RU189542U1 - Autonomous lighting system - Google Patents

Abstract

The invention relates to the field of lighting technology, namely, autonomous lighting systems (AOS), designed to illuminate at night, pedestrian crossings, bus stops, dangerous sections of roads and other areas without the need to connect to power supply lines. A photovoltaic module is installed, which contains a built-in solar battery in the upper part, and a LED luminaire with a diffusing canopy at the bottom. A battery compartment is attached to the solar battery case at the bottom, in which a thermal box with a rechargeable battery is stored to save the accumulated energy, a battery charge / discharge controller that automatically turns the lighting system on / off at dawn / dusk, and a thermal sensor connected to the corresponding controller input. The AOC also contains a second solar battery, which is located under the photovoltaic module and is connected to the corresponding input of the controller. Thermoboxing is made like a transformer coil, which on one side is equipped with a deaf insulated lid, and on the other - plug-in removable insulating cap. On the side surface of the coil frame is wound a heat-insulating layer with a thickness of about 5-10 cm, and on its inner walls, on the sides and bottom, there are longitudinal projections centering the position of the battery inside the thermal box. To maintain the set temperature inside the thermobox, heating elements are located on both sides of the inner side walls of the coil, the outputs of which are connected to the corresponding control inputs of the controller. 4 hp f-ly, 7 ill.

Description

The utility model relates to the field of lighting technology, namely, autonomous lighting systems (AOS) intended for lighting at night pedestrian crossings, bus stops, dangerous sections of roads and other territories without the need to connect to power lines.

A well-known autonomous lighting system "Sunlight 80" is used for street lighting of areas, parking places, park lighting, which includes a support to which the solar module FSM 310M, a lamp, and an underground metal box buried in the ground at the foot of the support are attached with brackets ( case), which houses the charge controller, battery and automation unit [1].

A disadvantage of the known autonomous lighting system is that in order to eliminate the influence of low temperatures on the charge controller and the battery, the latter are placed underground at the base of the support. For this purpose, a special underground box (case) is used, which, together with the equipment, is buried in the ground. However, this scheme of protecting equipment from low temperatures is extremely inefficient. In addition, access to equipment becomes more complicated when carrying out work on the replacement or routine inspection (repair) of its component parts.

The closest in technical essence to the claimed object is an autonomous lighting system containing a support on which a photovoltaic module is placed, containing in the upper part an integrated solar battery that converts sunlight into electricity, and a LED luminaire with a diffusing lampshield attached to the body from below a battery compartment in which a thermal box with a battery is placed to save stored energy, a charge / discharge optimizing controller A battery that automatically turns on / off the dawn / dusk lighting system, as well as a thermal sensor located inside the thermal box, the terminals of which are connected to the corresponding input of the controller, while the lighting system contains a second solar battery that is located below the photovoltaic module and connected to the corresponding input of the controller [2] PROTOTYPE.

One of the drawbacks of the system is that a thermobox (thermostat), AKB-12/7 Ah “Bastion” [3] is used to maintain the normal temperature conditions of the battery operation.

Thermobox is installed inside the battery compartment. Structurally, a thermobox is a rectangular body enclosed and heat-insulated from all sides, covered outside with heat-insulated layer. Inside the thermal box is a battery with elements of control and management of temperature. In some cases, for this purpose, a heat insulated case that is not convenient to use is used, or a thick-layer bag-trunk insulated on all sides, which, together with the battery and the monitoring and control system (controller), is placed inside the battery compartment.

One of the drawbacks of the known system is the complexity of the thermobox design. It does not provide effective elements of protection against hypothermia in the difficult Russian winters, when bad weather can act for many days. Under these conditions, the temperature in the battery compartment and inside the thermobox drops, which leads to disruption of the battery and electronic components of the control system (controller). As a result of these drawbacks, the reliability and efficiency of the entire lighting system is reduced.

In view of the above, the technical result of the claimed technical solution is to increase the reliability and efficiency of the autonomous lighting system by creating a simple, reliable and efficient construction of a thermobox.

The technical result is achieved by the fact that in a known autonomous lighting system containing a support on which a photovoltaic module is placed, contains in the upper part an integrated solar battery that converts sunlight into electricity, and a LED luminaire with a diffusing plafond from below, with a battery attached to the case from below. the compartment in which the thermal box with the battery is placed to save the accumulated energy, the controller that optimizes the charge / discharge of the battery is automatically turned on A yuchuyushchaya / deactivating lighting system at dawn / dusk, as well as a thermal sensor placed inside the thermal box, the findings of which are connected to the corresponding input of the controller, while the lighting system contains a second solar battery, which is located under the photovoltaic module and connected to the corresponding input of the controller, according to the declared technical to the solution, the thermobox contains a rectangular hollow frame placed on a pallet, made of a transformer coil type that is equipped with with a deaf heat-insulated lid, and on the other - a removable removable heat-insulating plug, while outside, on the side surface of the coil frame, wound a heat-insulating layer, about 5-10 cm thick, and on its inner walls, on the sides and bottom, are longitudinal projections, The centering position of the battery inside the thermobox, while on the inner side walls of the coil on both sides are placed heating elements, the outputs of which are connected to the corresponding control inputs of the controller.

The technical result is achieved by the fact that the height of the protrusions of the heating elements is 0.2-0.5 of the magnitude of the longitudinal protrusions placed on the inner side walls of the coil,

The technical result is also achieved by the fact that a self-adhesive heat-insulating tape material with a foil-coated surface is used as the heat-insulating layer in the thermobox.

The technical result is achieved by the fact that the thermal sensor is located in the cavity of the thermobox, in the upper middle part of it, and the controller is located outside, on the body of the thermobox, at the entrance in the upper part.

The technical result is also achieved by the fact that the thermal box contains an exhaust strap for discharging the battery from the casing to the outside.

The figures are schematically presented:

FIG. 1 - frontal projection of an autonomous lighting system.

FIG. 2 - profile projection of an autonomous lighting system.

FIG. 3 - photovoltaic module (front view).

FIG. 4 - photovoltaic module (side view).

FIG. 5 - thermobox (front view).

FIG. 6 - thermobox (side view).

FIG. 7 is a diagram of connecting AOC elements to the controller inputs.

The autonomous lighting system presented in the figures (Fig. 1, Fig. 2) contains support 1 placed on the foundation mortar rack 2. In the upper part of support 1 an LED lamp 3 with an embedded solar battery 4 is placed at an angle of 15 °. The base of the LED lamp 3 by means of a flange connection 5 is attached to the battery compartment 6, with a removable side cover 7. The lighting system contains a second solar battery 8, which is located below, and attached to the support 1 with clamps 9. Inside the battery from Eka 6 (Fig. 3, Fig. 4) placed a thermal box 10 with a battery 11 to save stored energy, a controller 12 that optimizes the charge / discharge of the battery, automatically turning on / off the lighting system at dawn / dusk, as well as a thermal sensor 13 that is placed in the cavity of the thermobox 10 in the upper middle part, and the controller 12 is located outside, on the body of the thermobox 10, at the entrance in the upper part.

Thermobox 10 (Fig. 5, Fig. 6) contains a rectangular hollow frame 15 placed on a pallet 14, made in the form of a transformer coil, which on one side is equipped with a deaf heat-insulated cover 16, and the other with an insertable removable heat-insulating cap 17, while , on the side surface of the frame of the coil 15, the heat-insulating layer 18 is wound, about 5-10 cm thick, and on its inner side walls 19 and bottom 20, longitudinal projections 21 are placed, centering the position of the battery 11 inside the thermobox 10. On the inside nnih sidewalls coil 19 from both sides (mirror) has the heating elements 22.

In order to prevent direct contact of the heating elements 22 with the case of the battery 11, the height of the projections of the heating elements 22 is 0.2-0.5 of the magnitude of the longitudinal protrusions 21 located on the inner side walls 19 of the thermobox 10.

The thermo-insulating layer 18 in the thermobox 10 uses a self-adhesive heat-insulating tape material with a foil surface, and the thickness of the heat-insulating layer is 5-10 cm, which ensures reliable thermal protection of the battery 11 from overcooling during the cold winter period.

To provide convenience when unloading the battery 11 to the outside of the thermal box 10, a special belt is used that covers the battery 11 along its outer contour (the belt is not shown in the figures).

The battery compartment 6 (Fig. 4) is made in the form of a rectangular box cut in the upper part at an angle of 15 ° and is equipped with a flange connection 5 for fastening it to the base of the housing of the LED lamp 3.

When preparing the AOC for operation, a thermal box 10, with the battery 11 placed inside, is carefully installed through the side opening into the battery compartment 6. Then, the operating outputs of the elements of the autonomous lighting system are connected to the control inputs of the controller 12 (Fig. 7): XP2 and XP3 are connected, respectively, the outputs of the lines of the lamp 3; a battery 10 is connected to the input XP4; Thermal sensor 13 and heating elements 22 are connected to input XP5 and outputs of integrated solar battery 4 and additional solar battery 8 are connected to inputs XP6 and XP7. Then controller 12 is placed in the upper outer part of thermobox 10. After connecting all outputs of AOC elements to controller input 12, a removable heat-insulating plug 17 is tightly installed in the open opening of the thermobox 10. Then the side removable cover 7 is tightly screwed to the body of the battery compartment with 6 self-tapping screws.

Autonomous lighting system works as follows.

In cloudless weather, the system accumulates solar energy and stores it in the battery 11. For the period from dusk to dawn, the controller 12 automatically switches on the lighting using battery power 11. The chart of sunsets and sunrises, as well as the system time, is individually adjusted for a particular region of the country. Throughout the daylight hours, the solar battery 4 absorbs solar energy and converts it into electrical energy, which accumulates in the battery 11. The controller 12 protects the battery 11 from overcharging and excessive overdischarge, which ensures a long-term service life. In addition, the solar battery 4 will also perform the function of a light sensor, i.e. at nightfall, the controller 12 automatically turns on the LED lamp 3, which shines all night until dawn, after which the controller 12 turns off the lights and resumes charging the battery 11.

The technical result from the use of the claimed utility model is that the construction of the thermobox is significantly simplified, which in comparison with the closest analogues (insulated boxes, trunks, etc.) can significantly increase the reliability and energy efficiency of the entire lighting system.

At present, a prototype model of a thermobox has been developed, integrated into an existing autonomous lighting system, which has successfully passed preliminary tests at a manufacturing plant.

Information sources

1. Website: enpartner.ru> index ... magazin ... avtonomnaya-sistema

2. Website: telemehanika.com> produkciva / avtonomnv ... nava ... aos ... 80

3. Website: bast.ru> Products> Outdoor UPS> Thermostat akb-12/7 Ah

Claims (5)

1. An autonomous lighting system containing a support on which a photovoltaic module is placed, containing a built-in solar battery in the upper part, which converts sunlight into electricity, and a LED luminaire with a diffusing plafond to the bottom, to which a thermal box is attached to the case with rechargeable battery to save the accumulated energy, the controller that optimizes the charge / discharge of the battery, automatically turns on / off the lighting system at dawn The cathe as well as the thermal sensor placed inside the thermobox, the outputs of which are connected to the corresponding controller input, while the lighting system contains a second solar battery that is located under the photovoltaic module and connected to the corresponding controller input, characterized in that the thermal box contains a hollow frame placed on the pallet rectangular shape, made as a transformer coil, which on one side is equipped with a deaf heat-insulated cover, and on the other - plug-in removable heat insulator a stub, while outside, on the side surface of the coil frame, wound a heat-insulating layer, about 5-10 cm thick, and on its inner walls, on the sides and bottom, are placed longitudinal projections centering the position of the battery inside the thermobox, while on the inner side The coil walls are located on both sides of the heating elements, the outputs of which are connected to the corresponding control inputs of the controller. 2. Autonomous lighting system under item 1, characterized in that the height of the projections of the heating elements is 0.2-0.5 from the magnitude of the longitudinal projections located on the inner side walls of the coil. 3. The self-contained lighting system according to claim 1, characterized in that a self-adhesive heat-insulating tape material with a foil-coated surface is used as the heat-insulating layer in the thermobox. 4. The autonomous lighting system according to claim 1, characterized in that the thermal sensor is located in the cavity of the thermal box, in the upper middle part of it, and the controller is located outside, on the body of the thermal box, at the entrance in the upper part. 5. Autonomous lighting system according to claim. 1, characterized in that the thermal box contains an exhaust strap for discharging the battery from the casing to the outside.

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