ITRM20130086A1 - DEVICE AND SYSTEM FOR LIGHTING AND ROAD AND ENVIRONMENTAL SAFETY - Google Patents

Description

DESCRIPTION

`` DEVICE AND SYSTEM FOR LIGHTING AND ROAD AND ENVIRONMENTAL SAFETY ''

TECHNICAL FIELD OF INVENTION

The present invention relates to a device and a system for lighting and safety, in particular for lighting and road safety, that is to say for the lighting and safety of a road, a motorway, a parking lot, a square, a roundabout, etc.

STATE OF THE ART

As is known, in Italy street lighting is largely made with older generation systems that use high and / or low pressure sodium vapor lamps and / or metal halide lamps and / or lamps mercury vapors which by now should be eliminated as they no longer comply with current regulations on the use of certain hazardous substances in electrical and electronic equipment (in this regard, for example, reference can be made to Community Directive 2002/95 / EC so-called â € œRoHSâ €), on light pollution and on the reduction of greenhouse gas / CO2 emissions (in this regard, for example, reference can be made to the Kyoto Protocol 1 and 2 (Durban 10.12.11)).

Unfortunately, however, the need to massively replace all the street lighting fixtures that do not comply with the law clashes and is very often held back by the very high costs associated with replacement operations.

OBJECT AND SUMMARY OF THE INVENTION

The Applicant has conducted a very in-depth study to try to find a way to favor the replacement of non-compliant street lighting fixtures.

Therefore, the purpose of the present invention is to provide a street lighting system that favors the replacement of non-compliant street lighting fixtures.

The aforesaid object is achieved by the present invention as it relates to a device and a system for lighting and road and environmental safety, as defined in the attached claims.

In particular, the present invention relates to a device for lighting and road safety designed to be connected to an electrical power supply network and comprising:

â € ¢ a street lighting fixture based on LED technology;

â € ¢ a surveillance camera configured to capture a video stream of the surrounding environment;

â € ¢ means of control and communication which are connected to the street lighting fixture based on LED technology and to the surveillance camera, and which are configured for

- communicate and exchange data with, and receive commands from, an operational control center via the power supply network using power line technology (PLC) and / or via wireless communication technology,

- send the video stream captured by the surveillance camera to said operational control center,

- check the operation of the street lighting device based on LED technology and of the surveillance camera on the basis of respective commands received from the control operations center, - perform a self-diagnosis of the entire device for the lighting and road safety, e

- generate and send to said operational control center, for example in response to a request from the latter, a self-diagnosis report that indicates whether the entire device is functioning correctly, if there are faults and, in case of failure, the type of fault and the component affected by the fault; And

â € ¢ vehicles designed to connect one or more additional sensors and / or devices to the lighting and road safety device.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the present invention, some preferred embodiments, provided purely by way of non-limiting explanatory example, will now be illustrated with reference to the attached drawings (not to scale), in which:

â € ¢ Figures 1 and 2 illustrate two examples of embodiment of a device for lighting and road safety according to the present invention;

â € ¢ Figure 3 schematically illustrates the architecture of a device for lighting and road safety according to a preferred embodiment of the present invention; And

â € ¢ Figure 4 schematically illustrates the architecture of a lighting and road safety system according to a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF PREFERRED FORMS OF REALIZATION OF THE INVENTION

The following description is provided to enable a person skilled in the art to make and use the invention. Various modifications to the embodiments presented will be immediately evident to skilled persons and the generic principles disclosed herein could be applied to other embodiments and applications without, however, thereby departing from the scope of protection of the present invention.

Therefore, the present invention must not be understood as limited only to the embodiments described and shown, but it must be granted the widest scope of protection consistent with the principles and characteristics presented here and defined in the attached claims.

The present invention arises from the Applicant's intuition to try to favor the replacement of street lighting fixtures that do not comply with the law, making the replacement, on the one hand, more sustainable from an economic and environmental point of view and, on the other on the other hand, more attractive thanks to the installation of new lighting devices capable, on the one hand, of rapidly amortising replacement costs and, on the other hand, of providing one more additional services than simple street lighting.

In particular, the Applicant has understood that the costs for the replacement of street lighting fixtures that do not comply with the law can be decidedly contained, if not even eliminated, by the considerable savings obtained on energy costs thanks to the use of the new LED technology (from English â € œLight Emitting Diodeâ €, or light emitting diode) which complies with current regulations on energy saving, light pollution and the reduction / zeroing of greenhouse gas emissions / CO2.

Furthermore, the Applicant has also devised to replace the old luminaires with new concept luminaires, which are multi-function and which are also designed to respond to another primary need of the community, namely safety, so that their installation is extremely attractive.

All without the need for new wiring, excavations, road surface restoration works and, in general, construction sites which for a long time, in addition to reducing vehicular traffic, jeopardize the life of the workers involved, the forces of order, of motorists and pedestrians.

In particular, these multi-function luminaires are equipped with a dedicated system:

â € ¢ electronic surveillance through the use of one or more sensors for monitoring the surrounding environment, specifically at least one camera; and

â € ¢ to the transfer of the data provided by the sensors, specifically at least of the video stream captured by the camera, to an operational control center using conveyed wave technology (in English â € œPower Line Communicationâ € â € “PLC) and / or through one or more wireless communication technologies, i.e. wireless, such as WiFi technology and / or one or more cellular telephone technologies, such as GSM technology (from English â € œGlobal System for Mobile Communicationsâ €), the GPRS technology (from English â € œGeneral Packet Radio Serviceâ €), EDGE technology (from English â € œEnhanced Data rates for GSM Evolutionâ €), UMTS technology (from English â € œUniversal Mobile Telecommunications Systemâ € ), HSPA technology (from English â € œHigh Speed Packet Accessâ €) and LTE technology (from English â € œLong Term Evolutionâ €).

Thanks to the use of conveyed wave technology (which in the following, for simplicity of description, will also be called PLC technology) and / or one or more of the aforementioned wireless communication technologies, it is not necessary to make wiring to connect the new ones. multi-function luminaires to the control operations center and, therefore, there is no additional wiring cost.

For a better understanding of the present invention, figure 1 shows a device for lighting and road safety (indicated as a whole with 1) according to an exemplary embodiment of the present invention.

In particular, as shown in figure 1, the device 1 comprises a pole 11 on which a LED lamp 12 (with integrated heatsink) is fitted at the top (for example by means of a joint) into which a camera 13 is conveniently integrated. equipped with an audio sensor. The LED lamp 12 can, for example, comprise 112 LEDs, or 112 light emitting diodes, for an overall brightness of 11200 lumens.

In an alternative embodiment shown in Figure 2, instead of, or in addition to, said camera 13 integrated in the LED lamp 12 (also) a pivoting camera 14 is used (also conveniently equipped with an audio sensor) fixed to pole 11 (always without prejudice to the use of an LED lamp).

In order to describe the present invention in greater detail, Figure 3 shows, in the form of a block diagram, the architecture of a device for lighting and road safety (indicated as a whole with 2) according to a preferred embodiment of the present invention.

In particular, as shown in figure 3, the lighting and road safety device 2 includes:

â € ¢ a LED 21 luminaire for street lighting;

â € ¢ a surveillance camera 22 (digital or analog) configured to capture a video stream (or a sequence of images) of the surrounding environment;

â € ¢ an audio sensor 23 (digital or analog) which is configured to capture an audio stream from the surrounding environment and which may or may not be integrated into the surveillance camera 22;

â € ¢ one or more further sensors and / or devices 24, such as for example a temperature sensor and / or a fire sensor and / or a button to request help and / or audio reproduction means, etc., to implement functions of surveillance and monitoring and / or anti-panic and / or fire and / or anti-crime and / or anti-theft and / or request for help and / or sending / receiving instructions and / or alarms, etc .;

â € ¢ means of control and communication 25 that

- they can be made through a single component (for example an appropriately configured electronic control unit) or in the form of an electronic system comprising a plurality of components, and

- they are connected to the LED luminaire 21, the surveillance camera 22, the audio sensor 23, the said further sensor (s) and / or device (s) 24 and to a power supply network (not shown in the figure 3 for simplicity of illustration).

In detail, the control and communication means 25 are configured for:

â € ¢ supply the power supply to the LED device 21, the surveillance camera 22, the audio sensor 23 and said further sensor (s) and / or device (s) 24;

â € ¢ controlling the operation of said LED device 21, of said surveillance camera 22, of said audio sensor 23 and of said further sensor (s) and / or device (s) 24; And

â € ¢ communicate with an operational control center (not shown in figure 3 for simplicity of illustration) through the power supply network using PLC technology and / or via radio using WiFi and / or GSM and / or GPRS technology and / o EDGE and / or UMTS and / or HSPA and / or LTE.

Going even more in detail, the control and communication means 25 are configured for:

â € ¢ exchange data with the control operations center;

â € ¢ receive commands from said operational control center;

â € ¢ sending to said operating control center the video stream captured by the surveillance camera 22 and the audio stream captured by the audio sensor 23;

â € ¢ check the operation of the LED luminaire 21 on the basis of respective commands received from the control operations center, in particular

- turn on said LED device 21 in response to a respective switch-on command received from the control operation center, - turn off said LED device 21 in response to a respective switch-off command received from the control operation center, and

- varying the intensity of illumination produced by said LED luminaire 21 in response to a respective command to vary the intensity of illumination received from the operational control center;

â € ¢ check the operation of the surveillance camera 22 on the basis of respective commands received from the control operations center, in particular

- turning on said surveillance camera 22 in response to a respective switch-on command received from the control operations center,

- turning off said surveillance camera 22 in response to a respective shutdown command received from the control operating center, e

- aiming said surveillance camera 22 in an aiming direction indicated in a respective aiming command received from the operational control center;

â € ¢ check the operation of the audio sensor 23 and of said further sensor (s) and / or device (s) 24 on the basis of respective commands received from the control operations center, in particular

- turning on said audio sensor 23 in response to a respective ignition command received from the control operational center,

- turn off said audio sensor 23 in response to a respective shutdown command received from the control operations center,

- turning on a further sensor / device 24 in response to a respective ignition command received from the control operating center, and

- turning off said further sensor / device 24 in response to a respective shutdown command received from the control operating center; and,

â € ¢ in response to a request received from the control operations center, perform a self-diagnosis of the entire device 2, and generate and send a self-diagnosis report to said control operating center which indicates whether the entire device 2 it works correctly, if there are faults and, in the event of a fault, the type of fault and the component affected by the fault.

Figure 4 also shows, in the form of a block diagram, the architecture of a system for lighting and road safety (indicated as a whole with 3) according to a preferred embodiment of the present invention.

In particular, as shown in figure 4, the lighting and road safety system 3 includes:

â € ¢ a plurality of lighting and road safety devices 2 as previously described;

â € ¢ an operational control center 31; and

â € ¢ an electrical power supply network 32 to which the lighting and road safety devices 2 and the control operations center 31 are connected.

As previously described, according to the present invention, the operational control center 31 and the devices for lighting and road safety 2 can communicate through the power supply network 32 using PLC technology and / or through one or more of the aforementioned technologies. wireless communication.

In this way, the operational control center 31 remotely controls all the lighting and road safety devices 2 by sending respective commands and data and receiving the respective audio and video streams, the respective data and the respective self-diagnosis reports.

Briefly summarizing, therefore, the device for lighting and road safety according to the present invention allows to transmit the CCTV video signal (Closed Circuit Television - images from cameras for audio-video surveillance) on conveyed waves, so as to be able to be used as a real integrated safety device capable of providing images from a camera located on the pole (street lamp) to a remote control center.

The device according to the present invention can also be conveniently equipped with some standard RJ-45 connectors available to connect any further sensors / devices in order to implement further functions, such as surveillance and monitoring and / or panic and / or fire and / or anti-panic functions. anti-crime and / or anti-theft and / or request for help and / or sending / receiving of instructions and / or alarms, etc. .. The control of these additional sensors / devices will always be centralized in the operational control center.

Conveniently, a special programmable logic controller (in English â € œProgrammable Logic Controllerâ €) will allow the video surveillance a constant power supply / operation (24h) even in the presence of a limited power supply / operation (12h) of the lighting; in other words, the functioning of the electronic surveillance (all the sensors and safety and surveillance devices) will be completely independent from the lighting / functioning.

Preferably, PLC digital power transmission occurs at 500 Mbps via the international HOMEPLUG®AV protocol which represents a reliable and super-tested standard throughout the world.

The use of LED technology saves over 40% of the energy destined for public lighting compared to the best traditional technologies (high pressure sodium vapor and metal halide lamps) and up to 70% compared to traditional technologies with lower efficiency (mercury vapor lamps) with a consistent containment of energy costs and a low environmental impact, thanks to lower CO2 emissions, a gas considered to be the main responsible for the greenhouse effect (in fact, LEDs emit a light that does not produce heat).

The LED solution represents a great and concrete step forward in achieving the objectives of sustainability and respect for the environment since, in addition to low energy consumption, there are other aspects to consider, including waste reduction, recyclability, use of materials and resources.

LED lamps are innovative lighting products and systems that use semiconductor technology, perfectly combining the quality of lighting with a significant reduction in energy consumption and respect for the environment.

The LED lighting system, which is powered in low voltage, therefore guarantees considerable advantages (indicated below) compared to traditional high-pressure mercury vapor lamps or the â € œinnovativeâ € high and low sodium vapor lamps. low pressure currently used in public street lighting.

First, the light emitted by the sodium vapor lamps is yellow and does not correspond to the peak sensitivity of the human eye; colors are not reproduced faithfully and therefore more light is needed to ensure safe viewing.

LED lamps, on the other hand, emit white light that allows for safe lighting for road users (lowers reaction times to unexpected events), with less energy consumption; the white light also passes through the fog much better, making vehicles more visible and thus ensuring greater safety for road users.

The LED lighting significantly increases the quality of the images captured at night by road video surveillance cameras, an aspect that in the past has also considerably affected the judicial police activity (alteration of the real livery of the vehicle, limited power produced by infrared illuminators; aspects that negatively affect the vision of the scene, the depth of the field and the correct recognition of the vehicle).

The color rendering index (CRI) indicates the fidelity of color reproduction:

â € ¢ is worth 20 for sodium vapor lamps (yellow light);

â € ¢ while it is worth 80 for LED lamps (white light). The idea of linking LED technology to public street lighting also derives from the latest scientific discoveries in the perceptual field. In fact, the studies on the visibility with the white light are based on the fact that, according to the luminance, people use or not all the perceptive apparatuses of the eye (cones and rods); greater visibility for motorists, greater safety for pedestrians, thus ensuring suitable conditions of visual comfort for users.

The results indicate that light sources with a predominant spectrum in the blue band, such as LEDs, are preferred, without requiring high luminance values.

The high / low pressure sodium vapor lamps have a spectrum centered in the red band, far outside the peak sensitivity of the human eye.

It can therefore be said that with sodium vapor lamps, the light output must be increased by 50% to ensure safe vision.

Secondly, the mercury or sodium vapor lamps, being omnidirectional, diffuse the light in all directions and it is necessary to equip the lamp with a parabola to recover half of it. Therefore, the final luminous efficiency (use / yield) is 50% compared to that emitted.

The LED is directional by construction and emits a 90 lumen / watt defined 90 ° light beam (350mA power supply) and therefore reduces light pollution to a minimum.

The LED can even be interfaced with secondary optics (in polymethylmethacrylate or pMMA) to further narrow the light beam.

Thirdly, the use of LED as a solid state light source (SSL - â € œSolid State Lightingâ € - light source from a diode rather than from a glass bulb with a filament or glass tube filled with gas) , guarantees sturdiness of the structure and reliability over time, its duration is estimated at 50,000 / 60,000 hours (11-13 years, with 12 hours a day of ignition) against the 12,000 hours (31 months) of sodium vapor lamps. high pressure and the 10,000 hours (26 months) of mercury vapor lamps.

According to estimates, after 50,000 / 60,000 hours the brightness of the LED systems drops to 80% of the initial value and this can be considered the end of the useful life of the LED.

The luminous flux index of LEDs is nil after 3,000 hours of operation, indeed in the first 5,000 hours it increases slightly, while sodium vapor lamps after 3,000 hours of ignition, on the other hand, have a reduction in luminous flux up to to 40%.

A system of LED lamps according to the present invention therefore comprises a series of lamps installed in different environments, such as urban and suburban roads, highways, squares, roundabouts, pedestrian paths, underpasses, tunnels, parking lots, etc., with the large simplification of supervision that remote control allows:

â € ¢ variation of the brightness system and therefore of the power absorbed by the lamps during the day, optimizing energy costs;

â € ¢ the use of PLC technology makes it possible to communicate with each single lamp, using the same electric line, already wired, for its power supply, avoiding the further wiring of telephone pairs or optical fibers for data transmission;

â € ¢ PLC technology duly integrated with the services offered by modern TCP / IP networks, easily allows remote control of the systems via Internet / Intranet, allowing the person in charge (client) to comfortably / constantly supervise the systems (diagnostics, operation, LED brightness control, etc.) from a remote control center and to know perfectly the situation of the system, lamp by lamp, without having to send any operator on site.

In the field of telecommunications, PLC technology, ie conveyed wave technology, is a technology for the transmission of voice or data, which uses the power supply network as a transmission medium.

It is achieved by superimposing on the transport of electric current, direct or alternating at low frequency (50 Hz in Europe and most of Asia and Africa, 60 Hz in other regions of the world), a signal with a higher frequency than It is modulated by the information to be transmitted.

The separation of the two types of currents is carried out thanks to the filtering and separation of the frequency ranges used.

The technique has therefore been used for decades (exclusively for the transmission of voice or data) before the introduction of mobile telephony, for transmissions with running trains, to control electrical equipment via its own power supply network, to read meters remotely. electrical, for home intercom systems, etc.

More recently it has been used to give data access (for example the Internet) to homes via the electrical network without the need for specific access for coaxial cable or radio.

The use of conveyed waves (PLC), no longer only used to transmit voice and data, thanks to a device (hardware and software) specially designed, also allows the CCTV video signal to be transmitted using the power supply network, allowing / thus realizing the possibility of using the lighting system as a real integrated security system, capable of providing images from a camera, located on any pole (lamp post), equipped with the particular device for street lighting , to a remote control center.

From the foregoing description the advantages of the present invention can be immediately understood.

In particular, it is important to underline the fact that the present invention makes it possible to create a public lighting system with high energy savings, with low or even negligible CO2 emissions (light that does not produce heat), which respects the environment and European regulations relating to light pollution, has a visual yield above any expectation (natural lumens such as sunlight) and allows self-financing resulting from use. In fact, the administrations that opt for this solution achieve significant / unimaginable savings over the medium / long term.

Furthermore, as previously described, the present invention allows remote control of street lighting devices by means of PLC and / or WiFi technology. In particular, in case of use of WiFi technology, the manager of the community where the system according to the present invention will be installed, by replacing only the fixtures already in place (luminaires with sodium or mercury vapor lamps), will be able to supply its entire community the Wi-Fi service (free or with payment of a modest fixed fee).

Furthermore, with the present invention each public lighting pole (street lamp) can be conveniently transformed into an anti-panic unit, since it is possible to speak to a remote control center (using the surveillance camera and the audio sensor present on the pole to be seen and heard, a possible button provided specifically on the pole to request help and any audio reproduction means provided specifically on the pole to hear the voice of the operator present in the remote control center), receiving immediate verbal assistance and / o rescue by the operator in charge and / or by re-launching the request to the police; the operator will also be able to see the images of the person making the emergency call.

Furthermore, the continuous capillary remote control of the entire street lighting network allows the adjustment of the luminous flux, the reception of alarms relating to any anomalies of the lighting poles (armature / camera out of service, etc.), the programming of the lighting poles. Armor switching on and off, etc ..

The present invention can also allow the possible sale of services to interested third parties (companies, traders, individuals). In fact, the system lends itself well to further implementations, such as the possible centralization of the alarm systems of the community served and protected by the infrastructure itself.

To conclude, every single pole (street lamp) can be seen as an active part of an infrastructure destined to carry out multiple functions in favor of the individual, the community, society (Smart City) and not only as a source to illuminate the darkness of the streets.

Finally, it is clear that various modifications can be made to the present invention, all falling within the scope of protection of the invention, as defined in the attached claims. For example, we want to emphasize here the fact that the present invention can be advantageously exploited, as well as on a road, a motorway, a parking lot, a square, a roundabout, etc., also for the lighting and monitoring of outdoor areas, i.e. outdoors, of a house, a school, a condominium, a building, a park, a construction site, a stadium, a prison, a factory, an energy production and / or distribution center, a port, an airport, a station, a bank, a company headquarters, an office, etc.

Claims (8)

CLAIMS 1. Lighting and road safety device (2), designed to be connected to an electrical power supply network (32) and comprising: â € ¢ a street lighting fixture based on LED technology (21); â € ¢ a surveillance camera (22) configured to capture a video stream of the surrounding environment; â € ¢ means of control and communication (25) which are connected to the luminaire for street lighting based on LED technology (21) and to the surveillance camera (22), and which are configured for - communicate and exchange data with, and receive commands from, a control operations center (31) via the power supply network (32) using power line technology (PLC) and / or via wireless communication technology, - sending the video stream captured by the surveillance camera (22) to said operational control center (31), - check the operation of the street lighting luminaire based on LED technology (21) and of the surveillance camera (22) on the basis of respective commands received from the control operations center (31), - perform a self-diagnosis of the entire lighting and road safety device (2), and - generate and send to said operational control center (31) a self-diagnosis report which indicates whether the entire device (2) is functioning correctly, if there are any faults and, in the event of a fault, the type of fault and the affected component from failure; And â € ¢ means designed to connect one or more additional sensors and / or devices to the lighting and road safety device (2). The device of claim 1, wherein the control and communication means (25) are further configured for: â € ¢ switch on the street lighting fixture based on LED technology (21) in response to a respective switch-on command received from the control operations center (31); â € ¢ turn off said street lighting device based on LED technology (21) in response to a respective shutdown command received from the control operations center (31); And â € ¢ vary the intensity of illumination produced by said luminaire for street lighting based on LED technology (21) in response to a respective command to change the intensity of illumination received from the control operations center (31) . The device according to claim 1 or 2, wherein the control and communication means (25) are further configured to point the surveillance camera (22) in a pointing direction indicated in a respective pointing command received from the operations center control (31). The device according to any preceding claim, further comprising an audio sensor (23) configured to capture an audio stream from the surrounding environment; and in which the control and communication means (25) are also connected to said audio sensor (23) and are also configured for: â € ¢ send the audio stream captured by the audio sensor (23) to the operational control center (31); And â € ¢ check the operation of said audio sensor (23) on the basis of respective commands received from the control operations center (31). The device according to any preceding claim, comprising one or more further sensors and / or devices (24); and in which the control and communication means (25) are also connected to each further sensor / device (24) and are also configured to control the operation of each further sensor / device (24) on the basis of respective commands received from the control center control (31). The device according to any preceding claim, wherein the wireless communication technology comprises the WiFi technology. The device according to any preceding claim, wherein the wireless communication technology comprises one or more cellular telephone technologies. 8. System for lighting and road safety (3), comprising: â € ¢ a plurality of lighting and road safety devices, each of which has the same characteristics and is configured in the same way as the lighting and road safety device (2) claimed in any one claim previous one; and â € ¢ an operational control center (31) designed to be connected to an electrical power supply network (32) and to communicate and exchange data with, and to send commands to, said lighting and road safety devices ( 2) through the power supply network (32) using power line technology (PLC) and / or through wireless communication technology.