

  In this embodiment, the protective cover 3 is formed in a double structure with the upper cover 3a and the lower cover 3b. However, the structure of the protective cover is not limited to this embodiment, and the portion on the light guide plate side. If the overhang | projection part projected outside the said light-guide plate is provided in this, it may be integral. Further, the distance L from the inspector X to the guide light A is an example, and the distance L may be appropriately set according to the layout of the guide light, for example.

It is sectional drawing which can abbreviate | omit a part of the guide light of this embodiment. It is another sectional view which can be omitted partially. It is an exploded perspective view same as the above. FIG. 4A is a perspective view, and FIG. It is a schematic block diagram same as the above. It is another sectional drawing which can be omitted partially. It is another sectional drawing which abbreviate | omits a part same as the above. It is operation | movement explanatory drawing at the time of operating a remote control same as the above.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Frame 1a Opening part 3 Protective cover 3c Overhang | projection part 4 Display board 5 Light guide plate 16 Monitor lamp A Guide light

Claims (2)

A guide light embedded in the floor,
A light guide plate to irradiate the light from the light source which enters from the end face to the front, arranged in front of the light guide plate so as to face the opening of the frame body disposed in front, by transmitting light from the light guide plate comprising a display panel for performing predetermined display, a protective cover of translucent protecting the display panel is disposed in front of the display panel, and a monitor lamp for performing an operation display,
The protective cover, the projecting portion that projects outward from the light guide plate to at least a portion of the light guide plate is formed, the monitor lamp lamp light is transmitted through the projecting opening of the frame as is irradiated obliquely forward from the parts, guide lights, characterized in that the monitor lamp is disposed.   The reflector plate for reflecting the lamp light is provided so that at least a part of the lamp light passes through the inside of the protective cover and is irradiated obliquely forward from the opening of the frame body. Item 1. The guide light according to item 1.

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