KR102725541B1 - Light-emitting bollard with solar panel - Google Patents

Abstract

Disclosed are a light emitting bollard having a solar panel and a control method thereof. The light-emitting bollard comprises: a pillar unit installed to protrude upward from the ground; and a lighting unit fixed to an upper portion of the pillar unit. The lighting unit comprises: a light-transmitting cover mounted on an upper end of the pillar unit; an upper surface cap of a transparent material disposed to cover an open upper portion of the light transmitting cover to form a body of the lighting unit; a shielding plate separating an inner space of the body of the lighting unit in a vertical direction; a solar panel disposed on an upper portion of the shielding plate to generate power using sunlight passing through the upper surface cap; a rechargeable battery storing the power generated by the solar panel; a first type light source unit disposed below the shielding plate to face downward and turned on using the power charged in the rechargeable battery; and an upwardly convex curved surface reflection unit disposed below the first type light source unit to reflect light emitted downward from the first type light source unit.

Description

Light-emitting bollard with solar panel

The present invention relates to a luminous bollard equipped with a solar panel and a method for controlling the same.

Bollards are generally obstacles installed on pedestrian roads or lawns to prevent vehicles from entering. These bollards are made of strong materials such as iron, stone, and concrete and are installed in the shape of pillars so that they are not easily damaged even when vehicles collide with them.

However, there were frequent accidents in which vehicles or pedestrians did not check whether the bollard was installed and crashed into the bollard, resulting in damage to the bollard or injury to pedestrians.

To solve these problems, previously installed bollards were installed by attaching luminous paint or fluorescent colored paper to the surface of the bollards so that they could be easily identified. However, even with these bollards, there was a problem in that the identification was reduced in places where there was insufficient light, and the desired results could not be achieved.

In addition, recently, luminous bollards with built-in light sources are being installed as landscape lighting to create a more ambience in areas with a lot of people, such as tourist attractions, parks, downtown squares, and stairways, or as visual guidance along pedestrian walkways.

However, when installing luminous bollards as landscape lighting, there was a problem in that installation and construction costs were high because power cables had to be installed to supply operating power.

In addition, there is the inconvenience of having to manually control the turning on and off of the luminous bollards, and if the luminous bollards are not turned on at an appropriate time, visibility is not secured, which can threaten the safety of pedestrians, and if they are not turned off at an appropriate time, there is also the problem of unnecessary power consumption.

The prior art described below with reference to the aforementioned background art and related drawings is technical information that the inventor possessed for deriving the present invention or acquired in the process of deriving the present invention, and cannot necessarily be said to be a publicly known technology disclosed to the general public prior to the application of the present invention.

Korean Public Utility Model No. 20-2009-0007740

The present invention provides a light-emitting bollard equipped with a solar panel, which can secure visibility by emitting light for a long period of time while being easy to install, by using electric energy charged by sunlight during the day to turn on a light source at night and by allowing a light-accumulating portion equipped on a columnar body to emit light even after the light source is turned off, and a method for controlling the same.

The present invention provides a light-emitting bollard equipped with a solar panel and a method for controlling the same, which uses electric energy charged by sunlight during the day to light a first type light source with bright brightness at night, and after the first type light source is turned off due to insufficient remaining power, a second type light source with low brightness that consumes less power is turned on for a long period of time, thereby emitting light for a long period of time even in a situation where the remaining power is insufficient, thereby ensuring visibility of the bollard.

The present invention provides a light-emitting bollard equipped with a solar panel and a control method thereof, which enables efficient use of electric energy by appropriately sequencing the operation timing of various light-emitting means equipped in the light-emitting bollard and allowing an appropriate type of light-emitting means to adaptively and selectively emit light according to the remaining amount of electric energy currently secured.

Other problems to be solved by the present invention can be easily understood through the following explanation.

According to one aspect of the present invention, there is provided a lighting device comprising: a pillar part installed to protrude upward from the ground; and a lighting unit fixed to an upper portion of the pillar part, wherein the lighting unit comprises: a light-transmitting cover mounted on an upper portion of the pillar part; an upper cap made of a transparent material arranged to cover an open upper portion of the light-transmitting cover to form a body of the lighting unit; a cover plate separating an internal space of the body of the lighting unit in a vertical direction; a solar panel arranged on an upper portion of the cover plate to generate electricity using sunlight passing through the upper cap; a rechargeable battery arranged to store electricity generated by the solar panel; a first type light source part arranged on a lower portion of the cover plate so as to face downward and to be lit using electricity charged in the rechargeable battery; And a light-emitting bollard is provided, which includes a curved reflector having an upwardly convex shape disposed below the first type light source to reflect light emitted downward from the first type light source, wherein the light emitted from the first type light source and the light reflected by the curved reflector are transmitted to the outside through a side region of the light-transmitting cover positioned below the cover plate.

On the circumference of the above pillar, a light-absorbing portion is formed in a ring shape around the outer periphery of the pillar with a predetermined width. The light-absorbing portion may be formed of a light-absorbing pigment or light-absorbing sheet that absorbs and stores light internally and has the property of emitting and emitting light.

A rough pattern having an angle that refracts light emitted from the first type light source and transmitted through the light transmitting cover toward the light-accumulating portion may be formed on a portion of the surface of the light-emitting cover.

The device may further include a second type light source unit positioned on the upper portion of the cover so as to face upward and lit using power charged in the rechargeable battery, wherein the second type light source unit may be configured to operate with relatively lower brightness and relatively lower power consumption compared to the first type light source unit.

One side of the above lighting unit is provided with an operation control button, and by referring to setting information regarding a pre-stored manual setting mode, the control unit can control the first type light source unit to be turned on and off at a time according to the setting information corresponding to the number of times the operation control button is pressed.

The control unit controls the first type light source unit and the second type light source unit to operate according to a preset adaptive control mode, and according to the adaptive control mode, the control unit controls the first type light source unit to turn on at a preset time, and then, when the remaining amount of charge power stored in the rechargeable battery reaches a preset first threshold value, controls the first type light source unit to turn off, and controls the second type light source unit to turn on, and then, when the remaining amount of charge power stored in the rechargeable battery reaches a preset second threshold value, controls the second type light source unit to turn off.

The control unit controls the first type light source unit and the second type light source unit to operate according to a preset adaptive control mode, wherein, according to the adaptive control mode, the control unit controls the first type light source unit to be turned on at a preset time, and then, when the remaining charge power stored in the rechargeable battery reaches a preset first threshold value, controls the first type light source unit to be turned off, and when a preset time elapses, controls the second type light source unit to be turned on, and then, when the remaining charge power stored in the rechargeable battery reaches a preset second threshold value, controls the second type light source unit to be turned off, wherein the preset time may be designated as a statistical time required until the light-emitting portion decreases below a preset brightness after the first type light source unit is turned off.

The above top cap may be mounted to be coupled with a support to close the open top of the light-emitting cover, or may be directly coupled with the light-emitting cover to close the open top of the light-emitting cover.

According to another aspect of the present invention, a computer program stored in a computer-readable medium is provided for performing a method for controlling the operation of a light-emitting bollard, wherein the computer program causes a computer to perform the following steps, wherein the steps include: a step of controlling a first type light source unit to be turned on at a predetermined time; a step of controlling the first type light source unit to be turned off and a second type light source unit to be turned on when the remaining amount of charge power stored in a rechargeable battery reaches a predetermined first threshold; and a step of controlling the second type light source unit to be turned off when the remaining amount of charge power stored in the rechargeable battery reaches a predetermined second threshold. Here, the light-emitting bollard may include a pillar unit installed to protrude upward from the ground; and a lighting unit fixed to an upper portion of the pillar unit. The lighting unit may include: a light-transmitting cover mounted on an upper end of the pillar unit; an upper cap made of a transparent material arranged to cover an open upper portion of the light-transmitting cover to form a body of the lighting unit; The lighting unit comprises: a cover plate that vertically separates the internal space of the body; a solar panel disposed on an upper portion of the cover plate, the solar panel generating electricity using sunlight passing through the upper surface cap; the rechargeable battery storing the electricity generated by the solar panel; a first type light source portion disposed on a lower portion of the cover plate so as to face downward, the first type light source portion being lit using electricity charged in the rechargeable battery; a curved reflection portion having an upward convex shape disposed on a lower portion of the first type light source portion to reflect light emitted downward from the first type light source portion; and a second type light source portion disposed on an upper portion of the cover plate so as to face upward, the second type light source portion being lit using electricity charged in the rechargeable battery, wherein the second type light source portion can be configured to operate with relatively lower brightness and relatively lower power consumption than the first type light source portion.

According to another aspect of the present invention, a computer program stored in a computer-readable medium is provided for performing a method for controlling the operation of a light-emitting bollard, wherein the computer program causes a computer to perform the following steps, wherein the steps include: a step of controlling a first type light source unit to be turned on at a predetermined time; a step of controlling the first type light source unit to be turned off when the remaining charge power stored in a rechargeable battery reaches a predetermined first threshold value; a step of controlling the second type light source unit to be turned on after a predetermined time has elapsed; and a step of controlling the second type light source unit to be turned off when the remaining charge power stored in the rechargeable battery reaches a predetermined second threshold value. Here, the light-emitting bollard may include a pillar unit installed to protrude upward from the ground; and a lighting unit fixed to an upper portion of the pillar unit. The lighting unit may include: a light-transmitting cover mounted on an upper end of the pillar unit; an upper cap made of a transparent material arranged to cover an open upper portion of the light-transmitting cover to form a body of the lighting unit; A cover plate that vertically separates the internal space of the body of the lighting unit; a solar panel disposed on an upper portion of the cover plate and generating electricity using sunlight passing through the upper surface cap; the rechargeable battery that stores the electricity generated by the solar panel; a first type light source portion disposed on a lower portion of the cover plate so as to face downward and lit using electricity charged in the rechargeable battery; a curved reflector having an upward convex shape disposed on a lower portion of the first type light source portion to reflect light emitted downward from the first type light source portion; And a second type light source part which is arranged on the upper part of the cover so as to face upward and is lit using power charged in the rechargeable battery, wherein the second type light source part is configured to operate with relatively lower brightness and relatively lower power consumption compared to the first type light source part, and a light-absorbing part is formed on the peripheral surface of the pillar part so as to have a predetermined width and to circle the outer periphery of the pillar part in a ring shape, and the predetermined time can be designated as a statistical time required until the light-absorbing part, which emits light, is reduced to below the predetermined brightness after the first type light source part is turned off.

Other aspects, features and advantages other than those described above will become apparent from the following drawings, claims and detailed description of the invention.

According to an embodiment of the present invention, a light source is turned on at night using electric energy charged using sunlight during the day, and a light-absorbing portion provided in a columnar body emits light even after the light source is turned off, thereby enabling easy installation while emitting light for a long period of time to ensure visibility.

In addition, the first type light source with bright brightness is turned on at night using electric energy charged using sunlight during the day, and after the first type light source is turned off due to insufficient remaining power, the second type light source with low brightness and low power consumption is turned on for a long period of time, thereby emitting light for a long period of time even in a situation where the remaining power is insufficient, thereby ensuring visibility of the bollard.

In addition, the present invention provides a light-emitting bollard equipped with a solar panel and a method for controlling the same, which enables efficient use of electric energy by appropriately sequencing the operation timing of various light-emitting means equipped on the light-emitting bollard and allowing an appropriate type of light-emitting means to adaptively and selectively emit light according to the remaining amount of electric energy currently secured.

The effects obtainable from the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art to which the present invention belongs from the description below.

Figure 1 is an external view of a light-emitting bollard according to one embodiment of the present invention.
FIG. 2 is an exploded perspective view showing a configuration arranged inside a light-emitting cover of a light-emitting bollard according to one embodiment of the present invention.
FIG. 3 is a drawing illustrating the arrangement shape of a first type light source unit according to one embodiment of the present invention.
FIGS. 4 and 5 are drawings for explaining the light-emitting and light-accumulating operations of a light-emitting bollard according to embodiments of the present invention.
FIG. 6 is a drawing illustrating the arrangement shape of a second type light source unit according to one embodiment of the present invention.
Figure 7 is a schematic block diagram of a light-emitting bollard according to one embodiment of the present invention.
FIG. 8 is a drawing exemplifying the contents of a manual setting mode applied to a light-emitting bollard according to one embodiment of the present invention.
FIG. 9 is a flowchart showing an operation process according to an adaptive control mode of a light-emitting bollard according to one embodiment of the present invention.
FIG. 10 is a flowchart showing an operation process according to an adaptive control mode of a light-emitting bollard according to another embodiment of the present invention.

The present invention can have various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, but should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the present invention. The singular expression includes the plural expression unless the context clearly indicates otherwise. As used herein, the terms "comprises" or "has" and the like are intended to specify the presence of a feature, number, step, operation, component, part or combination thereof described in the specification, but should be understood to not exclude in advance the possibility of the presence or addition of one or more other features, numbers, steps, operations, components, parts or combinations thereof.

In addition, when describing with reference to the attached drawings, regardless of the drawing symbols, identical components are given identical or related reference symbols, and redundant descriptions thereof are omitted. When describing the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the gist of the present invention, the detailed description thereof is omitted.

FIG. 1 is an external view of a light-emitting bollard according to an embodiment of the present invention, FIG. 2 is an exploded perspective view showing a configuration arranged inside a light-transmitting cover of a light-emitting bollard according to an embodiment of the present invention, and FIG. 3 is a drawing exemplifying the arrangement shape of a first type light source unit according to an embodiment of the present invention. FIGS. 4 and 5 are drawings for explaining light-emitting and light-accumulating operations of a light-emitting bollard according to embodiments of the present invention, and FIG. 6 is a drawing exemplifying the arrangement shape of a second type light source unit according to an embodiment of the present invention, and FIG. 7 is a schematic block diagram of a light-emitting bollard according to an embodiment of the present invention, and FIG. 8 is a drawing exemplifying the contents of a manual setting mode applied to a light-emitting bollard according to an embodiment of the present invention.

Referring to Fig. 1, the light-emitting bollard (100) is configured to include a lighting unit (105) and a pillar part (110).

The pillar part (110) can be formed in a polygonal shape, such as a circular pillar, a square pillar, or a hexagonal pillar, and a ground fixing part (115) for fixing to the ground is mounted at the bottom of the pillar part (110).

On the circumference of the pillar part (110), a light-absorbing part (120) is formed in a ring shape around the outer periphery of the pillar part (110) with a predetermined width. The light-absorbing part (120) can be formed, for example, of a light-absorbing pigment or light-absorbing sheet that has the property of absorbing and storing light internally and emitting and emitting light.

The light accumulator (120) may be positioned at a predetermined distance from the light unit (105) to absorb and store the light emitted from the light unit (105) internally. Of course, it is also possible for the light accumulator (120) to absorb and store the surrounding light of the light-emitting bollard (100) internally.

The light-absorbing portion (120) may be formed by applying a light-absorbing pigment to the surface of the column portion (110) or by attaching a light-absorbing sheet, and the light-absorbing portion (120) may be formed by using a concave groove formed in the column portion (110) so that the light-absorbing portion (120) is stably fixed in position. In addition, although FIG. 1 illustrates two light-absorbing regions spaced apart at a predetermined interval to form the light-absorbing portion (120), it is to be understood that the number of light-absorbing regions forming the light-absorbing portion (120) is not limited thereto.

The lighting unit (105) is fixedly installed on the upper part of the pillar part (110). That is, a light-emitting cover (130) is mounted on the upper part of the pillar part (110), and a top cap (140) and a support (145) are combined to close the open upper part of the light-emitting cover (130) to form the body of the lighting unit (105). An operation control button (150) may be arranged on one side of the support (145) for the user to set the operation form of the light-emitting bollard (100) (e.g., power control, setting the on/off time of the light source part, etc.).

The light-emitting cover (130) can be formed in a shape (e.g., an inverted dome shape) that is relatively wider at the top than at the bottom, and is formed of a transparent material so that light emitted from a first type light source (270) arranged in the internal space of the body of the lighting unit (105) is transmitted.

In addition, if necessary, part or the entire area of the light-emitting cover (130) may be subjected to corrosion treatment (e.g., mold treatment that provides a fine roughness to the exterior of the injection mold to make the injection molded product translucent) so that the light source and other circuit components placed inside are not visible from the outside.

In addition, the support (145) is mounted to close the open upper portion of the light-transmitting cover (130) by being combined with the upper cap (140), and the upper cap (140) and the support (145) can be formed of a transparent material to transmit sunlight reaching the solar panel (210) arranged in the internal space of the body of the lighting unit (105).

Of course, as mentioned above, in order to prevent the internal components from being visible from the outside, the support (145) is selected from an opaque material, and can be complementarily processed with a transparent material top cap (140) (for example, the support (145) made of silicone and joined to the transparent material top cap (140) such as glass can be processed in black or brown). In addition, the support (145) can be die-casted for heat dissipation of the light source part provided in the lighting unit (105).

The light-emitting cover (130), top cap (140), etc. may be made of a material such as acrylic, reinforced glass, transparent PC, glasstic, ABS, PC/ABS, or reinforced plastic with added glass fiber, etc., which is resistant to heat and has a certain level of strength while allowing the transmission of sunlight or light emitted from the first type light source (270).

It is to be understood that the upper surface cap (140) may be directly coupled to the upper portion of the light-transmitting cover (130) as illustrated in (a) of Fig. 5, unless the upper surface cap (140) is limited to being mounted on the open upper portion of the light-transmitting cover (130) while being coupled to the support (145). In addition, the coupling shape of the light-transmitting cover (130), the upper surface cap (140), and/or the transparent support (145) may vary.

As illustrated in FIG. 2, a solar panel (210), a rechargeable battery (220), an auxiliary battery (225), a control unit (230), a shield (235), and a heat sink (240) are provided inside the body of the lighting unit (105).

The solar panel (210) generates electricity by sunlight that reaches the top cap (140), and the generated electricity is stored in the rechargeable battery (220). If the support (145) is made of a material that transmits light, light that has passed through the support (145) may reach the solar panel (210).

That is, the rechargeable battery (220) stores the power generated by the photoelectric effect when the solar panel (210) receives sunlight, and an auxiliary battery (225) is further provided as an auxiliary means for the rechargeable battery (220).

The auxiliary battery (225) may be, for example, a dry cell, and may be provided as an emergency power source to allow the light bollard (100) to perform its designated operation normally even when the power generated by solar energy is insufficient, such as during a long rainy season. Of course, if sufficient power is stored in the rechargeable battery (220) by solar energy to allow the light bollard (100) to operate, the auxiliary battery (225) may be omitted.

The internal space of the body of the lighting unit (105) is separated in the upper and lower directions by a cover plate (235).

The cover plate (235) functions to cover the circuit part that drives the first type light source part (270) to be described later so that it is not exposed, and to prevent the circuit part from being separated even by external impact by fastening the circuit part to a connecting part such as a boss of the cover plate (235). In addition, through this, the problem of the circuit part being separated by external impact and causing damage to other parts can be prevented.

In addition, depending on the size and shape of the shield (235) installed, the light emitted from the first type light source unit (270) or the second type light source unit (280) arranged in different areas with the shield (235) as the boundary can be suppressed from proceeding to another area separated by the shield (235).

A control unit (230) may be mounted on the upper surface of the cover plate (235). The specific operation of the control unit (230) will be described in detail later with reference to FIG. 7.

A heat sink (240) is mounted on the lower surface of the cover plate (235), and a plurality of first type light sources (270) are mounted on the lower surface of the heat sink (240) (i.e., the inner lower portion of the cover plate (235) on which the heat sink (240) is mounted) as illustrated in FIG. 3. The heat sink (240) may be formed of a metal material such as aluminum, for example, to function as a heat sink that dissipates heat generated during operation of the first type light source (270).

The first type light source unit (270) is lit by power supplied from a rechargeable battery (220) and/or an auxiliary battery (225) under the control of the control unit (230), and may be composed of, for example, LED light-emitting elements.

The heat sink (240) reflects light emitted from the first type light source (270) in the lower region inside the body of the lighting unit (105) separated by the cover plate (235) (see (b) of FIG. 4). To this end, a thin white reflective sheet may be attached to the lower surface of the heat sink (240) on which the first type light source (270) is mounted, or a white spray for reflection may be applied.

In order to allow light emitted downward from the first type light source (270) mounted on the lower surface of the heat sink (240) to pass through the light-transmitting cover (130) and be emitted to the outside of the lighting unit (105), as illustrated in FIGS. 4 and 5, a curved reflector (310) having a convex shape upward is fixedly mounted using the peripheral surface of the inner lower portion of the light-transmitting cover (130). Of course, the curved reflector (310) may be integrated into the light-transmitting cover (130) so as to close the open lower portion of the light-transmitting cover (130).

As illustrated in FIG. 4, light emitted from the first type light source (270) may be reflected by a curved reflector (310) disposed below and emitted to the outside of the light-transmitting cover (130), or may be sequentially reflected by the curved reflector (310) and the heat sink (240) and emitted to the outside of the light-transmitting cover (130), or may be emitted to the outside of the light-transmitting cover (130) without being reflected by the curved reflector, etc.

At this time, a rough and uneven pattern may be formed on the light-transmitting cover (130) that scatters the light emitted from the first type light source (270) to refract (for example, 9.1 degrees) the transmitted light. The uneven pattern formed on the light-transmitting cover (130) may be formed so that some of the light reaching the lower area of the light-transmitting cover (130) is refracted toward the light-accumulating unit (120) formed on the outer peripheral surface of the pillar unit (110) (see (b) of FIG. 4). By forming a refractive pattern on the light-transmitting cover (130), the amount of light reaching the light-accumulating unit (120) may be increased, thereby allowing sufficient light to be absorbed and stored in the light-accumulating unit (120).

In order to allow a relatively large amount of light from among the light emitted from the first type light source (270) to reach the light accumulator (120), the size of the upper region of the light-projecting cover (130) (i.e., the upper region of the lower region inside the body of the lighting unit (105) separated by the cover plate (235)) may be relatively increased, as illustrated in FIG. 5 (b). In addition, as illustrated in FIG. 5 (a), a protruding pattern that refracts light passing through the light-projecting cover (130) in accordance with the distance between the light accumulator (120) and the lighting unit (105) may be formed in the lower region of the light-projecting cover (130).

In the upper region of the internal space of the body of the lighting unit (105) separated vertically by the cover plate (235), one or more second type light sources (280) are mounted. In FIG. 6, the case where the second type light source (280) is fixedly mounted on the side of the solar panel (210) is exemplified. However, if the location does not hinder the power generation of the solar panel (210) by sunlight and the light emitted from the second type light source (280) can be transmitted through the upper side of the lighting unit (105) (for example, the upper cap (140) etc.), the fixing location of the second type light source (280) is not limited. In addition, in FIG. 6, the second type light source (280) is applied to a PCB, but it can also be implemented as a structure in which control is possible at any time with only a hardware control command by connecting the LED alone to a power source without using a PCB, such as a dip type LED.

The second type light source unit (280) may be a light source unit (e.g., an LED light emitting element) that is illuminated with a relatively lower brightness and operates with a relatively lower power consumption compared to the first type light source unit (270) described above. Accordingly, when comparing the lighting maintenance time of each of the first type light source unit (270) and the second type light source unit (280) until they consume the same amount of power specified in advance, the second type light source unit (280) has a characteristic of being illuminated for a relatively long time, although it has a relatively dark brightness.

Here, the first type light source unit (270) and the second type light source unit (280) may be pre-designated to be turned on for different purposes. For example, the first type light source unit (270) may be turned on for the purpose of allowing the light-emitting bollard (100) to function as landscape lighting for creating a landscape atmosphere or providing visual guidance for a pedestrian path. In contrast, the second type light source unit (280) may be turned on for the purpose of securing minimum visibility to prevent collisions with pedestrians.

Hereinafter, with reference to Fig. 7, which illustrates a block diagram of a lighting unit (105) of a light-emitting bollard (100), the configuration of the light-emitting bollard (100) and its operation according to the manual setting mode will be briefly described.

Referring to FIG. 7, the lighting unit (105) of the light-emitting bollard (100) may include a solar panel (210), a rechargeable battery (220), an auxiliary battery (225), a control unit (230), an operation control button (150), a first type light source unit (270), and a second type light source unit (280).

The solar panel (210) generates power by sunlight that reaches the upper cap (140), and the generated power is stored in the rechargeable battery (220). The power stored in the rechargeable battery (220) can be supplied to the first type light source unit (270) or/and the second type light source unit (280) under the control of the control unit (230) to turn on the corresponding light source unit.

The auxiliary battery (225) may be, for example, a dry cell, and may be provided as an emergency power source to allow the light bollard (100) to perform a normally designated operation when the power charged in the rechargeable battery (220) is insufficient. As described above, if sufficient power is stored in the rechargeable battery (220) by solar energy to allow the light bollard (100) to operate, the auxiliary battery (225) may be omitted.

The structure and control technique by which the control unit (230) selects one of the rechargeable battery (220) and the auxiliary battery (225) and controls power to be supplied to the first type light source unit (270) are obvious to those skilled in the art, so a detailed description thereof is omitted.

As described above, the interior space of the body of the lighting unit (105) is separated in the upper and lower directions by a cover plate (235), and a first type light source unit (270) is mounted on the lower part of the interior space of the body separated by the cover plate (235), and a second type light source unit (280) is mounted on the upper part of the interior space of the body.

Here, the second type light source (280) may be a light source (e.g., an LED light-emitting element) that is illuminated at a relatively lower brightness than the first type light source (270) and operates with relatively less power consumption.

A first type light source part (270) is mounted on the lower surface of a heat sink (240) attached to the lower surface of a cover plate, and a curved reflector part (310) having an upwardly convex shape is placed on the lower surface of the light-transmitting cover (130) so that light emitted downward from the first type light source part (270) passes through the light-transmitting cover (130) and is emitted to the outside of the lighting unit (105) (see FIGS. 4 and 5).

A column (110) supporting a lighting unit (105) from below may be provided with a light-emitting means, a light-emitting portion (120). The light-emitting portion (120) may be formed to have a predetermined width on the circumference of the column (110) and to surround the outer periphery of the column (110) in a ring shape. The light-emitting portion (120) may be formed of, for example, a light-emitting pigment or a light-emitting sheet that absorbs and stores light internally and has the property of emitting and emitting light.

The control unit (230) can control the first type light source unit (270) and the second type light source unit (280) to operate according to a manual setting mode or an adaptive control mode.

Here, the manual setting mode is an operation mode in which the lighting maintenance time of the first type light source unit (270) is set according to the user's operation using the operation control button (150, see FIG. 1). Setting information regarding the manual setting mode for varying the lighting maintenance time of the first type light source unit (270) according to the number of times the user presses the operation control button (150) can be stored in advance in a storage unit (not shown).

For example, referring to the setting information on the pre-stored manual setting mode, if the user presses the operation control button (150) once, the control unit (230) can control the operation so that the first type light source unit (270) maintains the lighting state from 6 o'clock to 6 o'clock, and if the user presses the operation control button (150) four times, the control unit (230) can control the operation so that the first type light source unit (270) maintains the lighting state only from 8 o'clock to 12 o'clock. An indicator lamp (not shown) may be provided on one side of the light-emitting bollard (100) so that the user can check how many times the operation control button (150) has been pressed. Of course, the indicator lamp may be omitted, and it is natural that the operation of the indicator lamp may be preset so as to be performed by the second type light source unit (280).

At this time, if the power stored in the rechargeable battery (220) is insufficient to keep the first type light source unit (270) lit according to the setting information regarding the manual setting mode, the control unit (230) can change the power supply line so that the first type light source unit (270) is lit using the power of the auxiliary battery (225).

The user can differentiate the lighting time of the first type light source unit (270) by using the motion control button (150) provided on the light-emitting bollard (100) depending on the season, or limit the lighting time so that the first type light source unit (270) is lit only when pedestrians or tourists are present in the area where the light-emitting bollard (100) is installed.

As described above, the control unit (230) may control the first type light source unit (270) and the second type light source unit (280) to operate according to an adaptive control mode.

Hereinafter, with reference to FIGS. 9 and 10, the control operation of the control unit (230) according to the adaptive control mode will be described.

FIG. 9 is a flowchart showing an operation process according to an adaptive control mode of a light-emitting bollard according to one embodiment of the present invention.

Referring to FIG. 9, at step 910, the control unit (230) turns on the first type light source unit (270) at a pre-designated time.

Here, the first type light source (270) may be turned on for the purpose of, for example, allowing the light bollard (100) to function as landscape lighting for creating a landscape atmosphere or for providing visual guidance for a walkway. In addition, the time for which the first type light source (270) is turned on may be preset for example by season, or may be set to be specified by the user by pressing the motion control button (150).

At step 920, the control unit (230) determines whether the remaining charge power stored in the rechargeable battery (220) is less than or equal to a pre-specified first threshold value (e.g., 10% of the maximum charge amount).

If the remaining charge power stored in the rechargeable battery is greater than or equal to the first threshold value, the control unit (230) controls the lighting state of the first type light source unit (270) to be maintained.

However, if the remaining charge power stored in the rechargeable battery (220) is less than the first threshold value, at step 930, the control unit (230) controls the first type light source unit (270) to turn off and the second type light source unit (280) to turn on.

The second type light source unit (280) may be a light source unit (e.g., an LED light emitting element) that is illuminated with a relatively low brightness and operates with a relatively low power consumption compared to the first type light source unit (270) described above. In addition, the second type light source unit (280) may be illuminated with a relatively dark color, but for the purpose of recognizing the presence of the bollard and securing a minimum level of visibility to prevent collisions with pedestrians, unlike the first type light source unit (270) that is intended to secure a predetermined illuminance.

At this time, when the area around the light-emitting bollard (100) is dark due to the lighting of the second type light source (280), the light absorbed and stored inside the light-accumulating portion (120) is emitted, thereby ensuring additional visibility.

At step 940, the control unit (230) determines whether the remaining charge power stored in the rechargeable battery (220) is less than or equal to a pre-specified second threshold value (e.g., 3% of the maximum charge amount).

If the remaining charge power stored in the rechargeable battery (220) is greater than or equal to the second threshold value, the control unit (230) controls the lighting state of the second type light source unit (280) to be maintained.

However, if the remaining charge power stored in the rechargeable battery is less than the second threshold value, then in step 950, the control unit (230) controls the second type light source unit (280) to be turned off. This means that the remaining charge power less than the second threshold value may be used, for example, for the purpose of maintaining the setting information of the light-emitting bollard (100) stored in the storage unit.

FIG. 10 is a flowchart showing an operation process according to an adaptive control mode of a light-emitting bollard according to another embodiment of the present invention.

Referring to FIG. 10, in step 1010, the control unit (230) turns on the first type light source unit (270) at a pre-designated time. Here, the first type light source unit (270) may be turned on for the purpose of functioning as landscape lighting, and the pre-designated time for the first type light source unit (270) to emit light may be pre-set by season, for example, or may be pre-set so that the user may press the operation control button (150) to designate it.

In step 1020, the control unit (230) determines whether the remaining charge power stored in the rechargeable battery (220) is less than or equal to a pre-specified first threshold value (e.g., 10% of the maximum charge amount).

If the remaining charge power stored in the rechargeable battery is greater than or equal to the first threshold value, the control unit (230) controls the lighting state of the first type light source unit (270) to be maintained.

However, if the remaining charge power stored in the rechargeable battery (220) is less than the first threshold value, in step 1030, the control unit (230) controls the first type light source unit (270) to turn off.

At this time, when the area around the light-emitting bollard (100) becomes dark due to the turning off of the first type light source (270), the light absorbed and stored inside the light-accumulating portion (120) is emitted, thereby ensuring additional visibility.

In step 1040, the control unit (230) determines whether a predetermined time has elapsed since the first type light source unit (270) was turned off. Here, the predetermined time may be predetermined as a statistical time required from the time when the light-accumulating unit (120) receives light from the lighting unit (105) and/or the surroundings, absorbs it internally, and stores it, and then starts emitting light below a predetermined illuminance until the brightness decreases below a predetermined brightness.

However, if the pre-specified time has not elapsed, wait at step 1030.

However, if a pre-specified time has elapsed, at step 1040, the control unit (230) controls the second type light source unit (280) to turn on.

The second type light source unit (280) may be a light source unit (e.g., an LED light emitting element) that is illuminated with a relatively low brightness and operates with a relatively low power consumption compared to the first type light source unit (270) described above. In addition, the second type light source unit (280) may be illuminated with a relatively dark color, but for the purpose of recognizing the presence of the bollard and securing a minimum level of visibility to prevent collisions with pedestrians, unlike the first type light source unit (270) that is intended to secure a predetermined illuminance.

That is, after the first type light source (270) functioning as a landscape light is turned off, the light-absorbing part (120) is illuminated for a predetermined period of time to ensure visibility of the bollard, and then the second type light source (280) is turned on to ensure visibility of the bollard, so that the time during which pedestrians, etc. recognize the existence of the bollard and avoid collision can be extended as much as possible, even though it is relatively dark.

At step 1060, the control unit (230) determines whether the remaining charge power stored in the rechargeable battery (220) is less than or equal to a pre-specified second threshold value (e.g., 3% of the maximum charge amount).

If the remaining charge power stored in the rechargeable battery (220) is greater than or equal to the second threshold value, the control unit (230) controls the lighting state of the second type light source unit (280) to be maintained.

However, if the remaining charge power stored in the rechargeable battery is less than the second threshold value, at step 950, the control unit (230) controls the second type light source unit (280) to turn off.

As described above, the light-emitting bollard equipped with a solar panel according to the present embodiment and the control method thereof have the characteristics of being easy to install while emitting light for a long time to secure visibility by using electric energy charged using sunlight during the day to turn on the light source at night and allowing the light-accumulating portion equipped on the column-shaped body to emit light even after the light source is turned off. In addition, the light-emitting bollard has the characteristic of enabling efficient use of electric energy by appropriately sequencing the operation timing of various light-emitting means equipped on the bollard and adaptively selecting and turning on an appropriate type of light source depending on the remaining amount of electric energy currently secured.

Although the present invention has been described above with reference to embodiments thereof, it will be understood by those skilled in the art that various modifications and changes may be made to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below.

100 : Luminous bollard 105 : Lighting unit
110: Column part 115: Ground fixing part
120: Light-emitting part 130: Light-emitting cover
140 : Top cap 145 : Support
150 : Motion control button 210 : Solar panel
220 : Rechargeable Battery 225 : Auxiliary Battery
230: Control unit 235: Cover plate
240: Heat sink 270: Type 1 light source
280: Type 2 light source 310: Curved reflector

Claims (8)

In luminous bollards,
A column part installed so as to protrude upward from the ground; and
Including a lighting unit fixed to the upper part of the above pillar,
The above lighting unit,
A light-emitting cover mounted on the top of the above pillar;
An upper cap made of a transparent material, arranged to cover the open upper portion of the light-emitting cover, to form the body of the above lighting unit;
A cover plate that separates the internal space of the body of the above lighting unit in the vertical direction;
A solar panel positioned on the upper part of the above-mentioned cover, which generates electricity using sunlight passing through the upper surface cap;
A rechargeable battery that stores the power generated by the solar panel;
A first type light source portion positioned at the lower portion of the cover so as to face downward and illuminated using power charged in the rechargeable battery;
A curved reflector having an upward convex shape, arranged at the bottom of the first type light source unit, to reflect light emitted downward from the first type light source unit; and
A second type light source portion is disposed on the upper part of the above-mentioned cover so as to face upward and is illuminated using power charged in the above-mentioned rechargeable battery.
The first type light source unit is provided so that the light-emitting bollard functions as a landscape light, and the second type light source unit is provided so that the light-emitting bollard functions as a pedestrian collision prevention light, wherein the second type light source unit is configured to operate with relatively lower brightness and relatively lower power consumption compared to the first type light source unit.
By the cover plate that separates the internal space of the body of the lighting unit in the vertical direction, the light emitted from the first type light source unit arranged below the cover plate and the second type light source unit arranged above the cover plate is suppressed from progressing to another area separated by the cover plate as a boundary.
Light emitted from the first type light source and light reflected by the curved reflector are prevented from progressing upward by the cover plate and transmitted to the outside through the side area of the light-transmitting cover located below the cover plate, and light emitted from the second type light source is prevented from progressing downward by the cover plate and transmitted to the outside through the upper cap located above the cover plate.
On the circumference of the above pillar, a light-absorbing portion is formed in a ring shape around the outer periphery of the pillar with a predetermined width, and the light-absorbing portion is formed of a light-absorbing pigment or light-absorbing sheet that absorbs and stores light internally and has the property of emitting and emitting light.
In order to allow the light-emitting bollard to function as either a landscape light or a pedestrian collision prevention light corresponding to the remaining charge power stored in the rechargeable battery, the control unit controls the first type light source unit and the second type light source unit not to be turned on at the same time according to a preset adaptive control mode, wherein the control unit controls the first type light source unit to be turned on while the second type light source unit is turned off at a preset time, and when the remaining charge power stored in the rechargeable battery reaches a preset first threshold value, controls the first type light source unit to be turned off while the second type light source unit is turned off, and when a preset time elapses while both the first type light source unit and the second type light source unit are turned off, controls only the second type light source unit to be turned on, and when the remaining charge power stored in the rechargeable battery reaches a preset second threshold value, controls the second type light source unit to be turned off.
A luminous bollard, wherein the above-mentioned predetermined time is designated as a statistical time required for the luminous brightness of the luminous portion to decrease below the predetermined brightness after the first type light source portion is turned on and then turned off.
delete In the first paragraph,
A rough pattern is formed on some areas of the surface of the above-mentioned light cover,
A light-emitting bollard, wherein the above-mentioned pattern is formed at an angle such that light emitted from the first type light source portion and passing through the light-transmitting cover is refracted toward the light-accumulating portion.
delete In the first paragraph,
One side of the above lighting unit is provided with an operation control button,
A light-emitting bollard, wherein the control unit controls the first type light source unit to turn on and off at a time according to the setting information corresponding to the number of presses of the operation control button, by referring to the setting information regarding the pre-stored manual setting mode.
delete delete In the first paragraph,
A luminous bollard, wherein the upper surface cap is mounted to close the open upper portion of the light-emitting cover by being coupled with a support, or is directly coupled with the light-emitting cover to close the open upper portion of the light-emitting cover.