KR20190074272A - Smart shelter - Google Patents

Abstract

The present invention relates to a smart shelter, which can be remotely controlled and managed, comprising: a first body part extending in the first direction; a second body part extending from an upper portion of the first body part in a second direction crossing the first direction; an awning screen protruding from a side surface of the second body part; and a heater provided at a lower portion of the second body part.

Description

Smart Shelter {SMART SHELTER}

The present invention relates to a smart shelter.

Many shade devices have been installed in India recently. Awnings simply provide shade to people who are waiting for a signal to cross the crosswalk and are not exposed to strong sunlight.

Patent No. 10-962508 discloses a foldable shade apparatus. Since the shade apparatus of Patent No. 10-962508 provides only a simple shade, it is generally used only in the summer, and occupies an unnecessary space in the seasons other than the summer. The shade apparatus of the Japanese Patent No. 10-962508 has a disadvantage that it is inconvenient to operate because the shade must be manually folded or unfolded manually by a person.

Japanese Patent Registration No. 10-1871202 discloses a shade apparatus including a shade which is automatically opened and closed according to illuminance and wind speed, and a configuration in which outside air is blown to the lower part of the shade using a sirocco fan operated by solar power generation. However, in the case of Patent No. 10-1871202, in order to operate the shade in a general situation (that is, a situation not depending on the illuminance or wind speed), as in JP 10-962508, a person manually folds or stretches the shade And in the seasons other than the summer, it is not used unless it rains, so that it takes up space unnecessarily and has its drawbacks in that its utility is reduced.

Japanese Patent Registration No. 10-1824909 discloses an awning device including a gait identifying unit for illuminating green or red light in conjunction with an operation of an ornamental shade and a traffic light by sensing temperature, rainfall, wind speed, and wind speed. Patent No. 10-1824909 discloses that a person must manually fold or unfold a shade manually in order to operate a shade in a general situation (i.e., not in accordance with temperature, rain, wind speed, and wind speed) In season, it is not used unless it comes to rain or snow, so it takes up space unnecessarily and has its drawbacks in that its utility is poor.

A problem to be solved is to provide a smart shelter having various functions.

A problem to be solved is to provide a smart shelter having high usability.

The challenge is to provide a smart shelter that can be remotely controlled and managed.

However, the problem to be solved is not limited to the above disclosure.

A first body portion extending in a first direction; A second body extending from an upper portion of the first body portion in a second direction crossing the first direction; An eyelash protruded from a side surface of the second body part; And a heater provided at a lower portion of the second body portion.

The heater radiates radiant heat. The air below the sun shade is heated by the radiant heat, and the sun shade prevents the heated air from rising, thereby increasing the time the air stays under the sun shade.

The heaters may be provided in a pair.

The heater may protrude from a bottom surface of the second body part.

The heater may extend along the second direction, and the length of the heater along the second direction may be more than half the length of the second body along the second direction.

And a solar module provided on the second body portion, wherein the heater can be driven by at least one of power produced by the solar module and external power.

And a display unit provided on a side surface of the first body part.

And a charging unit provided on a side surface of the first body part, wherein the charging unit may include at least one of a wire charging apparatus and a wireless charging apparatus.

A lower illumination provided in the lower portion of the second body portion; And an upper illumination unit provided at an upper end of the first body unit.

The upper illumination may be disposed at a higher level than the second body.

A photographing unit for photographing the periphery thereof; And a storage unit for storing the image photographed by the photographing unit.

Awnings; heater; A communication unit for communicating with an external server; And a processor, wherein the processor controls the shade film to expand or contract the shade film based on the control signal received by the communication unit, and controls the heater to be turned on or off, May be provided.

And the processor may control the fine dust signal unit to emit light having a color corresponding to the fine dust density of the fine dust signal portion based on the control signal.

A first body portion extending in a first direction; A second body extending from an upper portion of the first body portion in a second direction crossing the first direction; A lower illumination provided at a lower portion of the second body portion; And an upper illuminator provided at an upper end of the first body portion, wherein the processor controls the lower illuminator so that the lower illuminator is turned on or off based on the control signal, and the upper illuminator is turned on The upper illumination can be controlled to be turned off.

Wherein the processor controls the photographing section to photograph the periphery of the photographing section to generate moving image data based on the control signal and to control the communication section to transmit the moving image data to the external server can do.

A first body portion extending in a first direction; A second body extending from an upper portion of the first body portion in a second direction crossing the first direction; An eyelash provided on the second body part; A heater provided at a lower portion of the second body portion; temperature Senser; And a processor, wherein the processor controls the temperature sensor such that the temperature sensor measures the temperature to generate temperature data, and operates the heater such that the heater emits heat when the temperature is below a reference temperature And a smart shelter for stopping the operation of the heater when the temperature exceeds the reference temperature.

The processor controls the winging film so that the winging film expands when the heater is operated, and the expanded winging film prevents the air heated by the heater from rising, so that the time when the air stays under the shading film .

And a weight sensor for measuring a weight applied to the shade film, wherein when the shade film is in an extended state, the processor controls the shade film to be inserted into the second body part when the weight is equal to or greater than a reference weight, Can be controlled.

And a display unit provided on the first body unit for outputting information, wherein the processor is further configured to cause the display unit to display a warning phrase related to operation of the ornamental film before the winging film is inserted into the second body unit Can be output.

Wherein the distance measuring sensor is disposed between an object approaching the second body part at a height at which the second body part is disposed and a second body part between the second body part and the second body part, The distance measuring sensor may be controlled to measure the distance between the first and second wing films.

The present disclosure can provide a smart shelter having various functions.

The present disclosure can provide a smart shelter with high utility.

The present disclosure can provide a smart shelter that can be remotely controlled and managed.

However, the effect of the invention is not limited to the above disclosure.

1 is a block diagram of a smart shelter in accordance with exemplary embodiments of the present invention.
2 is a perspective view of a smart shelter in accordance with exemplary embodiments.
Figure 3 is a front view of the smart shelter of Figure 2;
Figure 4 is a smart shelter perspective view of Figure 2 with the expanded state. Figure 5 is a front view of the smart shelter of Figure 4;
FIG. 6 is a flow chart for explaining an operation mode according to pre-stored conditions of the smart shelter of FIGS. 2 to 5; FIG.
7 is a conceptual diagram for explaining an operating mode of the smart shelter of FIG.
8 is a flow chart for explaining an operation mode according to a pre-stored condition of the smart shelter of Figs. 2 to 5. Fig.
FIG. 9 is a conceptual diagram for explaining an operating mode of the smart shelter of FIG. 8; FIG.
FIG. 10 is a flow chart for explaining an operation mode according to pre-stored conditions of the smart shelter of FIGS. 2 to 5; FIG.
11 is a conceptual diagram for explaining an operation mode of the smart shelter of FIG.
12 is a conceptual diagram for explaining an operation mode of the smart shelter of FIG.
FIG. 13 is a flow chart for explaining an operation mode according to pre-stored conditions of the smart shelter of FIGS. 2 to 5; FIG.
14 is a conceptual diagram illustrating a smart shelter system according to exemplary embodiments.
Fig. 15 is a conceptual diagram for explaining a provision position of smart shelters in Fig. 14;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following drawings, like reference numerals refer to like elements, and the size of each element in the drawings may be exaggerated for clarity and convenience of explanation. On the other hand, the embodiments described below are merely illustrative, and various modifications are possible from these embodiments.

In the following, what is referred to as "upper" or "upper"

The singular expressions include plural expressions unless the context clearly dictates otherwise. Also, when an element is referred to as "comprising ", it means that it can include other elements as well, without departing from the other elements unless specifically stated otherwise.

Furthermore, the term " part " or the like described in the specification means a unit for processing at least one function or operation, which may be implemented by hardware or software, or a combination of hardware and software.

1 is a block diagram of a smart shelter in accordance with exemplary embodiments of the present invention.

1, a smart shelter 1 including a processor CU, a communication unit TU, a sensor unit SU, an operation unit OP, a power unit PU, and a storage unit MU is provided . The smart shelter 1 can provide various information including a location where the user of the smart shelter 1 can avoid strong sunlight, cold air, rain, snow, and so forth, and fine dust concentration information to the user. For example, the smart shelter 1 may be provided on a sidewalk adjacent to a crosswalk so that the user can use it while waiting for a pedestrian signal.

The processor CU may receive measurement signals from the sensor unit SU. For example, the measurement signals may be generated by the sensors included in the sensor unit SU, respectively. The processor CU may store the measurement signals in the storage unit MU. The processor CU can control the actuating part OP based on the measurement signals. The processor CU may control the power unit PU to distribute power to the components included in the operating unit OP.

The communication unit (TU) can communicate with a server outside the smart shelter (1). The communication unit TU can communicate with a server outside the smart shelter 1 by wire or wirelessly. For example, the communication unit TU may be a local area network (LAN), a wide area network (WAN), a value added network (VAN), a mobile radio communication network, And one or more components that enable communication through a combination of the two. The communication unit TU can transmit and receive data or signals wirelessly using an external device or an external server directly using a wireless LAN (for example, Wi-Fi). In one example, the communication unit TU may receive a control signal from a server outside the smart shelter 1. The control signal may be a signal for controlling the operation part OP. The control signal may be generated by a manager of the smart shelter 1 using a terminal device connected to an external server. That is, the manager of the smart shelter 1 can control the smart shelter 1 remotely using the terminal device. The communication unit TU may provide the control signal to the processor CU. The server may be a device that can be connected to a terminal device through a network to transmit and receive data, and to provide an application according to a user's request. A terminal device is a terminal that can be used by an administrator, and can be a terminal capable of connecting to a server through a wired or wireless network to transmit and receive data. For example, the terminal device may be a smart phone, a PC, a tablet PC, a notebook, a cellular phone, a personal digital assistant (PDA), a laptop, a wearable device and other mobile or non-mobile computing devices, but the present invention is not limited thereto .

The sensor unit SU can detect situations around the smart shelter 1 and generate corresponding signals. The sensor unit SU includes a motion sensor 110, a weight sensor 120, an air volume / wind speed sensor 130, an illuminance sensor 140, a rain sensor 150, a dust sensor 160, a temperature sensor 170, And a distance measurement sensor 180. However, this is an exemplary one. In another exemplary embodiment, the sensor portion SU may include only some of the sensors, or may include sensors other than the sensors. The sensor unit SU may provide the signals to the processor CU. The processor CU may store the signals in the storage unit MU.

The motion sensor 110 can sense the operation of the user of the smart shelter 1. For example, the motion sensor 110 may include an infrared sensor. The weight sensor 120 can sense the weight applied to the later-described eyelashes. The air volume / wind speed sensor 130 can measure the amount and intensity of wind provided to the smart shelter 1. The illuminance sensor 140 can sense the illuminance around the smart shelter 1. For example, the light intensity sensor 140 may include a photodiode. The rain sensor 150 may sense rain and / or snow falling on the smart shelter 1. For example, the rain sensor 150 can sense rain and / or snow using a phenomenon in which the reflectance of light is reduced by water droplets. The dust sensor 160 can measure the dust concentration around the smart shelter 1. The temperature sensor 170 can measure the temperature around the smart shelter 1. The distance measuring sensor 180 may measure the distance between the object approaching the nose 220 and the nose 220 at a height at which the nose 220 is disposed. For example, the distance measurement sensor 180 may comprise an ultrasonic sensor.

The operation unit OP includes an illumination unit 210, a wing unit 220, a photographing unit 230, a heater unit 240, a display unit 250, a fine dust signal unit 260, . However, this is an exemplary one. In another exemplary embodiment, the operating portion OP may include only some of the above configurations, or may include other configurations.

The illumination unit 210 may emit light. The illumination unit 210 may be controlled by the processor CU to provide light around the smart shelter 1. For example, the illumination portion 210 may include LED illumination. In the exemplary embodiments, the illumination portion 210 may be operated in response to the illuminance measured by the illuminance sensor 140.

The flange portion 220 can be expanded or contracted. The eyelid part 220 may provide a shade to the user of the smart shelter 1 in an expanded state or may prevent the air heated by the heater part 240 from rising. The eyelid portion 220 can be operated based on a signal generated by at least one of the weight sensor 120, the airflow / wind speed sensor 130, the illuminance sensor 140, and the rain sensor 150.

The photographing unit 230 is controlled by the processor CU to photograph the surroundings of the smart shelter 1 to generate moving images. The processor CU may store the moving picture in the storage unit MU. In the exemplary embodiments, the photographing section 230 can be operated based on a signal generated by the motion sensor 110. [

The heater section 240 may emit heat. The heater unit 240 may provide heat to the user of the smart shelter 1. The heater section 240 may be operated based on signals generated by at least one of the motion sensor 110 and the temperature sensor 170. [

The display unit 250 is controlled by the processor CU and can output information. For example, the display unit 250 may output an announcement, an advertisement, and a warning indicator.

The fine dust signal portion 260 can emit light having a color corresponding to the fine dust concentration. The processor CU is configured to generate a fine dust signal 260 based on a signal received from the dust sensor 160 or a signal received from the outside of the smart shelter 1 by the communication unit TU so that the fine dust signal unit 260 emits light. The control unit 260 can control the display unit.

The charging unit 270 can charge the electronic device. For example, a user of the smart shelter 1 can charge the mobile device using the charger 270. The charging unit 270 may include a wired charging device or a wireless charging device.

The power unit PU may include a solar module 310 and a battery 320. The solar module 310 can receive solar light to produce power. The battery 320 may store the power produced by the solar module 310. The smart shelter 1 can be driven by at least one of the power produced by the solar module 310 and the power supplied from the outside of the smart shelter 1.

The smart shelter 1 of the present disclosure can be used to evacuate the user of the smart shelter 1 from the sunlight, rain, snow, cold, and crime by using the covering part 220, the heater part 240 and the photographing part 230 It is possible to provide a place where it can be done. The smart shelter 1 of the present disclosure can provide fine dust information and various information to the user of the smart shelter 2 by using the fine dust signal unit 260 and the display unit 250. [

Generally, the sunscreen device is only used in the summer since it has a function of covering strong sunlight. In this case, in the season when the shading film device is not used (for example, in winter), the shading film device takes up unnecessary space. That is, the screening apparatus has low utility. Further, in order to operate the shading device, a person must directly approach the shading device.

The smart shelter 1 of the present disclosure is a place where the user of the smart shelter 1 can be evacuated from the sunlight, rain, snow, cold, and crime by using the shading film, the heater section 240 and the photographing section 230 Can be provided. A smart shelter 1 that can be used regardless of the season can be provided. A smart shelter 1 having high usability can be provided.

The smart shelter 1 of the present disclosure can provide fine dust information and various information to the user of the smart shelter 1 by using the fine dust signal unit 260 and the display unit 250. [

The smart shelter 1 of the present disclosure can be controlled by an instruction that the administrator inputs to the terminal device. For example, the administrator can input a command using the input device of the terminal device, and the command can reach the smart shelter 1 via the server. The processor of the smart shelter 1 can control the components of the actuating part based on the command received by the communication part TU. A smart shelter 1 that can be remotely controlled even if a person does not directly access the smart shelter 1 can be provided. As a result, a smart shelter 1 that can be easily controlled and managed can be provided.

2 is a perspective view of a smart shelter in accordance with exemplary embodiments. Figure 3 is a front view of the smart shelter of Figure 2; Figure 4 is a smart shelter perspective view of Figure 2 with the expanded state. Figure 5 is a front view of the smart shelter of Figure 4; For brevity of description, substantially the same contents as those described with reference to Fig. 1 may not be described.

2 to 5, the body 10, the illumination unit 210, the flange 220, the photographing unit 230, the heater unit 240, the display unit 250, the fine dust signal unit 260, A charger 270, and a smart shelter 2 including a solar module 310 may be provided. A processor, a storage unit, a communication unit, a battery, and a sensor unit described with reference to Fig. 1 may be provided in the body portion 10. [

The body portion 10 may include a first body 12 extending in a first direction D1. For example, the first body 12 may extend in a vertical direction from the ground surface GR.

The body portion 10 may include a second body 14 extending in a second direction D2 that intersects the first direction D1. For example, the second body 14 may extend in a direction parallel to the ground surface GR. The second body 14 may extend from the upper portion of the first body 12 in the second direction D2. Openings 14_OP may be provided on both sides of the second body 14, respectively.

The illumination unit 210 may include a lower illumination 212 and an upper illumination 214. The lower illumination 212 may be provided on the lower portion of the second body 14. [ The lower illumination 212 may extend along the second direction D2. The length of the lower illumination 212 along the second direction D2 may be more than half the length of the second body 14 along the second direction D2. The lower illumination 212 may emit light below the second body 14. [ For example, the illumination portion 210 may include LED illumination. The lower illuminations 212 may be provided in pairs. However, this is an exemplary one. In another example, the lower illumination 212 may be provided in one or more than three. The pair of lower illuminations 212 may be spaced from each other along a third direction D3 that intersects the first direction D1 and the second direction D2. A pair of lower illuminations 212 may be provided at both ends along the third direction D3 of the second body 14, respectively. The upper illuminator 214 may be provided at the upper end of the first body 12. [ The upper illuminator 214 may be disposed at a higher position than the second body 14. The top light 214 may emit light. For example, the top lighting 214 may include LED lighting.

The processor may control the bottom illumination 212 and the top illumination 214 such that the bottom illumination 212 and the top illumination 214 are operated according to pre-stored conditions in the storage. In one example, the bottom illumination 212 and the top illumination 214 may be operated in time. For example, the lower illumination 212 and the upper illumination 214 may be controlled by the processor to be turned on at a first time and turned off at a second time. In one example, the bottom illumination 212 and the top illumination 214 may be operated according to illumination. For example, the lower illumination 212 and the upper illumination 214 are controlled by the processor such that they are turned on when the illumination is below the reference illumination and can be turned off when the illumination is above the reference illumination. In one example, the bottom illumination 212 and the top illumination 214 may be operated according to time and illumination. For example, the lower illumination 212 and the upper illumination 214 are controlled by the processor to turn on when the first time is reached or the illumination is below the reference illumination, and when the second illumination is reached or the illumination is above the reference illumination Can be turned off.

The processor may control the lower illumination 212 and the upper illumination 214 such that the lower illumination 212 and the upper illumination 214 are activated by signals received from an external server by a communication unit. For example, when an administrator inputs a command to turn on the lower lighting 212 and the upper lighting 214 to the terminal device, the communication unit receives a signal for turning on the lower lighting 212 and the upper lighting 214 from an external server can do. The processor may control the bottom illumination 212 and the top illumination 214 so that the bottom illumination 212 and the top illumination 214 emit light based on the signal.

The flange portion 220 may be provided on the second body 14. The eyelid portion 220 may include an ornamental membrane 222, a support portion 224, and a cover 226. [ One end of the ornamental membrane 222 may be fixed within the second body 14 and the other end may be fixed to the cover 226. For example, one end of the shade film 222 may be fixed to a roller (not shown) in the second body 14. Accordingly, when the wing film 222 is contracted or expanded, the wing film 222 can be wound around the roller or unwound from the roller. When the ornamental membrane 222 is reduced, the ornamental membrane 222 may be inserted into the second body 14. When the orifice 222 is expanded, the orifice 222 may protrude out of the second body 14. For example, the expanded sun visor 222 may protrude from the side surface of the second body 14.

One end of the support portion 224 can be fixed within the second body 14 and the other end can be fixed to the cover 226. [ For example, the support 224 may be folded or unfolded. The operation of the support 224 may be controlled by a processor. When the support 224 is unfolded, the cover 226 may be away from the second body 14. [ Since the other end of the shade film 222 is fixed to the cover 226, the shade film 222 can be expanded. When the support 224 is folded, the cover 226 can be brought close to the second body 14. [ Since the other end of the shade film 222 is fixed to the cover 226, the shade film 222 can be reduced. In one example, a pair of supports 224 may be provided within one flange 220.

The cover 226 may have substantially the same shape and size as the opening 14_OP. The cover 226 can be inserted into the aperture 14_OP to block the aperture 14_OP when the support 224 is fully folded (i.e., when the shade film 222 is completely shrunk).

The canopy membranes 222 may be provided in pairs. A pair of shade films 222 may be provided on both sides along the third direction D3 of the second body 14. [ The pair of sun visors 222 can be operated independently. For example, the pair of shade films 222 may be expanded or contracted at the same time or at the same time.

The processor can control the ornamental film 222 so that the ornamental film 222 is expanded or contracted according to conditions previously stored in the storage section. In one example, the canopy 222 can be expanded or contracted with time. For example, the canopy 222 may be controlled by a processor, expanded at a first time, and reduced at a second time. In one example, the canopy 222 can be expanded or contracted according to illumination. For example, the ornamental film 222 is controlled by the processor so that it is expanded when the illuminance is higher than the reference illuminance, and can be reduced when the illuminance is lower than the reference illuminance. In one example, the ornamental film 222 may be operated according to visual and illuminance. For example, the shade film 222 may be controlled by the processor to expand when it reaches the first time or the illuminance is below the reference illuminance, and may be reduced when the second time is reached or the illuminance is higher than the reference illuminance.

In one example, the winging film 222 having an expanded state can be reduced in accordance with the air volume and the wind speed. For example, the widening film 222 having an expanded state can be controlled by the processor, and can be reduced when the wind amount and the wind speed are equal to or greater than the reference value.

In one example, the widening film 222 having an expanded state can be reduced according to the weight applied to the wing film 222. For example, the shroud 222 with the expanded state may be controlled by the processor, and may be reduced if the weight is above a reference weight.

In one example, the shroud 222 with a reduced condition may be expanded in proportion and / or in the eye. For example, the shroud 222 with a reduced condition may be controlled by the processor and expanded when the rain sensor senses rain and / or eyes. The processor can again shrink the expanded sun shade 222 if the rain and / or eyes are no longer sensed.

In one example, the pair of ornamental films 222 may be expanded or contracted according to a signal received from an external server by the communication unit. For example, when an administrator inputs a command to extend a pair of ornamental films 222 to a terminal device, the communication section can receive a signal for extending a pair of ornamental films 222 from an external server. Based on the signal, the processor can control the fence 220 so that the pair of shade films 222 is expanded.

The photographing unit 230 may be provided below the second body 14. The photographing unit 230 may be provided at an end of the second body 14 along the second direction D2. The photographing unit 230 can photograph the periphery of the smart shelter 2 to generate a moving image. For example, the photographing unit 230 may include a CCTV device. The photographing unit 230 may provide the moving image to the processor. The processor may store the moving image in a storage unit.

The processor can control the photographing unit 230 to photograph the photographing unit 230 according to conditions stored in advance in the storage unit. In one example, the photographing unit 230 can photograph according to the presence or absence of the user. For example, when the motion sensor senses the movement of the user, the photographing unit 230 can photograph the periphery of the smart shelter 2, and if there is no movement of the user for a predetermined period of time, can do.

In one example, the photographing section 230 can be operated on a signal received from an external server by the communication section. For example, when an administrator inputs a command to operate the photographing unit 230 to the terminal device, the communication unit can receive a signal for operating the photographing unit 230 from an external server. The processor can control the photographing unit 230 to photograph the photographing unit 230 based on the signal.

The heater unit 240 may include a pair of heaters 240. [ However, the number of the heaters 240 is not limited. In another example, the heater 240 may be provided in one or more than three. A pair of heaters 240 may be provided under the second body 14. A pair of heater parts 240 may be provided between the pair of illumination parts 210. The pair of heaters 240 may extend along the second direction D2. The pair of heaters 240 may protrude from the bottom surface of the second body 14. The pair of heaters 240 may be spaced from each other along the third direction D3. The pair of heaters 240 may emit radiant heat. For example, each of the pair of heaters 240 may include an infrared heater. The pair of heaters 240 may provide direct radiant heat to the user of the smart shelter 2 and may increase the temperature of the air beneath the second body 14.

The processor may control a pair of heaters 240 such that a pair of heaters 240 are turned on according to conditions pre-stored in the storage. Hereinafter, turning on the pair of heaters 240 means that the pair of heaters 240 emits radiant heat, while turning off the pair of heaters 240 means that the pair of heaters 240 ) Does not emit radiant heat. In one example, the pair of heaters 240 may operate at a time. For example, the heater unit 240 may be controlled by the processor, turned on at the first time, and turned off at the second time.

In one example, the pair of heaters 240 may operate according to the temperature around the smart shelter 2. For example, the pair of heaters 240 may be controlled by the processor, turned on when the temperature is below the reference temperature, and off when the temperature is above the reference temperature. The temperature can be measured by a temperature sensor.

In one example, the pair of heaters 240 may operate according to the presence or absence of the user of the smart shelter 2. For example, a pair of heaters 240 may be controlled by the processor to turn on if the user is present and off when there is no user. The user can be detected by the motion sensor.

 In one example, the pair of heaters 240 may operate according to the ambient temperature and presence of the smart shelter 2. For example, the pair of heaters 240 may be controlled by the processor such that the temperature is below the reference temperature and may only be turned on if the user of the smart shelter 2 is present. Accordingly, even if the temperature is lower than the reference temperature, the pair of heaters 240 can be turned off if there is no user.

The processor can control the shade film 222 so that the shade film 222 is expanded while the pair of heaters 240 are turned on. The air can be heated to radiant heat emitted from the pair of heaters 240. [ The heated air can rise. The expanded sun shade 222 prevents the heated air from rising and can increase the time the air stays under the expanded sun shade 222. Thus, the time when the user of the smart shelter 2 is exposed to the warm air can be increased.

In one example, the pair of heaters 240 can be operated on a signal received from an external server by a communication unit. For example, when the administrator inputs a command to operate the pair of heaters 240 to the terminal device, the communication unit can receive a signal for activating the pair of heaters 240 from the external server. Based on the signal, the processor can control a pair of heaters 240 so that the pair of heaters 240 emits heat.

The display unit 250 may be provided on the first body 12. For example, the display unit 250 may be provided on one side of the first body 12 facing the second direction D2. For example, the display unit 250 may be disposed at the eye level of the user of the smart shelter 2. The user can easily view the information output to the display unit 250. [ The display unit 250 may output an announcement, an advertisement, a warning, and the like. The contents output to the display unit 250 may be stored in advance in the storage unit or received from an external server by the communication unit. The display unit 250 may include a touch screen. The user of the smart shelter 2 can touch the display unit 250 to acquire desired information.

The fine dust signal portion 260 may be provided to the first body 12. The fine dust signal unit 260 may be provided on the one side of the first body 12 provided with the display unit 250. For example, the fine dust signal portion 260 may be provided under the display portion 250. The fine dust signal unit 260 is controlled by the processor to output information on the fine dust concentration around the smart shelter 2 as light. Information on the fine dust concentration may be generated by measuring by a dust sensor or received from an external server by a communication unit. For example, the fine dust signal portion 260 may include LED illumination. The color of the light emitted from the fine dust signal portion 260 may correspond to the concentration of the fine dust. For example, the fine dust signal portion 260 may have a fine dust concentration of 'good' (0 to 30 μg / m ³ ), 'normal' (31 to 80 μg / m ³ ) / m ^3), or the case of very poor '(151 ㎍ / m ³ or higher), can emit each of blue light, green light, yellow light, and red light.

The charger 270 may be provided on the first body 12. [ The charging unit 270 may be provided on the one side of the first body 12 provided with the display unit 250. The charging unit 270 may be provided under the display unit 250. However, the position of the charger 270 is not limited to the area below the display unit 250. The charging unit 270 can charge the electronic device. For example, a user of the smart shelter 2 can charge the mobile device using the charger 270. [ The charging unit 270 may include a wired charging device or a wireless charging device.

The solar module 310 may be provided on the second body 14. The solar module 310 can generate electric power using the sunlight irradiated to the solar module 310. The solar module 310 can provide the generated power to the battery. The battery can store the power produced by the solar module 310. The smart shelter 2 may be driven by at least one of the power produced by the solar module 310 and the power supplied from the outside of the smart shelter 2.

The smart shelter 2 of the present disclosure can be used to evacuate the user of the smart shelter 2 from sunlight, rain, snow, cold, and crime by using the shade film 222, the heater section 240 and the photographing section 230 It can provide a place to be able to. A smart shelter 2 that can be used regardless of the season can be provided. A smart shelter 2 having high usability can be provided.

The smart shelter 2 of the present disclosure can provide fine dust information and various information to the user of the smart shelter 2 by using the fine dust signal unit 260 and the display unit 250. [

The smart shelter 2 of the present disclosure can be controlled by an instruction that the administrator inputs to the terminal device. For example, the administrator can input a command using the input device of the terminal device, and the command can reach the smart shelter 2 via the server. The processor of the smart shelter 2 can control the actuators based on the command received by the communicator. A smart shelter 2 that can be remotely controlled even if a person does not approach the smart shelter 2 directly can be provided. As a result, a smart shelter 2 that is easy to control and manage can be provided.

FIG. 6 is a flow chart for explaining an operation mode according to pre-stored conditions of the smart shelter of FIGS. 2 to 5; FIG. 7 is a conceptual diagram for explaining an operating mode of the smart shelter of FIG. For brevity of description, substantially the same contents as those described with reference to Figs. 2 to 5 may not be described.

6 and 7, an illuminance sensor (not shown) may sense the illuminance around the smart shelter 2. (S110) The illuminance sensor may provide information about the illuminance to the processor.

The processor may determine whether the illuminance is equal to or greater than the first reference illuminance (S120). The first reference illuminance may be stored in advance in the storage unit. 4 and 5, the processor can control the pair of shade films 222 so that the pair of shade films 222 are extended, and when the illuminance is lower than the first reference illuminance, The lower illumination 212 and the upper illumination 214 may be controlled such that the illumination 212 and the upper illumination 214 do not emit light.

If the illuminance is not equal to or greater than the first reference illuminance, the processor may determine whether the illuminance is equal to or greater than the second reference illuminance. (S130) The second reference illuminance may be stored in advance in the storage unit. 2 and 3, the processor can control a pair of shade films 222 so that the pair of shade films 222 is shrunk, and when the illuminance is lower than the second reference illuminance, The lower light 212 and the upper light 214 may be controlled such that the light source 212 and the upper light 214 do not emit light.

7, the processor can control a pair of shade films 222 to shrink the pair of shade films 222, and the lower light 212 can control the pair of shade films 222, And the upper illumination 214 may control the lower illumination 212 and the upper illumination 214 to emit the lights 210_L1 and 210_L2.

8 is a flow chart for explaining an operation mode according to a pre-stored condition of the smart shelter of Figs. 2 to 5. Fig. FIG. 9 is a conceptual diagram for explaining an operating mode of the smart shelter of FIG. 8; FIG. For brevity of description, substantially the same contents as those described with reference to Figs. 2 to 5 may not be described.

8 and 9, a temperature sensor may measure the temperature around the smart shelter 2 (S210). The temperature sensor may provide information about the temperature to the processor.

The processor may determine whether the temperature is equal to or higher than a reference temperature (S220). The reference temperature may be stored in advance in the storage unit. 9, the processor can control a pair of heaters 240 to cause a pair of heaters 240 to turn on (i.e., emit radiant heat) A pair of ornamental films 222 can be controlled so that the pair of ornamental films 222 are extended. The air (AA) can be heated by the radiant heat emitted from the pair of heaters (240). The heated air AA can rise. The ornamental film 222 may prevent the heated air AA from rising and increase the time for the air AA to stay under the ornamental film 222. [ Accordingly, the time for the user of the smart shelter 2 to be exposed to the warm air AA can be increased.

When the temperature exceeds the reference temperature, the processor can control a pair of heaters 240 so that the pair of heaters 240 are turned off (i.e., do not emit radiant heat) It is possible to control the pair of shade films 222 so that the shade 222 is expanded.

In one example, the pair of heaters 240 may operate according to the ambient temperature and presence of the smart shelter 2. For example, the processor may control a pair of heaters 240 such that the pair of heaters 240 are turned on only when the temperature is below the reference temperature and the user of the smart shelter 2 is present . Accordingly, even if the temperature is below the reference temperature, if there is no user of the smart shelter 2, the processor can control the pair of heaters 240 so that the pair of heaters 240 are turned off (i.e., 240 can be controlled. The presence or absence of the user can be detected by a motion sensor (not shown).

FIG. 10 is a flow chart for explaining an operation mode according to pre-stored conditions of the smart shelter of FIGS. 2 to 5; FIG. 11 is a conceptual diagram for explaining an operation mode of the smart shelter of FIG. 12 is a conceptual diagram for explaining an operation mode of the smart shelter of FIG. For brevity of description, substantially the same contents as those described with reference to Figs. 2 to 5 may not be described.

10 to 12, a weight sensor (not shown) may measure a weight applied to the pair of shade films 222 (S310). For example, the weight sensor may include a pair of shade films 222 can measure the weight of the snow SN accumulated on the snow. The weight sensor may provide information about the weight to the processor.

The processor may determine whether the weight is greater than a reference weight (S320). The reference weight may be stored in advance in the storage unit. When the weight is equal to or greater than the reference weight, as shown in FIG. 12, the processor can output to the display unit 250 a guidance indicating that the pair of ornamental films 222 is reduced within a predetermined time. If the weight is less than the reference weight, the weight sensor may again measure the weight applied to the pair of shade films 222 and provide it to the processor.

After a predetermined time has elapsed from when the guidance display is output to the display unit 250, the processor can control the pair of shade films 222 to shrink the pair of shade films 222 (S340)

FIG. 13 is a flow chart for explaining an operation mode according to pre-stored conditions of the smart shelter of FIGS. 2 to 5; FIG. For brevity of description, substantially the same contents as those described with reference to Figs. 2 to 5 may not be described.

2 to 5 and 13, a distance measuring sensor (not shown) may be provided between a second body 14 and an object approaching the second body 14 at a height at which the second body 14 is disposed, (S410). For example, the distance measuring sensor may include an ultrasonic sensor. The distance measurement sensor may provide information about the distance to the processor.

The processor may determine whether the distance is less than a reference distance (S420). The reference distance may be stored in advance in the storage unit. When the distance is equal to or less than the reference distance, as shown in FIGS. 2 and 3, the processor can control the pair of sun shades 222 so that the pair of sun shades 222 is shrunk. If the distance exceeds the reference distance, the distance measuring sensor measures the distance between the second body 14 and the object approaching the second body 14 at a height at which the second body 14 is disposed, .

14 is a conceptual diagram illustrating a smart shelter system according to exemplary embodiments. Fig. 15 is a conceptual diagram for explaining a provision position of smart shelters in Fig. 14; For brevity of description, substantially the same contents as those described with reference to Figs. 1, 2 to 5 may not be described.

Referring to Fig. 14, a smart shelter system 3 including a plurality of smart shelters (SS), a server 2000, and a terminal device 1000 may be provided. Each of the plurality of smart shelters SS may be substantially the same as the smart shelter 1 described with reference to Fig. 1 or the smart shelter 2 described with reference to Figs. 2-5. In one example, as shown in FIG. 15, a plurality of smart shelters SS may be provided on the leads adjacent to the crosswalks 3000.

The plurality of smart shelters (SS) can transmit the sensing signals generated by the sensor units to the server 2000. For example, each of the sensor portions may include at least one of a motion sensor, a weight sensor, a wind speed / wind speed sensor, an illuminance sensor, a rain sensor, a dust sensor, and a temperature sensor.

The server 2000 may process the detection signals. The administrator can generate control signals using the terminal device 1000. [ The terminal apparatus 1000 can transmit control signals to the server 2000. [ The server 2000 may transmit control signals to a plurality of smart shelters (SS), respectively. The server 2000 may be a device connected to the terminal device 1000 through a network and capable of transmitting and receiving data, and capable of providing an application according to a user's request. The terminal device 1000 may be a terminal that can be used by an administrator, and may be a terminal capable of connecting to a server through a wired or wireless network to transmit and receive data. For example, the terminal device 1000 may be a smart phone, a PC, a tablet PC, a notebook, a cellular phone, a personal digital assistant (PDA), a laptop, a wearable device and other mobile or non-mobile computing devices, It is not.

The plurality of smart shelters (SS) may be controlled by control signals received from the server (2000). For example, each of the control signals may control each of the illumination portion, the shade portion, the photographing portion, the heater portion, the display portion, the fine dust signal portion, and the charging portion of each of the plurality of smart shelters SS. The control signals may be independent of each other. For example, one of the plurality of smart shelters (SS) may include a lighting unit, a lighting unit, a photographing unit, a heater unit, a display unit, a fine dust signal unit, And can be controlled independently of the beep portion, the photographing portion, the heater portion, the display portion, the fine dust signal portion, and the charging portion. For example, a pair of sunglasses of one of the plurality of smart shelters (SS) can be controlled to expand and a pair of sunglasses of the other one of the plurality of smart shelters (SS) can be controlled to shrink . For example, a pair of heaters of one of the plurality of smart shelters (SS) may be controlled to emit radiant heat, and a pair of heaters of the other smart shelters (SS) .

In the following, an operating mode of the smart shelter system in relation to the dust sensor and the fine dust signal portion will be described in detail. Each of the dust sensors can generate dust concentration data. A plurality of smart shelters (SS) can transmit dust concentration data to the server. For example, the processors included in the plurality of smart shelters (SS) can control the communication units to transmit dust concentration data to the server.

In one example, the plurality of smart shelters SS may correct dust concentration data and transmit the corrected dust concentration data to the server. For example, processors included in a plurality of smart shelters (SS) can remove numerical increases in water vapor concentrations in dust concentration data. Thus, the reliability of the dust concentration data can be improved.

The server 2000 can generate the required data based on the dust concentration data received from the plurality of smart shelters SS. For example, the server 2000 may calculate dust concentration data to obtain an average value of dust concentrations. The server 2000 can transmit the average value of the dust concentration data and the dust concentrations to the terminal device 1000.

The terminal device 1000 may include a display unit and an input unit. The terminal device 1000 can output the average value of the dust concentration data and the dust concentrations received from the server 2000 to the display unit.

The administrator can input commands for the plurality of smart shelters (SS) to the terminal device (1000) using the input unit. The terminal apparatus 1000 can generate control signals based on the instructions. The terminal device 1000 may transmit the control signals to the server 2000. [

The server 2000 may receive control signals from the terminal device 1000 and transmit the control signals to a plurality of smart shelters SS. The control signals may be signals for controlling the fine dust signal portions of the plurality of smart shelters (SS).

The fine dust signal portions can emit light having a color corresponding to the fine dust concentration, based on the control signals. In one example, the light emitted by the fine dust signaling portions may have substantially the same colors as each other. In another example, the light emitted by the fine dust signaling portions may have different colors.

The smart shelter system 3 of the present disclosure may include smart shelters (SS) that provide a place for the user to evacuate from sunlight, rain, snow, cold, and crime. Accordingly, the smart shelter system 3 can be used irrespective of the season, and can have high usability.

The smart shelter system 3 of the present disclosure may include smart shelters (SS) that are controlled by commands that the administrator inputs to the terminal device. Accordingly, a smart shelter system 3 capable of easily controlling and managing smart shelters SS can be provided.

The above description of embodiments of the technical idea of the present invention provides an example for explaining the technical idea of the present invention. Therefore, the technical spirit of the present invention is not limited to the above-described embodiments, but various modifications and changes may be made by those skilled in the art within the technical scope of the present invention, It is clear that this is possible.

Claims (20)

A first body portion extending in a first direction;
A second body extending from an upper portion of the first body portion in a second direction crossing the first direction;
An eyelash protruded from a side surface of the second body part; And
And a heater provided at a lower portion of the second body portion. The method according to claim 1,
The heater emits radiant heat,
The air below the canopy is heated by the radiant heat,
Wherein the shade film prevents the heated air from rising, thereby increasing the time that the air stays under the shading film. The method according to claim 1,
Wherein the heater is provided in a pair. The method according to claim 1,
And the heater protrudes from a bottom surface of the second body part. The method according to claim 1,
Wherein the heater extends along the second direction,
Wherein the length of the heater along the second direction is at least half the length of the second body along the second direction. The method according to claim 1,
And a photovoltaic module provided on the second body portion,
Wherein the heater is driven by at least one of power produced by the solar module and external power. The method according to claim 1,
And a display unit provided on a side surface of the first body part. The method according to claim 1,
And a charging unit provided on a side surface of the first body part,
Wherein the charging unit comprises at least one of a wired charging device and a wireless charging device. The method according to claim 1,
A lower illumination provided in the lower portion of the second body portion; And
And an upper illumination provided at an upper end of the first body part. 10. The method of claim 9,
Wherein the upper illuminator is disposed at a higher level than the second body portion. The method according to claim 1,
A photographing unit for photographing the periphery thereof; And
And a storage unit for storing the image photographed by the photographing unit. Awnings;
heater;
A communication unit for communicating with an external server; And
A processor,
The processor comprising:
Controls the shade film to expand or contract the shade film based on a control signal received by the communication unit, and controls the heater so that the heater is turned on or off. 13. The method of claim 12,
And a fine dust signal portion,
Wherein the processor controls the fine dust signal unit to emit light having a color corresponding to the fine dust concentration of the fine dust signal portion based on the control signal. 13. The method of claim 12,
A first body portion extending in a first direction;
A second body extending from an upper portion of the first body portion in a second direction crossing the first direction;
A lower illumination provided at a lower portion of the second body portion; And
And an upper illuminator provided at an upper end of the first body portion,
Wherein the processor controls the bottom lighting to turn on or off the bottom lighting based on the control signal and controls the top lighting to turn on or off the top lighting. 13. The method of claim 12,
And a photographing unit,
The processor controls the photographing unit to photograph the periphery of the photographing unit based on the control signal to generate moving image data, and controls the communication unit to transmit the moving image data to the external server. A first body portion extending in a first direction;
A second body extending from an upper portion of the first body portion in a second direction crossing the first direction;
An eyelash provided on the second body part;
A heater provided at a lower portion of the second body portion;
temperature Senser; And
A processor,
Wherein the processor controls the temperature sensor such that the temperature sensor measures the temperature to generate temperature data and operates the heater such that the heater emits heat when the temperature is below a reference temperature, The operation of the heater is stopped. 17. The method of claim 16,
Wherein the processor controls the shade film to expand the shade film when the heater is operated,
Wherein the extended sun shield film prevents the air heated by the heater from rising, thereby increasing the time that the air stays under the sun visor. 17. The method of claim 16,
And a weight sensor for measuring a weight applied to the shade film,
Wherein when the weight of the wing is in the extended state, the processor controls the winging film so that the winging film is inserted into the second body part when the weight is equal to or greater than the reference weight. 19. The method of claim 18,
And a display unit provided on the first body unit for outputting information,
Wherein the processor outputs a warning message regarding the operation of the shade film to the display unit before the shade film is operated to be inserted into the second body part. 17. The method of claim 16,
And a distance measuring sensor,
Wherein the distance measuring sensor measures a distance between the second body part and an object approaching the second body part at a height at which the second body part is disposed when the sun visor is extended, And controls the shade film to reduce the shade film when the distance is less than or equal to a reference distance.

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