阅读说明：本技术 高效led灯 (High-efficiency LED lamp ) 是由 安杰洛·博尼 于 2018-06-06 设计创作，主要内容包括：一种LED灯,包括：基座(3),设置有连接到电能源的附件；多个LED行(4),每个LED行可单独调节和控制以接通和断开；微处理器(24),被预设置以控制LED行(4)；通信模块(25),连接到微处理器(24),被预设置以接收和发送灯的控制信号；电源(16),预设置以为LED行(4)供电；检测装置(17),连接到微处理器(24),预设置以检测灯在空间中的位置和方向。(An LED lamp comprising: a base (3) provided with accessories connected to an electric energy source; a plurality of LED rows (4), each LED row being individually adjustable and controllable to be switched on and off; a microprocessor (24) predisposed to control the rows of LEDs (4); a communication module (25), connected to the microprocessor (24), predisposed to receive and transmit lamp control signals; a power supply (16) preset to power the LED rows (4); detection means (17), connected to the microprocessor (24), are predisposed to detect the position and orientation of the lamp in space.)

1. An LED lamp comprising:

a base (3) provided with accessories connected to an electric energy source;

a plurality of LED rows (4), each LED row being individually adjustable and controllable to be switched on and off;

the LED lamp includes:

a microprocessor (24) predisposed to control said rows of LEDs (4);

-a communication module (25), connected to said microprocessor (24), predisposed to receive and transmit control signals of said lamps;

a power supply (16) predisposed to supply power to the LED row (4);

the method is characterized in that:

the lamp comprises detection means (17), said detection means (17) being connected to said microprocessor (24), being preset to detect the position and orientation of the lamp in the space and for sending to said microprocessor a piece of information (24) corresponding to the position and orientation of the lamp in the space;

the microprocessor (24) is predisposed to selectively control the switching on of one or more of the LED rows (4) according to the piece of information received from the detection means (17).

2. The lamp according to claim 1, wherein the communication module (25) is pre-set to receive and transmit one or more of the following control signals of the lamp:

switching on one or more of the LED rows (4);

-switching off one or more of said LED rows (4);

-adjusting the luminosity emitted by one or more of said rows (4) of LEDs.

3. Lamp according to claim 1, wherein the communication module (25) is pre-set to send diagnostics on the operational state of the lamp.

4. Lamp according to claim 1, wherein said microprocessor (24) is pre-set to control some of said LED rows (4) to be switched on and other of said LED rows (4) to be switched off with respect to the position of the lamp detected by said detection means (17).

5. The lamp according to claim 1, wherein the communication module (25) is pre-set to detect signals transmitted by one or more transmitting devices present in a reception area of the communication module (25) and to transmit signals indicative of the position of the transmitting devices and/or indicative of the content of the signals received by the transmitting devices.

6. A lamp according to claim 1, wherein each of said rows of LEDs (4) is associated with a first support (18), said first supports (18) being in turn associated with a connector (20) through a rotary joint (19), said rotary joint (19) being able to vary the inclination of said first supports (18) with respect to said connector (20).

7. Lamp according to claim 6, wherein the first support (18) comprises a heat sink (14) and wherein the base (3) is provided with accessories (23) each predisposed to enable connection of the connector (20) and provided with at least one slot (30), said slot (30) enabling the passage of an air flow to cool the LED (4) and the heat sink (14) associated with the connector (20).

8. The lamp of claim 6, wherein:

each of said connectors (20) comprises three electrical sources aligned with each other, one central pole and two lateral poles;

the base (3) is provided with appendages (23), each predisposed to enable connection to the connector (20), and with three electrical sources aligned with each other, one central pole and two lateral poles;

the two lateral poles have the same polarity opposite to the polarity of the central pole.

9. An illumination device, comprising:

a plurality of lamps (50) according to one of the preceding claims, wherein the communication module (25) is capable of transmitting information signals and control signals to the communication modules (25) of the other lamps (50) and of receiving the information signals and the control signals from the communication modules (25) of the other lamps (50);

-a programming module (40) predisposed to send control instructions to the communication module (25) of the lamp (50) and predisposed to receive the information signal from the communication module of the lamp (50).

10. The lighting device according to claim 9, wherein the control signal transmitted by the programming module (40) comprises one or more of the following controls:

switching on one or more LED rows (4);

-switching off one or more of said LED rows (4);

-adjusting the luminosity emitted by one or more of said rows (4) of LEDs.

11. The lighting device according to claim 9, wherein the information signal transmitted by each of the communication modules (25) comprises one or more of the following items of information:

interrupting the power supply to each of the lamps (50);

a requirement to change the intensity of light emitted by the remote device;

presence of the remote device;

the content of the signal emitted by the remote device;

-operating state of each of said lamps (50).

Background

High-efficiency illumination lamps, which are composed mainly of white LEDs, are becoming increasingly popular and even replace (fluorescent) gas discharge lamps due to their higher efficiency and long service life of the LEDs. Although they are more expensive than other types of lamps, they are approximately twice as energy efficient as fluorescent lamps and have three to four times longer life. With these efficiency and lifetime parameters, it is clear that the cost savings of the LED lamp over the lifetime cover well the higher costs. The object of the present invention is to further improve the performance of accessory lamps of the edison type (e.g. E27, E40) and all lamps with a rotary-type accessory system, in particular screw-threaded accessories, which once screwed in cannot perform a single positioning of the lamp.

The primary requirement is to distribute the light emitted, for example, in road lighting in the direction of the road. In this case, a greater degree of illumination is required in the direction of travel, while less or no illumination is required at the sides of the illuminating body. In fact, such side lighting is not useful for illuminating the road surface, and when it comes to the houses at the roadside, it can even cause injury to the people living there and therefore the people who are forced to close the shutters to obtain darkness overnight.

Fig. 1 and 2 show examples of known types of LED lamps. The lamp comprises a plurality of rows (4) of LEDs mounted on an insulating base (3) supporting them. The lamp is provided with an edison-type screw connector (2) for attachment to existing equipment so that an incandescent or fluorescent lamp can be replaced without any modification to the existing structure.

The lamp is also provided with slots (6), which slots (6) together with other slots (5) present on the insulating base (3) circulate cooling air, which can be achieved by natural convection or by forced convection by a fan.

As shown in fig. 2, the lamp is also provided with a heat sink (4a) which may be separate for each LED row (4) or a single heat sink joined. The heat sink comprises, for example, one or more fin strips associated with the LED rows (4).

The LED rows (4) can be lit together, as can the upper LEDs (24) present in the upper part of the lamp. The simultaneous turning on of all LEDs will emit light in all desired directions and in all unwanted scattering directions.

Each row of LEDs may be lit separately from the other rows. However, when the lamp is rotated to an undefined screwed-in position, this will not correctly select the row of LEDs that is directed in the desired direction. Therefore, the switching on of the selected LED row should be performed after screwing in the lamp. This operation is rather cumbersome and laborious considering that several hundreds of lamps can be arranged in succession along a path. Furthermore, the upper LED (24) is activated only when the lamp is facing downwards, whereas the upper LED (24) is not useful when the lamp is facing upwards.

Disclosure of Invention

The aim of the invention is to automate the adjustment process of the area illuminated by a lamp, irrespective of the direction of the lamp, and by replacing the lamp with another lamp. The desired lighting pattern may be automatically switched from one lamp to another, thereby almost immediately programming a plurality of street lights. The programming may also involve other ancillary functions that will be transferred automatically and equally to each lamp.

Drawings

The features and advantages of the invention will become more fully apparent from the following detailed description of embodiments of the invention, as illustrated by way of non-limiting example in the accompanying drawings, wherein:

figure 1 is a schematic view of a first view of an LED lamp of known type;

fig. 2 shows the lamp of fig. 1 in a top view;

fig. 3 schematically shows the lamp base of fig. 1 in a top view;

figure 3A shows some of the electronic components contained inside the base of the lamp;

figure 4 is a diagram of a device comprising a plurality of lamps according to the invention;

figure 5 shows an assembly of lamps according to the invention;

figures 6A and 6B show the lamp according to the invention in two operating configurations;

fig. 7A, 7B, 7C are electronic diagrams for the supply and control of lamps, respectively, according to the invention.

Detailed Description

The lamp of the invention comprises a plurality of LEDs distributed in respective rows (4) associated with a base (3) of the lamp.

The rows (4) of LEDs can be individually switched on and off by means of semiconductor electronic switches (60) (field effect transistors, etc.) in series with each row (4) of LEDs. As shown in fig. 7, each switch (60) may be controlled by a microprocessor (24) located, for example, in the base (3) of the lamp. The microprocessor (24) may for example be integrated in a printed circuit (21) arranged in the base (3).

The power supply (16) is preset to supply power to the LEDs, the microprocessor (24) and other components present on the printed circuit (21).

The lamp may advantageously be provided with an integrated communication circuit (25) which is preset to communicate remotely with the programming module and other lamps present in the lighting system. For example, the integrated circuit (25) may be bluetooth technology or generally wireless. The programming module may be a truly suitable programming station or may consist of a smartphone or portable programming device.

The lamp according to the invention further comprises detection means (17) predisposed to detect the position and orientation of the lamp in space. The detection means (17) comprise, for example, an accelerometer or magnetometer (17). The detection device (17) may be manufactured using MEMS technology.

The detection means (17) are connected to the microprocessor (24) and send it a piece of information corresponding to the position and orientation of the lamp in the space.

The microprocessor (24) is predisposed to control the switching on of one or more LED rows (4) according to a piece of information received from the detection means (17). To this end, the microprocessor (24) may be provided with an algorithm (for example in the form of firmware) configured to selectively control the switching on of one or more LED rows (4) according to a piece of information received from the detection means (17).

In essence, the detection means (17) are able to position the lamp in space, i.e. it is able to determine whether the lamp is oriented upwards or downwards and how its geographical position (relative to a base point) is oriented. It is thus clear that its spatial position can be defined precisely, irrespective of the installation position of the lamp. For example, if the road is oriented in a north-south direction and the light is located in the center of the road, the microprocessor (24) may be used to control the light to illuminate the LED rows (4) facing north to north-east, north-west, south-east, south-west, i.e. the LED rows (4) facing the road. This arrangement is valid for all lights located on the road as long as the road is straight, and can be transmitted to all lights having the same position with respect to the road. The programming control can be transmitted by a programming module or by a portable control device of the aforementioned type. If the road to be illuminated is characterized by tortuosity and curvature, each lamp can be automatically programmed using a map-based calculation algorithm, due to the presence of detection means (17) capable of indicating the direction of each lamp. Programming the lamp using the bluetooth transmission protocol involves establishing a secure and single connection between the lamp and the control device using a known security algorithm.

The lamp according to the invention can be advantageously used in all situations where asymmetrical lighting is required, for example in parks, gardens, courtyards, porches, intersections. The possibility of subdividing the lighting into successive sectors (for example eight parts of a circle) in addition to the upper or lower sectors (according to direction) makes the lamp extremely flexible and adaptable to various requirements, thus saving significant energy. The same techniques described above can be used in smaller environments to have the same advantages by using smaller accessories of the edison type (e.g., E27) that are very widely used in homes, offices, hallways, apartment blocks, etc.

The lamp of the present invention can be used without changing the existing equipment and structure by merely screwing the lamp of the present invention instead of the old lamp.

In addition to the above-mentioned energy saving, a series of auxiliary functions can be activated without increasing the hardware construction costs of the lamp, thanks to the presence of the microprocessor (24), based on the disconnection of the unwanted LED rows.

For example, the luminosity may be reduced at night, so that greater energy savings may be achieved when the normally illuminated road or place is illuminated to a lesser or partial extent. For example, in a park, after a certain time, the light facing the benches and the entertainment space can be turned off, while good lighting can be maintained on the lanes and paths to ensure a good level of safety for those passing through the park at a very late time.

By providing a communication circuit (25) on each lamp, each lamp can communicably receive instructions required to obtain lighting conditions required during use, such as during night lighting.

The lighting device of the present invention enables to realize a lighting device comprising a plurality of lamps (50), as schematically shown in fig. 4. The device may be provided with a programming module (40) which is pre-set to communicate with the lights of the device, for example, may be arranged along a road, park or elsewhere.

Preferably, although not necessarily, the lamp is provided with an integrated communication circuit (25) using bluetooth technology. As is known, this technique enables the various lamps to communicate with each other, thus forming a network comprising connections between the programming module (40) and the various lamps (50). These connections may be direct (41) or indirect (42), i.e. established via other lights (50) in order to be able to reach lights outside the direct range of the programming module (40). The use of a bluetooth connection also enables an alternative connection (43) to be defined in the event of failure of one of the plurality of lamps (50). In this way, the programming module (40) may be located anywhere on the device.

Furthermore, the control module (40) may be connected to other networks available in the area, such as WI-FI, WLAN, ethernet metropolitan networks, etc.

Information or instructions that may be sent to the various lamps (50) include, for example:

on/off time;

the luminous intensity of each region;

the total luminous intensity of the lamp;

lamp diagnostics (normal function of the various zones, temperature, operating life, etc.).

Existing lighting networks are able to send instructions to the various lamps in a programmed manner using transmitted waves or via a series of slow pulses (approximately one per second) that are sent based on the supply voltage of the lamps.

In the lamp of the invention, which is capable of using BT technology or other similar technologies, various information or instructions can be transmitted in a radio frequency manner and have a protocol that is preset to enable the lamp to connect to a network, for example, subdividing the lamp into defined groups that can be managed most efficiently.

In particular, the use of a microprocessor (24) and a power supply (16) makes it possible to maintain a constant activity of the communication network between the lamp and the programming module (40). For this purpose, it is sufficient to maintain the power supply (16) active and to always switch off the LEDs when no illumination is required to minimize energy consumption.

The possibility of maintaining a communication network between the lamps and the programming module (40) enables the following functions to be implemented in the lighting network.

The anti-theft function, which may be the result of a cut in the supply cable, can detect the eventual interruption in the communication network, so that an alarm signal can be issued.

Positioning and assistance functions, where a network of lights can be used as a receiver for search messages or for help calls, e.g. for elderly people. The messages may be sent via remote devices, for example "tags" of a known type, which may simply be located within the area covered by the network of lamps.

Direct control function of the individual lamps. For example, on a park bench, additional lighting of nearby street lights may be required. The request may be sent via a remote device (e.g., a smartphone) using a special application. Without such a requirement, the lamp can be kept at a lower illumination level to achieve greater energy savings.

The diagnostic function, for example, can verify the status of the lamp and the radio signaling of a broken and/or inefficient lamp by voltage, current and/or temperature data for each LED row.

By the possibility of producing directional illumination in an efficient manner, a further advantage of the lamp according to the invention is given.

In known types of lamps, the direction of the emitted light is provided by an external reflector, which converges the light if necessary. Over time, the reflector tends to become dirty and less efficient. Furthermore, in order to collect light efficiently, the reflector must be at least three times the diameter of the lamp and therefore have a large size.

The lamp of the invention may be provided with a row (4) of LEDs associated with the first support (18), for example in the form of a strip. The first support (18) is associated, through a rotary joint (19), with a connector (20) configured to be connected to the base (3) of the lamp, equipped for this purpose with a connector (23) for supplying electrical energy to the LEDs. The use of a swivel (19) allows the first support (18) to be tilted relative to the connector (20) to direct light in a desired direction. For example, if the base (3) is facing downwards, the support (18) may be inclined as shown in fig. 6B to direct light downwards. If the base (3) is instead facing downwards, the support (18) may be inclined as shown in figure 6A to direct light downwards.

Each support (18) is preferably, but not necessarily, provided with a heat sink (4a) of the type shown in figure 2. The connectors (23) of the base (3) may be provided with slots (30) for the passage of an air flow to cool the heat sink (14) and/or the rows (4) of LEDs. The air flow may be forced, i.e. obtained by a fan (22) housed in the base (3) of the lamp. The fan (22) is configured to push air through the slot (30) of the connector (23). The air is then directed through a portion of the connector (20) associated with the first support (18). The air flow can enter through slots (5) on the base (3) of the lamp and exit from each support (18) through slots (5a) arranged at the end of each first support (18). Alternatively, the first support (18) may be open at the end, so that the air flow is free to exit after hitting the radiator (4 a).

The LEDs are powered by direct current. Therefore, the connections between the connectors (20, 23) must also have the same power polarity. For this purpose, the connectors (20, 23) are provided with three mutually aligned electrical sources, one central pole and two lateral poles. The two transverse poles have the same polarity opposite to that of the central pole. For example, the center pole is the negative pole and the two lateral poles are the positive poles. In this way, the LED row receives the correct polarity regardless of the direction of insertion of the connector (20) of the LED into the connector (23) of the base (3). This enables each LED row (4) to be positioned in two symmetrical positions with respect to a plane containing the three poles. In this way, the support (18) can be tilted to direct light into a desired direction, independent of the upward or downward orientation of the base (3).

Fig. 7A, 7B, 7C emphasize a preferred embodiment of the invention implemented, and in particular fig. 7A shows a diagram of the power supply (16) in a typical implementation thereof, where the integrated circuit U2 is used as a flyback switchable power supply and the transformer T1 reduces the network voltage to a value compatible with the LED row (4). Circuitry U4 controlled by the processor (25) adjusts the luminance of the LEDs while power circuitry U1 powers the ancillary circuitry. Fig. 7B shows the processor (24) and the BT communication circuit (25), in this case made in a single integrated circuit U6 model CSR 1010. The magnetometer-accelerometer (17) is connected to the processor (24) and detects lamp position data. Fig. 7C shows 9 LED rows (4) controlled by a field effect transistor (60) capable of managing the switching on and off of each single LED row. Commands for the control element (60) are via the processor (25).