RU222959U1 - LED lighting device - Google Patents

Abstract

The utility model relates to electric lighting devices, in particular to high-power LED lighting devices with external power supply. The purpose of the claimed utility model is to achieve a technical result - increasing the reliability of the design. This goal is achieved as follows: an LED lighting device containing a housing, inside of which an LED unit with a reflective surface and a circuit board with a driver are installed, so that the input of the LED unit is connected to the output of the driver, and the input contacts of the driver are located outside the housing, characterized in that additionally equipped with a thermally dependent current control module in the power supply circuit of the LED block, so that the input of the thermally dependent current control module is connected to the driver output, and the output of the thermally dependent current control module is connected to the input of the LED block.

Description

A lighting device is known (patent RU 37180, published April 10, 2004), containing a housing, a mounting plate with semiconductor light-emitting elements installed in the housing, and an electrical circuit for supplying power to the semiconductor light-emitting elements, including an electric current converter. The lighting device is built-in, and the body of a standard built-in halogen or lamp lamp is used as the housing.

However, the known technical solution has low reliability, since the design does not have thermal control. When operating at elevated temperatures, LEDs degrade much faster, and the service life of LEDs is significantly reduced.

The closest known is a switching power supply for an LED flashlight (patent RU 127570, published on April 27, 2013), containing an input filter, an input rectifier, a control unit, a current protection unit, a transistor switch, the output of which is connected through a transformer to a powerful output rectifier and an output filter, a correction device, the first input of which is connected to the output filter, the output of the correction device is connected through an optocoupler to the first control input of the control unit, the second control input of the control unit is connected to the output of the current protection unit, and the output of the control unit is connected to the control input of the transistor key Contains a thermal relay with normally closed contacts, connected in series between the input of the power supply and the input filter.

However, a disadvantage of the known design is also low reliability. The thermal relay in the power circuit solves the problem of overheating, but if it overheats, the lighting device turns off completely, which indicates low reliability of the device. The device does not have the same quality as trouble-free operation.

The purpose of the claimed utility model is to eliminate the identified drawback in order to achieve a technical result - increasing the reliability of the structure by increasing the service life (increasing durability).

This goal is achieved as follows: an LED lighting device containing a housing, inside of which an LED unit with a reflective surface and a circuit board with a driver are installed, so that the input of the LED unit is connected to the output of the driver, and the input contacts of the driver are located outside the housing, characterized in that is additionally equipped with a thermally dependent current control module in the power supply circuit of the LED block, so that the input of the thermally dependent current control module is connected to the driver output, and the output of the thermally dependent current control module is connected to the input of the LED block.

The LED lighting device, in particular, can be characterized by the fact that the thermally dependent current control module contains: a temperature sensor, a setting resistor, an amplifying transistor and a divider, where the output of the temperature sensor is connected to the input of the setting resistor, the output of the setting resistor is connected to the input of the amplifying transistor, the output of which connected to the divider input.

The LED lighting device, in particular, can be characterized by the fact that the thermally dependent current control module contains: a temperature sensor, a setting resistor, an amplifying transistor and a divider, where the output of the temperature sensor is connected to the input of the setting resistor, the output of the setting resistor is connected to the input of the amplifying transistor, the output of which connected to the divider input.

The LED lighting device may in particular be characterized in that the temperature sensor is mounted directly adjacent to the LED unit.

The LED lighting device may in particular be characterized in that it contains a number of drive resistors.

The LED lighting device may in particular be characterized in that it further comprises a voltage stabilizer.

The LED lighting device can in particular be characterized in that the LED unit is additionally provided with a heat sink.

The essence of the claimed utility model is illustrated by drawings, where:

Fig. 1 shows the LED lighting device, front view;

Fig. Figure 2 shows the LED lighting device, rear view.

The numbers indicate:

1. body

2. circuit board,

3. LED block

4. reflective surface

The presented LED lighting device is arranged as follows

Inside the housing (1) of the LED lighting device, a circuit board (2) is fixed. A lighting device driver is attached to one side of the circuit board, the input contacts of which are brought outside the housing for connection to the power grid. The driver combines a controller with a power supply. The opposite side of the circuit board is made in the form of a reflective surface (4) (for example, it can be in the form of a reflective reflector), on which an LED block (3), made in the form of a plate with an LED matrix, is fixed.

The presented LED lighting device is used as follows.

As a result of the operation of any electrical device, its circuit elements inevitably dissipate energy in the form of heat. Elevated temperatures have a negative effect on circuit elements. For example, when operating at elevated temperatures, LEDs degrade much faster, and the service life of LEDs is significantly reduced.

To combat excess heat, while maintaining the functionality of the product, a temperature-dependent current control module is used in the LED power circuit. Connected to the driver output, a current control module in the LED power circuit generates a temperature-dependent voltage. Thus, a voltage is supplied to the input of the LED block, depending on the temperature of the LEDs. When the temperature exceeds a given threshold, a signal is generated at the output of the temperature-dependent control module, and the voltage supplied to the input of the LED unit is reduced. As the temperature decreases, this voltage also decreases and the signal at the output of the device disappears, and the previous value of the current through the LEDs is restored. In this case, the control module reduces the current through the LEDs not to zero, but to some reasonable value (for example, 50%), which, on the one hand, significantly reduces heat generation, ensuring a decrease in temperature, and on the other hand, the lighting device continues to perform its function.

The thermally dependent current control module may contain the following components: a temperature sensor, a setting resistor, an amplifying transistor and a divider. A divider connected to a stabilized voltage source generates a temperature-dependent voltage. When the temperature is exceeded, a control signal is generated from the output of the temperature sensor, which is fed into the driver feedback circuit to reduce the output current. For example, an NTC thermistor can be used as a temperature sensor. Until the temperature reaches the threshold value, this voltage is close to zero, it is not enough to open the amplifying transistor. When the temperature reaches a threshold value, this voltage begins to increase noticeably, flowing through the electrical circuit to the setting resistor. The setting resistor sets the threshold temperature values and the current reduction limit, which optimally contribute to the functioning of the device to ensure its reliable, uninterrupted, long-term operation. From the setting resistor, the current flows to the amplifying transistor, which opens and a signal appears at the output of the device, which is fed into the driver feedback circuit and causes a decrease in the current through the LEDs. Also, the design contains a divider, the input of which is connected to the output of the amplifier transistor. The voltage divider provides exactly the voltage that is most favorable for the LED lamp, thus increasing the durability of its operation and, accordingly, increasing reliability. Thus, it is obvious that adjusting current and temperature within strictly specified limits further increases durability and, therefore, reliability.

The temperature sensor can be mounted directly next to the LED block. This ensures the device responds quickly to temperature changes. This prevents the LED from being in an overheated state for a long time, increases the operating time of the LED light source (durability), and increases the reliability of the design. The closer and denser the temperature sensor is located to the body of the LED block, the more sensitive and reliable the temperature control circuit works, increasing the service life of the LED lamp.

To ensure greater reliability, due to finer adjustment to certain parameters of different LED lamps, a number of setting resistors can be used. The required number of setting resistors selected directly for each circuit will undoubtedly ensure the accuracy of the settings and, accordingly, the reliability of the proposed design.

Additionally, the design may contain a voltage stabilizer, which provides exactly the voltage that is most favorable for the LED lamp, thus increasing the durability of its operation and, accordingly, increasing reliability.

To provide a reduction in temperature of the LED lighting device, the housing may additionally include vents that allow heat exchange with the environment, providing further reduction in temperature. For the same purpose, the LED block can be additionally equipped with a radiator. The heatsink ensures efficient dissipation of the thermal energy generated from the LED unit, which reduces the temperature and thus increases durability and therefore reliability.

Thus, the use of a thermally dependent current control module in the power supply circuit of the LED unit ensures the achievement of the stated technical result - increasing the reliability of the design.

The claimed utility model can be used in the automotive industry and in the production of agricultural machinery, providing lighting for streets, industrial premises, LED lamps can be used in architectural lighting, and in many other areas. It can be manufactured, among other things, at electrical engineering enterprises.

Claims (6)

1. An LED lighting device containing a housing, inside of which an LED block with a reflective surface and a circuit board with a driver are installed, so that the input of the LED block is connected to the output of the driver, and the input contacts of the driver are brought outside the housing, characterized in that it is additionally equipped with a thermally dependent module adjusting the current in the power circuit of the LED block, so that the input of the thermally dependent current control module is connected to the driver output, and the output of the thermally dependent current control module is connected to the input of the LED block. 2. LED lighting device according to claim 1, characterized in that the thermally dependent current control module contains: a temperature sensor, a setting resistor, an amplifying transistor and a divider, where the output of the temperature sensor is connected to the input of the setting resistor, the output of the setting resistor is connected to the input of the amplifying transistor, the output of which is connected to the input of the divider. 3. LED lighting device according to claim 2, characterized in that the temperature sensor is fixed directly next to the LED unit. 4. LED lighting device according to claim 2, characterized in that it contains a number of setting resistors. 5. LED lighting device according to claim 1, characterized in that it additionally contains a voltage stabilizer. 6. LED lighting device according to claim 1, characterized in that the LED unit is additionally equipped with a radiator.